THE R.M. SANTILLI FOUNDATION
PROMOTING BASIC SCIENTIFIC ADVANCES AND SCIENTIFIC ETHICS


 

NEW SCIENCES FOR A NEW ERA:
Mathematical, Physical and Chemical Discoveries of
Ruggero Maria Santilli


I. Gandzha and J Kadeisvili


PRINTED VERSION
I. Gandzha and J Kadeisvili, New Sciences for a New Era:
Mathematical, Physical and Chemical Discoveries of Ruggero Maria Santilli,

Sankata Printing Press, University of Kathmandy, Nepal (2011), Free pdf download
http://www.santilli-foundation.org/docs/RMS.pdf

CHAPTER 4:
DISCOVERIES IN CHEMISTRY AND BIOLOGY

4.1. INTRODUCTION
4.1A. Lack of exact character of quantum mechanics for the hydrogen molecule (1978)
4.1B. Insufficiencies of the quantum chemical notion of valence (1978)
4.1C. Insufficiencies of screened Coulomb potentials (1978))
4.1D. Classification of hadronic chemistry (2000)
4.1E. Basic literature

4.2. HADRONIC CHEMISTRY
4.2A. Animalu-Santilli Cooper pair (1995)
4.2B. Santilli-Shillady strong valence bond (1999)
4.2C.The isoelectronium (1999)
4.2D. The hydrogen molecule (1999)
4.2E. The water molecule (2000)

4.3. THE NEW CHEMICAL SPECIES OF SANTILLI MAGNECULES
4.3A. Historical notes
4.3B. Conception of Santilli magnecules (1998)
4.3C. Detection of Santilli magnecules (1998)
4.3D. Magnecular structure of H3 and O3 (1998)
4.3E. Magnecular structure of liquids and solids (1998)

4.4 INDUSTRIAL REALIZATION OF FUELS WITH MAGNECULAR STRUCTURE
4.4A. Catastrophic forecasts facing mankind
4.4B. Santilli hadronic reactors (1998)
4.4C. Industrial realization of MagneGas fuel (1998)
4.4D. Industrial realization of the HHO fuel (2006)
4.4E. Industrial realization of MagneHydrogen fuel (2003)
4.4F. Molecular and magnecular combustions (1998).

4.5. SANTILLI DISCOVERY IN BIOLOGY
4.5A. Historical notes
4.5B. Deformability, irreversibility, and multi-valuedness of biological structures.
4.5C. Representation of biological structures via Santilli's deformable, irreversible and multi-valued hypermathematics
4.5D. Hypermolecules, hypermagnecules and hyperliquids
4.5E. Deciphering the DNA code?
4.5F. Understanding the DNA structure?
4.5G. A future new cure for cancer?
4.5H. Cloonan's advances in Santilli Magnecules


CHAPTER 4:
SANTILLI DISCOVERIES IN CHEMISTRY AND BIOLOGY


4.1. INTRODUCTION

4.1A. Lack of exact character of quantum mechanics for the hydrogen molecule (1978)

As recalled in Section 1.9, quantum chemistry has indeed permitted the achievement during the 20th century of historical advances in material and equipment of our daily lives. Nevertheless, it is the fate of all theories to admit broader formulations rendered necessary by insufficiencies of pre-existing theories or by the advent of basically new conditions for which preceding theories were not intended for.

As set in history, quantum mechanics provided a representation of the structure of one hydrogen atom with an incredible accuracy, essentially to the desired decimal value. However, when studying two hydrogen atoms bonded in the hydrogen molecule H2 = H-H (where the dash "-" represents valence bond hereon), the preceding accuracy is lost due to the historical inability to represent a residual 2 % of the binding energy from unadulterated quantum axioms, with much greater inaccuracies when passing to more complex molecules.


Figure 4.1. The original drawing used by Santilli to illustrate the physical differences between the hydrogen atom and the hydrogen molecule, the former consisting of point-like particles at large mutual distances, and the latter having additional short range interactions necessary for the valence bond. These physical differences illustrate the exact character of quantum mechanics for large mutual distances as in the hydrogen atom and its merely approximate character for additional short distance interactions as in the hydrogen molecule.

The above insufficiency of quantum mechanics for the hydrogen molecule was one of the motivations for the proposal by Santilli in 1978 to construct the hadronic covering of quantum mechanics, as per the historical paper hereon referred to as the "original proposal of 1978"

Need of subjecting to an experimental verification the validity within a hadron of Einstein special relativity and Pauli exclusion principle
R. M. Santilli,
Hadronic J. Vol. 1, 574-901 (1978)


4.1B. Insufficiencies of the quantum chemical notion of valence (1978)

Since nuclei do not participate in any appreciable way to molecular bonds, it is evident that the lack of exact character of quantum mechanics for the structure of the H-H molecule is due to the valence bond, namely, to the appearance of interactions and effects at the short distance conditions of the valence bond beyond the descriptive capabilities of quantum mechanics (see Figure 4.2),

For these and other reasons, Santilli never accepted the quantum chemical notion of valence bonds since his graduate studies in the 1960s at the University of Torino, Italy. In particular, as indicated in Section 1.9, Santilli always considered said notion as a pure nomenclature without quantitative scientific content because, to achieve the latter, the valence must verify the following:

CONDITION 1: Identify explicitly, that is, with equations, the force between a pair of valence electrons and its physical or chemical origin;

CONDITION 2: Prove that the above identified force is indeed attractive; and

CONDITION 3: The above identified attractive force must verify experimental evidence on molecular binding energies and other data.

Quantum chemistry cannot verify the above conditions because identical electrons repel each other, and certainly they do not attract each other, according to quantum mechanics and chemistry. Hence, Santilli sets his research objective of building a covering of quantum chemistry more adequate for the representation of the valence and other chemical features.


Figure 4.2. A reproduction of the original picture used by Santilli on the valence electrons bond in single coupling illustrating the need for a theory that is nonlinear (in the wavefunction), nonlocal (of integral type) and nonunitary (because of contact nonpotential type not representable with a Hamiltonian). Quantum chemistry is strictly linear, local-differential and Hamiltonian, thus being structurally unable to provide a quantitative representation of the valence. By comparison, the covering hadronic chemistry has the needed nonlinear, nonlocal and nonunitary structure beginning with its mathematical foundation.

The insufficiency of the quantum notion of valence was the central motivation for the construction of hadronic mechanics and chemistry, as stressed in the Original Proposal of 1978 quoted above, to such an extent that two intersecting circles were assumed as the first logo of the Institute for Basic Research.


4.1C. Insufficiencies of screened Coulomb potentials (1978)

The impossibility for the conventional formulation of quantum chemistry to provide an exact representation of molecular binding energies and other data became clear in the second part of the 20th century. The resolution of the insufficiencies was then attempted via the so-called screening of the Coulomb potential, that is, the multiplication of the fundamental Coulomb potential between two valence electrons, V = e2/r, by an arbitrary function f(r) of completely unknown origin, resulting in "screened potentials" of the type

(4.1) V'(r) = f(r) e2/r.

The arbitrary function f(r) was fitted from experimental data; screened Coulomb potentials did achieve the intended accuracy in the representation of binding energies; and quantum chemistry was confirmed as being exactly valid for molecular structures.

Despite the above success, Santilli never accepted screened Coulomb potentials for the following reasons:

1) .The map from the Coulomb potential to its screened form requires a nonunitary transform

(4.2) V(r) = e2/r → V'(r) = f(r) e2/r = U V(r) U.

(4.3) UU = f(dr) ≠ I .

Consequently, the screening of the Coulomb law causes major departures from the unitary structure of quantum mechanics

2) The Coulomb potential is a fundamental invariant of quantum mechanics. Consequently, its screening causes the breaking of the fundamental Galilei symmetry under which conditions quantum mechanics cannot any longer be exact.

3) It is well known that the quantum of energy is solely possible for the Coulomb law and that any quantization of the energy is impossible for screened potentials.

For these and other reasons, Santilli always rejected as inappropriate the name of "quantum chemistry" for screened Coulomb potentials. In the scientific reality, it is clear that the screening of the Coulomb law is outside the class of unitary equivalence of quantum mechanics and chemistry; hadronic mechanics and chemistry are indeed the broadest possible nonunitary coverings of quantum theories; and, therefore, screened potentials are a particular case of the nonunitary class of interactions treated by hadronic mechanics. To put it explicitly, Santilli showed that hadronic chemistry was already in use by the end of the 20th century, although under the disguised name of "quantum" chemistry.

As one can verify, Santilli's Original Proposal of 1978 was centered in the construction of a nonunitary covering of quantum mechanics also in view of the nonunitary character of map (4.2). Hence, the insufficiencies of quantum chemistry had a crucial role for the conception, development and verification of hadronic mechanics.


4.1D. Classification of hadronic chemistry (2000)

Immediately following the achievement in 1996 of mathematical maturity of hadronic mechanics, Santilli passed to applications of the new mechanics in chemistry because some of the most important experimental verifications and industrial applications of the new discipline was expected precisely in chemistry. These studies produced a covering of quantum chemistry known as hadronic chemistry comprising the following branches:

QUANTUM CHEMISTRY: assumed to be exactly valid for all mutual distances of particles bigger than 1 fm = 10-13 cm;

ISOCHEMISTRY: characterized by a Lie-isotopic, time invariant, axiom-preserving, nonunitary covering of quantum chemistry formulated over Hilbert-Santilli isospaces over Santilli isofields for the representation of isolated and reversible chemical structures and processes;

GENOCHEMISTRY: characterized by a Lie-admissible, time irreversible covering of isochemistry formulated on Hilbert-Santilli genospaces over Santilli genofields for the representation of irreversible chemical structures and processes;

HYPERCHEMISTRY: characterized by a multi-valued covering of genochemistry for the representation of organic structures and processes;

ISODUAL ISO-, GENO- AND HYPER-CHEMISTRY: characterized by the isodual map (2.9) for the description of the chemistry of antimatter.


4.1E. Basic literature

Hadronic mechanics achieved mathematical maturity in a special issue of the Rendiconti Circolo Matematico Palermo of 1996 entirely dedicated to Santilli's new mathematics, which issue also presented the first formulation of Santilli hypermathematics needed for biology

Nonlocal-integral isotopies of differential calculus, mechanics and geometries
R. M. Santilli,
Rendiconti Circolo Matematico Palermo, Suppl. Vol. 42, 7-82 (1996).

The main historical reference in hadronic chemistry is the 2001 monograph on Foundation of Hadronic Chemistry hereon refereed to as FHC:

"Foundations of Hadronic Chemistry,
with Applications to New Clean Energies and Fuels"

R. M. Santilli,
Kluwer Academic Publishers (2001)

Subsequent studies can be found in Hadronic Mathematics Mechanics and Chemistry, hereon referred to as HMMC Volumes I, II, III, IV and V:

Hadronic Mathematics, Mechanics and Chemistry, Volumes I, II, III, IV and V:
R. M. Santilli,
International Academic Press (2008)

Santilli's discovery of new magnecular fuels with complete combustion, and related industrial realization, can be found in the monograph

The novel magnecular species of hydrogen and oxygen with increased specific weight and energy content
R. M. Santilli,
Intern. J. Hydrogen Energy Vol. 28, 177-196 (2003)

A general review of the new species of magnecules is available from the monograph

The New Fuels with Magnecular Structure
Ruggero Maria Santilli

International Academic Press (2008)
200 pages
Italian translation by Giovanna Bonfanti and Michele Sacerdoti, published by Editori Riuniti, Roma, Italy, and available at
I Nuovi Carburanti con Struttura Magnecolare


The main references on Santilli's studies in biology can be found in the monographs

"Isotopic, Genotopic and Hyperstructural Methods in Theoretical Biology"
R. M. Santilli,
Ukraine Academy of Sciences (1997) The Australian biologist Chris R. Illert provided important input in Santilli's studies in biology, on which we quote the joint monograph

"Foundation of Theoretical Conchology"
C. R. Illert and R. M. Santilli,
Hadronic Press (1995)

Various, additional, specialized papers will be identified during the course of our presentation.

It should be stressed that in this chapiter we shall present for notational simplicity only the projection of Santilli's hadronic chemistry on a conventional Hilbert space over a conventional field, so as to avoid the complex notations of the full hadronic treatment. The understanding is that only the latter treatment resolves the Theorems of Catastrophic Inconsistencies of Section 3.7. Therefore, readers without a technical knowledge of hadronic mechanics are suggested to abstain from venturing judgments on the content of this chapter so as to avoid a clear illusion of knowledge.


4.2. HADRONIC CHEMISTRY

4.2A. Animalu-Santilli Cooper pair (1995)

The application and experimental verification of hadronic mechanics that anticipated hadronic chemistry is given by the first quantitative representation in history of the structure of the Cooper pair in superconductivity. As it is well known, quantum mechanics does provide a consistent representation of superconductivity, but via an ensemble of Cooper pairs considered point-like, without any description on how identical electrons could bond themselves into the Cooper pair, since electrons repel each other according to quantum mechanics.

A dominant model in the quantum literature in the field is that based on the interplay of entities called "phonons" that, however, are known to have a purely mathematical character since no "phonon" has ever been discovered, or can at least be formulated, within the context of elementary particle physics.

Independently from this basic insufficiency, the quantum description of superconductivity has long surpassed the boundaries of quantitative predictions for the increase of superconductive temperatures, recent efforts being essentially conducted on grounds of trials and errors without any mathematical and/or physical and/or chemical guiding foundations.

Hadronic mechanics permitted the first quantitative representation of the structure of the Cooper pair without any use of hypothetical "phonons", in a way fully compatible with available experimental data, as well with remarkable predictive capacity for bigger superconductive temperature.

The origin of the bond between the identical electrons of the Cooper pair resulted to be the contact nonpotential interactions occurring in the deep mutual penetration and overlapping of the wavepackets of the electrons, as first identified by Santilli in the Original Proposal of 1978. The trigger for the bond of the electrons resulted to be due to the cuprate as well as other nuclei. The nonpotential character of the interactions rendered mandatory the use of the sole invariant mechanics for their representation, hadronic mechanics.

In this way, the hypothetical "phonons" providing a hypothetical exchange bond between electrons that repel each other according to quantum laws, resulted as being a mere mathematical mechanism for the approximation of contact nonpotential interactions beyond any capability of quantum representations. The main gain in the process is a dramatic increase of the predictive capacities to increase the superconductive temperature, all the way to the prediction of a new electric current based on the transfer of Cooper pairs or, more appropriately, valence electrons pairs in singlet bond, since the latter have no appreciable magnetic moment, with evident dramatic decrease of the resistance.

Among a large number of publications in the field, we quote the historical paper by A. O. E. Animalu and R. M. Santilli of 1995

Nonlocal isotopic representation of the Cooper pair in superconductivity
A. O. E. Animalu and R. M. santilli,
Intern. J. Quantum Chemistry Vol. 29, 175-187 (1995)

Vast studies in the field were conducted by Animalu and reviewed in details in HMMC, Volume V, where Santilli gave the name of Animalu isosuperconductivity to the resulting new discipline.


4.2B. Santilli-Shillady strong valence bond (1999)

The central problem of molecular chemistry is the verification of Conditions 1, 2, 3 of Section 4.1. This objective was achieved by R. M. Santilli and the American chemist D. D. Shillady in the historical paper of 1999 .

A new isochemical model of the hydrogen molecule
R. M. Santilli and D. D. Shillady,
Intern. J. Hydrogen Energy Vol. 24, pages 943-956 (1999)

To provide a conceptual outline, consider the conventional quantum mechanical equation in relative coordinates and reduced mass for two electrons in singlet coupling as per Figure 4.2,

(4.4) (p2/m + e2/r) ψ(r) = E ψ(r),

where m is the electron mass. The above equation shows the repulsive Coulomb force between the point-like charges of the electrons. But the electrons have extended wavepackets of the order of 1 fm whose mutual penetration, as necessary for the valence bond, causes nonlinear, nonlocal and nonpotential interactions at the foundations of hadronic mechanics (see the preceding chapter). The only known possibility fo an invariant representation of these interactions is to exit from the class of unitary equivalence of Eq. (4.4) via an isounitary transformation (see Section 3.11) that, for simplicity, we present below in its projection into a conventional nonunitary form

(4.5) UU ≠ I, UU = I* = 1/T ,

(4.6) U [(p2/m + e2/r) ψ(r)] U =

= [ (Up2U)/m + (e2/r)UU] (UU)-1 [Uψ(r)U] =

= [1/m)p* T p* T + e2/r ] ψ*(r) = E' ψ*(r),

where one should note the different eigenvalue E' from the value E of Eq. (4.4) (due to the general noncommutativity of the Hamiltonian and the isounit).

At this point, Santilli and Shillady introduce the following realization of the nonunitary transform, that is, of the fundamental isounit of hadronic chemistry, Eq. (4.7) of FHC,

(4.7) UU = I* = 1/T =

= e{[ψ(r)/ψ*(r)] ∫ ψ1(r) ψ2(r) d3(r)} = 1 + [ψ(r)/ψ*(r)] ∫ ψ1(r) ψ2(r) d3(r) + ...

where ψ and ψ* are the solutions of the unitary and nonunitary equations, and ψk, k = 1,2, are the conventional quantum mechanical wavefunctions of the two electrons.

It is evident that, as desired, the above isounit represents interactions that are: nonlinear, because dependent in a nonlinear way in the wavefunctions; nonlocal, because inclusive of a volume integral; and nonpotential, because not representable with a Hamiltonian. Additionally, for all mutual distances between the valence electrons greater than 1 fm, the volume integral of Eq. (4.7) is null with the crucial limit

(4.8) Limr bigger 1 fm I* = 1,

under which hadronic chemistry recovers quantum chemistry identically and uniquely. As it was the case for hadronic mechanics, hadronic chemistry merely provides a form of "completion" of quantum chemistry at short distances much along the celebrated intuition by Einstein, Podolsky and Rosen.

Santilli and Shillady solved the above equations in all details. First, by inserting isounit (4.7) in Eqs. (4.6), they obtained the isoequation here projected on a conventional Hilbert space

(4.9) [p2/2m' + e2/r - Voe-br/(1 - e-br)] ψ*(r) = E'ψ*(r),

where m' represents the isorenormalization of the mass caused by nonpotential interactions, and one recognizes the emergence of the attractive Hulten potential

(4.10) VHulten = Voe-br/(1 - e-br).

But the Hulten potential is known to behave like the Coulomb potential at short distances and be much stronger than the latter. Therefore, Eq. (4.9) admits the excellent approximation

(4.11) [p2/2m' - V' e-br/(1 - e-br)] ψ*(r) = E' ψ*(r),

where the new constants V' reflects the "absorption" of the repulsive Coulomb potential by the much stronger attractive Hulten potential.

In this way, Santilli and Shillady achieved for the first time in the history of chemistry a valence coupling between two identical electrons in singlet coupling with a strongly attractive force, as requested by experimental evidence, which model is today known as the Santilli-Shillady strong valence bond.


4.2C.The isoelectronium (1999)

Another major insufficiency of quantum chemistry is the lack of restriction of the valence correlation-bond specifically and solely to a valence pair. This additional insufficiency causes further inconsistencies between the prediction of the theory and reality, such as the prediction that all molecules are paramagnetic, in dramatic disagreement with experimental evidence.


Figure 4.3. The original drawing used by Santilli to illustrate a catastrophic consequence of the quantum chemical notion of valence, the prediction of the paramagnetic character of all substances. The prediction includes the hydrogen molecule, in dramatic disagreement with experimental evidence according to which the hydrogen molecule is diamagnetic, thus being unable to acquire a total magnetic polarization under an external magnetic field. The indicated prediction is a consequence of the absence in quantum chemistry of a strongly attractive valence force, in which case valence electrons are unconstrained and, consequently, can acquire independent magnetic polarizations under an external magnetic fieod. The picture provides a conceptual rendering of the two H-atoms of the hydrogen molecule as essentially being independent. The alternative conception of orbitals distributed around the two nuclei carries an even stronger prediction of paramagnetic character because it can acquire more easily a total polarization under an external magnetic field contrary to nature.

Alternatively and equivalently, the fact that the hydrogen molecule is not paramagnetic can solely be represented via a strong bond between a valence electron pair into a quasiparticle Santilli and Shillady called the isoelectronium, that, as a necessary condition to avoid the prediction of the paramagnetic character of the H-H molecule, must have an oo-shapes orbit around the individual H atom as shown in Figure 4.4.

In the event the isoelectronium orbits along a single external orbit encompassing the two nuclei, its orientation under a sufficiently strong external field is consequential, resulting again in the catastrophic prediction of the paramagnetic character of the H-H molecule.

On technical grounds, the isoelectronium is the bound state of two identical valence electrons in singlet coupling characterized by the isoequation (4.9). Intriguingly, said equation admitted one and only one eigenvalue, thus characterizing the isoelectronium as a quasiparticle possessing the following main characteristics (see FHC for details):

ISOELECTRONIUM: Mass = 1.022 MeV; spin 0; charge 2e; magnetic moment 0; radius b-1 = 6.8432 10-11 cm.


Figure 4.4. A view of isochemical model of the hydrogen molecule at absolute zero degrees temperature, thus without any rotational degree of freedom, with the Santilli-Shillady strong valence bond between valence electrons pairs into the isoelectronium quasiparticle. Note the oo-shaped orbital of the isoelectronium, the only one allowing a representation of the diamagnetic character since, under an external strong magnetic field, the two H atoms acquire parallel but opposite magnetic polarities with null value at sufficient distance. Note also the toroidal distribution of the orbital of the isoelectronium due to the isouncertainty principle of hadronic mechanics,

Needless to say, the isoelectronium is unstable because the isouncertanty principle predicts the tunneling of the electrons through the nonpotential barrier. However, the bond between identical electrons in singlet coupling is so strong to cause the recombination of the isoelectronium following its spontaneous disintegration since the bond is attractive at distances much bigger than b-1 due to the extended character of the wavepackets.

It should be indicated that the name "isoelectronium" was proposed to emphasize the fact hat the individual electrons in valence couplings are not conventional particles, but isoelectrons, that is, electrons under Hamiltonian and non-Hamiltonian interactions characterized by the fundamental Poincare'-Santilli isosymmetry, thus having not only conventional renormalizations of kinematical characteristics caused by Hamiltonian interactions, but also isorenormalizations of intrinsic characteristics caused by non-Hamiltonian interactions.

A fundamental feature is that the strongly attractive Santilli-Shillady valence bond has no potential energy by central assumption because originating from nonpotential/non-Hamiltonian interactions. By recalling that the mass of the electron is 0.511 MeV, the mass of the isoelectronium 1.022 MeV is therefore assumed under the assumption that the positive potential energy for the Coulomb repulsion cancels out with the negative binding energy of the electron magnetic fields that, in singlet coupling, is attractive.


4.2D. The hydrogen molecule (1999)

By combining the vast advances outlined until now, hadronic chemistry permitted the first achievement of an exact-numerical representation of all characteristics of the hydrogen molecule H2 = H-H from unadulterated first principles without ad hoc adulterations, including binding energy, electric and magnetic moments, size, and other features, as presented in FHC Section 4.4 and the historical paper

A new isochemical model of the hydrogen molecule
R. M. Santilli and D. D. Shillady,
Intern. J. Hydrogen Energy Vol. 24, pages 943-956 (1999)


Figure 4.5. A view of all possible conventional interactions between the two electrons and the two protons of a hydrogen molecules. Being quantum mechanical, all these interactions are solely at a distance derivable from a potential, as in Eq. (4.12), thus being basically insufficient for a representation of the short term nonpotential interactions in valence bonds.

As it is well known, according to quantum chemistry, the hydrogen molecule is a four body system comprising two protons and two electrons with conventional equation for the molecule at rest, that is, the two protons are considered as rest as conventionally done

(4.12) [p12/2m1 + p22/2m2 + e2/r12 - e2/r1a - e2/r1b - e2/r2a - e2/r2b + e2/R] ψ(r) = E ψ(r),

where: 1, 2 represents the two electrons; a, b represent the two protons; and R is the distance between the protons. Due to its four-body character, the above equation, does not admit any analytic solution; misses at least 2% of the binding energy; and predicts that the hydrogen molecule is paramagnetic due to the evidence independence of the electrons.

The repetition of the nonunitary transform of the preceding section yield the isochemical model of the hydrogen molecule as a four-body system

(4.13) [p12/2m'1 + p22/2m'2 - V* e-br/(1 - e-br) + e2/R] ψ*(r) = E' ψ*(r),

showing the appearance of the Santilli-Shillady strong valence bond of Hulten type that "absorbs" all coulomb potentials, where m' represents the isorenormalized mass of the electrons.

In the figures below we provide the results of the solutions of the isochemical model (4.13) achieved via variational methods by Santilli and Shillady in their historical paper of 1999, with detailed elaboration additionally provided in FHC, Chapter 4.



Figure 4.6. A reproduction of Tables 4.1 and 4.2 of Santilli's FHC showing the achievement by isochemistry of a numerically exact representation of all features of the hydrogen molecule.

However, a fundamental implication of hadronic chemistry is that of restricting the above four-body model to a three-body structure evidently composed by the two protons at mutual distance R and the two valence electrons strongly bonded into the isoelectronium quasiparticle. In fact, by repeating the nonunitarity map of the preceding section, the isochemical model of the hydrogen molecule as a three-body system can be written

(4.14) [pisoel2/2misoel + pa2/2mprot + pb2/2mprot - V* e-br/(1 - e-br) + e2/R] ψ(r) = E' ψ(r),

where: the system does admit an analytic solution in its restricted form under the assumption that the isoelectronium is stable; and one should note again the change of the eigenvalue in the transition from Eq. (4.12). Note also that Eq. (4.14) is purely quantum chemical because all distances between the constituents are much bigger than 1 fm.

An exact variational solution of model (4.14) was first studied in 2000 by A.K. Aringazin and M.G. Kucherenko in the paper

Exact variational solution of the restricted three-body Santilli-Shillady model of the hydrogen molecule
A.K. Aringazin and M.G. Kucherenko
, Hadronic J. Vol. 23, 1-56 (2000) (physics/0001056)

The exact analytic solution of model (4.14) was achieved in 2007 by R. Perez-Enriquez and R. Riera in the paper

Exact analytic solution of the restricted three-body Santilli-Shillady model of the hydrogen molecule
R. Perez-Enriquez and R. Riera
, Progress in Physics Vol. 2, 34-41 (2007) (physics/0001056)


4.2E. The water molecule (2000)

Despite a deceptive simplicity, the water molecule H2O = H-O-H is one of the most complex structures in nature whose understanding, let alone its representation, is beyond the capability of the rather limited theories of the 20th century because of the following additional insufficiencies or inconsistencies:


Figure 4.7. A view of the water molecule H2O at absolute zero degree temperature, thus without any rotational degree of freedom, showing the H-O-H plane, the 105o between the H-O and O-H dimers and, above all, the natural occurrence according to which the orbitals of the H atoms are not spherical, but of toroidal character for their coupling with the oxygen, thus providing a direct verification of the isochemical model of the hydrogen molecule of Figure 4.5

1) Quantum chemistry not only fails to achieve an exact representation of the binding energy of the water molecule from first principles without ad hoc adulterations, but predicts electric and magnetic polarizations that are wrong even in the sign, let alone in their (absolute) values.

2) Quantum chemistry is a structurally linear theory, thus representing complex multi-body systems such as the water molecule via the factorization of the total wavefunction into its individual components,

(4.15) ψtotal = ψ1 ψ2 ... ψn

which factorization, in turn, requires the validity of the superposition principle as a pre-requisite for consistency. However, multi-body systems are nonlinear (in the wavefunction and other quantities), under which occurrence the superposition principle is inapplicable, with consequential impossibility of formulating a consistent factorization

(4.16) H(r, p, ψ, ...) ψtotal ≠ H(r, p, ψ, , ...) ψ1 x ψ2 x ... ψn.

thus resulting in the inapplicability of the very axioms of quantum chemistry to complex structures such as the water molecule.

3) When passing to the synthesis of the water molecule, the insufficiencies of quantum chemistry become embarrassing because the former process is structurally irreversible, while the latter theory is reversible, thus predicting with equal statistical probability both the synthesis and its spontaneous decay (Section 1.9)

(4.17) H2 + O → H2O

(4.18) H2O → H2 + O.

thus becoming inapplicable for a serious study.

4) When passing to water molecules as part of complex environments such as in the liquid state or when at the foundation of life, the insufficiencies of quantum chemistry become simply beyond any level of acceptability.

5) Besides all these limitations or sheer inconsistencies, quantum chemistry admits an additional rather crucial limitation given by the poor convergence of perturbative series. In essence, the water and other complex molecules are multi-body systems, thus requiring approximate solutions via variational, perturbative, Gaussian, and other methods, all based on expansions whose calculations require computers due to their complexity. The insufficiency here referred to is given by the fact that the time requested for basic calculations by large computers is generally excessive, thus implying an inherent lack of strong convergence of the underlying perturbative series, with consequential debatable accuracy.

All the above insufficiencies or sheer inconsistencies establish that the selection of the appropriate generalization of quantum chemistry should indeed be subjected to scientific debate, but its denial for the preservation of an old theory is equivocal and ascientific.

Santilli conceived and constructed hadronic mechanics and chemistry for the solution of the above insufficiencies. In fact:

1*) Hadronic chemistry achieved the first exact representation of all features of the water molecule from first unadulterated principles;

2*) The reconstruction of linearity on the Hilbert-Santilli isospace over Santilli isofields (isolinearity) achieved via the embedding of all nonlinear terms in the isounit and isotopic element,

(4.19) H(r, p, ψ, ...) = Ho(r, p) T(ψ,...),

and restores the superposition principle with exact factorization

(4.20) Ho(r, p) T(ψ, ...) ψtotal = Ho T(r, p, ψ, , ...) ψ1 x ψ2 x ... ψn.

with consequential validity of the isotopic theory for complex systems.

3*) The entire branch of genochemistry has been constructed by Santilli with an irreversible structure precisely to resolve the inconsistency 3).

4*) The additional branch of hyperchemistry has been built by Santilli precisely to initiate the study of complex inorganic and organic structures, as we shall see later on this chapter (see Section 4.5 below).

5*) Yet another central feature of isochemistry is that the absolute value of the isounit, such as Eq. (4.7), is much bigger than one and the isotopic element is much smaller than one. Consequently, all series that are slowly convergent are turned into a strongly (fast) convergent form. In fact, the variational calculations for the isochemical model of the water molecule turned out to require a computer time at least 1,000 shorter than that of conventional calculations (see FHC for details).

The understanding of hadronic chemistry requires the knowledge that it permits a series of treatments of the water molecule with increasing complexities and methodological capabilities. The first treatment addressed in this section is that via isochemistry and applies when the water molecule is assumed as isolated from the rest of the universe, reversible over time and at absolute zero degrees temperature, thus without any rotational degrees of freedom as in Figure 4.7.

ISOCHEMICAL MODEL OF THE WATER MOLECULE:
The model achieved for the first time the exact representation from first axiomatic principles without ad hoc adulterations of the binding energy, sign and values of the electric and magnetic moments, and other features as first presented by Santilli and Shillady in their second historical paper of 2000

A new isochemical model of the water molecule
R. M. Santilli and D. D. Shillady,
Intern. J. Hydrogen Energy Vol. 25, 173-183 (2000)

with a detailed presentation available in FHC, Chapter 5. The study is too complex for a technical outline in this section. Therefore, we limit ourselves to the following conceptual summary.

The model can be constructed and worked out via a series of progressively improving representations. The simplest one is given by achieving an exact solution for the dimer O-H and then introducing the additional H atom as a perturbation. This can be done by representing the oxygen as a two-body ion O- characterized by one valence electron and all the rest of the atom assumed as concentrated in its nucleus with one single positive elementary charge.

The Santilli-Shillady strong bond of the valence electrons into the isoelectronium then renders the system H-O- a restricted three-body system with an exact solution. The additional H atom is then added as a perturbation or via other mean.

By denoting with the subindics 1 and a the hydrogen and 2 and b the oxygen, the conventional quantum chemical representation of the above indicated H-O- dimer is similar to that of Eq. (4.12), i.e.,

(4.21) [p12/2m1 + p22/2m2 + e2/r12 - e2/r1a - e2/r1b - e2/r2a - e2/r2b + e2/R] ψ(r) = E ψ(r),

Santilli and Shillady then apply a nonunitary transform as for the hydrogen molecule, resulting in the appearance of the strongly attractive Hulten potential as in model (4.13). At this point, the bond of the second H atom can be represented via a nonunitary image of the Coulomb law resulting in screening of Gaussian type

(4.22) 2e2/r → 2e2(1 +/- e-αr)/r

where: the double value 2e originate from the duality of the bonds in H-O-H; α is a positive constant to be determined from the data; the sign "-" applies for an O-atom as seen from an H-electron; and the sign "+" applies for the O-atom as seen from the H-nucleus.

Note that lifting (4.22) would be aprioristic and without axiomatic foundation for quantum chemistry, since it requires a nonunitary image of the Coulomb law, while for the covering hadronic chemistry it is derived from first principles, namely, via precisely the needed nonunitary transform of quantum settings.

The implementation of the above features then yields the isochemical model of the water molecule in its projection in the conventional Hilbert space over conventional fields

(4.23) [p12/2m'1 + p22/2m'2 - V* e-br/(1 - e-br) - 2e2/r2a - 2e2(1 - e - αr1b)/r1b + e2(1 + e-αR)/R] ψ*(r) = E' ψ*(r),

where; E' is half of the binding energy of the water molecule; R is the interatomic distance; and the size of the isoelectronium should also be fitted from the data.
Under the above approximation, plus the assumption that the isoelectronium is stable, model (4.23) constitutes the first exactly model of the water molecule from first principles in scientific history. Such an exact solution was first reached by Santilli and Shillady via variational methods in their historical paper of 2000, with comprehensive variational studies conducted by A. K. Aringazin a reproduced in Chapter 6 of FHC.


Figure 4.8. A reproduction of Table 5-1 of Santilli's FHC summarizing the achievement of the first numerically exact representation of the binding energy, electric and magnetic moments of the water molecule.

Note the double nonunitary transform requested by the model, the first for the isoelectronium and related strong bond, and the second for the representation of the second H atom via a perturbation-screening of the H-O dimer. Note also that the model is invariant if and only if written on Hilbert-Santilli isospaces over Santilli isofields. Note finally that the computer usage needed for the variational calculations resulted to require 1/1000 shorter time than that needed for conventional model because both unitary transforms verify the conditions that the related isotopic element is must smaller than one.

A more accurate isochemical model of the water molecule is given by a five body system comprising the two H nuclei, the O atom assumed with all electrons concentrated in the nucleus except for the two valence electrons, and two isoelectronia assumed as fully stable. Needless to say, this model admits no analytic solution, thus requiring variational or other approaches.

A further isochemical model is the preceding one in which the two isoelectronia are assumed as being unstable and their meanlives are computed from the experimental data.

GENOCHEMICAL MODEL OF THE WATER MOLECULE. It is based on the assumption of two nonunitary transforms for the characterization of the forward "f" and backward "b" genounits and related motion in time

(4.24) UW = If, WU = bI,

(4.25) If = (bI),

The model is particularly useful for the irreversible representation of the synthesis of the water molecule H2 + O → H2O in such a way to prevent the existence of a finite probability for the spontaneous time reversal image.

HYPERCHEMICAL MODEL OF THE WATER MOLECULE. It is essentially given by a multi-valued extension of the preceding models and has resulted as having basic relevance for the initiation of the understanding of the complexity of the water molecule when part of living cell, thanks also to the availability of a virtually unlimited degree of freedom for biological correlations and other complex events (see Section 4.5 below). Note that the water molecule acquires such a complexity as being beyond our conceptual understanding.

ISODUAL ISO-, GENO-, AND HYPER-CHEMICAL MODELS OF THE WATER MOLECULE. They are the images of the preceding models characterized by the isodual map (2.9,) and are used for quantitative studies of the antimatter water molecule (see FHC for details).

Additional very important studies on hadronic chemistry were conducted by A. K. Aringazin and his group in Kazakhstan. Besides the detailed review of these studies by Santilli in FHC, we indicate here the additional papers

On a variational solution of the four-body Santilli-Shillady model of the hydrogen molecule
A.K. Aringazin, Hadronic J. Vol. 23, 57-113 (2000), physics/0001057.

Isoelectronium correlations as a nonlinear two-dimensional two-particles tunnel effect
A.K. Aringazin and M.B. Semenov, Hadronic Journal Vol. 23, 25-53 (2000).


4.3. THE NEW CHEMICAL SPECIES OF SANTILLI MAGNECULES

4.3A. Historical notes

The dimension of Santilli's scientific conceptions can be understood by noting that all the preceding advances on conventional molecular structures were done as a mere preparatory basis for the conception, quantitative treatment, experimental verification and industrial development of a basically new chemical species, that is, a species whose bond is NOT that of valence. The results were presented in yet another historical paper of 1998

Theoretical prediction and experimental verification of the new chemical species of magnecules,
R. M. Santilli,
Hadronic J. Vol. 21, 789-894 (1998)

with a detailed presentation in FHC and an update in the monograph of 2008

The New Fuels with Magnecular Structure
Ruggero Maria Santilli

International Academic Press (2008)
200 pages
Italian translation by Giovanna Bonfanti and Michele Sacerdoti, published by Editori Riuniti, Roma, Italy, and available at
I Nuovi Carburanti con Struttura Magnecolare

plus various papers quoted in the subsequent sections.


4.3B. Conception of Santilli magnecules (1998)

The primary origin of pollutants contained in fossil fuel exhaust is the valence bond that is so strong to prevent full combustion. Consequently, Santilli set his research goal to search for a new way of bonding together into stable clusters the same atoms composing fossil fuels under the following:

CONDITION 1: The new bond should be weaker than the valence bond as a necessary condition to decrease pollutants;

CONDITION 2: The new weaker bond should allow the formation of clusters that are stable at industrially used storage values of temperature and pressure, e.g., those for methane; and

CONDITION 3: The new, weaker and stable bond should decompose itself at the combustion temperature to optimize the energy released by the combustion.


Figure 4.9. The new chemical species of Santilli magnecules requires an atomic technology capable of polarizing the orbitals of individual atoms (rather than molecules) into a toroidal form (rendering by A. K. Aringazin).

As we shall see later, the above conditions permitted the identification of new environmental processes in which pollutants in the exhaust are decreased by increasing the combustion. In particular, fuels verifying the above conditions are said to admit a full combustion, namely, they release no uncombusted component in the exhaust, that is, no HydroCarbons HC, carbon Monoxide CO and other combustible contaminants present in fossil fuel exhaust.

By proceeding in his typical analytic way, following the identification of his research goal, Santilli conducted systematic studies on the realization of the above conditions. To understand the difficulties facing the conception and production of a new chemical species, one should recall that atoms have a spherical distribution of their orbitals, thus normally exhibiting the sole possibility of a valence bond. Hence, Santilli had to create a new force field in atoms as a condition to achieve a new chemical species.

The answer originated from Condition 3 that suggested the use of magnetic forces since all magnetic effect disappear at a given temperature (called the Curie Temperature). Therefore, Santilli argued that, in the event a new bond could be based on magnetic fields, all Conditions 1, 2, 3 would be verified because: magnetic bonds are known to be weaker than valence bonds; they are expected to be stable under ambient conditions; and they are expected to decompose themselves at the combustion temperature that was assumed as being the Curie temperature of the new bond.


Figure 4.10. The sole known possibility of industrial production of new fuels with Santilli magnecular structure is given by submerged electric arcs due to the need for very strong magnetic fields that are indeed provided by electric arcs at atomic distances. In particular, the arc performs three important functions: 1) the polarization of atomic orbitals into toroids with symmetry axis tangent to the local magnetic force given by a circle perpendicular to the arc direction; 2) The coupling of different atoms with opposing magnetic polarities North-South-North-South- etc.; and 3) The compression of magnetically polarized and coupled atoms toward the arc due to still unknown effects .

Santilli argued that the possible control of the distribution of atomic orbitals, from their conventional spherical form to a toroidal form would indeed create a magnetic dipole North-South along the symmetry axis, thus creating the needed new field in atoms that normally have none.

A huge difficulty then emerged because it is known in the technical literature that the control of the orbitals of atomic electrons requires extremely strong magnetic fields of the order of 1010 Gauss or more, namely, magnetic fields at least 1,000 time stronger then the biggest magnetic field available at the U. S. Large Magnet Laboratory in Tallahassee, Florida.

By again proceeding in his analytic way, Santilli conducted a systematic search of engineering means for exposing atomic orbitals to the needed very strong magnetic fields, and concluded his studies with the selection of DC electric arcs submerged within a fluid (a gas or a liquid). In fact, in this case, the magnetic field M follows the known law

(4.26) M = k A/r,

where A represents the number of Amperes of the arc, r the distance from the arc and k a constant depending of the selected units whose value is here irrelevant. Therefore, at atomic distances from the arc, that are of the order of 10-8 cm, and for currents of the order of 103 A, the magnetic field M is indeed of the desired order of 1011 Gauss.

In early 1998, Santilli introduced his new chemical species he called magnecules to distinguish them from conventional molecules, the former having the new magnecular bond, the latter being characterized by the conventional valence bond, the new species being defined as follows:

SANTILLI MAGNECULES: Are given by clusters comprising individual atoms, such as H, C, O, etc., dimers, such as H-O, C-H, etc., and ordinary molecules, such as C-O, CO2, etc., bonded together by opposing magnetic polarities of toroidal polarizations of atomic orbitals plus opposing nuclear and electron magnetic polarizations. Electric polarizations are evidently expected to participate in the magnecular bond, although they are notoriously weaker and much more unstable than magnetic bonds.



Figure 4.11. A conceptual rendering of an "elementary magnecule" comprising two identical or different atoms whose bond is entirely of magnecular character, namely, originating from opposing polarities North-South-North-South of the toroidal distributions of orbitals, as well as the polarization of nuclear and electron magnetic moments.

In the historical paper of 1998 Santilli conducted a quantitative identification of the magnetic field caused by electrons rotating at a speed close to the speed of light within a toroidal polarization, and concluded that such a magnetic field is about 1,315 stronger than the nuclear magnetic field. This calculation was independently verified for the first time by M.G. Kucherenko and A.K. Aringazin in the paper

Estimate of the polarized magnetic moment of the isoelectronium in the hydrogen molecule
M.G. Kucherenko and A.K. Aringazin, Hadronic J. Vol. 21, 895-902 91998.

Additional comprehensive studies were conducted by A. K. Aringazin, as in the paper

Toroidal configuration of the orbit of the electron of the hydrogen atom under strong external magnetic fields
A.K. Aringazin, to appear in Hadronic J. (2001).


4.3C. Detection of Santilli magnecules

There should be no surprise on the fact that no new chemical species were discovered from the pioneering studies by Avogadro, Canizzaro and others of the middle of the 19th century until Santilli studies at the end of the 20th century. In fact, all available analytic methods and equipment have been conceived, developed and established for the detection of molecules, and NOT for magnecules. Any belief that Santilli's magnecules can be detected or denied via the use of conventional molecular means constitutes a mere illusion at best, the results emerging from such biased approaches being called by Santilli "experimental beliefs."

The serious scientist should remember that, by conception and construction, magnecules have a bond much weaker than that of molecules. Consequently, all analytic methods that are indeed very fast and efficient for the detection of molecules, usually destroy the very magnecular species to be detected, e.g., because the energy of ionization beams is much bigger than that for magnecular separation while being unable to cause any molecular separation. Also, all magnetic bonds and effects are known to have a Curie temperature at which they disappear. Therefore, any claim of lack of existence of magnecules via Gas Chromatographers (GC) and other equipment using thermal and/or high temperature detection processes, is purely nonscientific, since the thermal process destroys the very species to be detected.

By far the biggest difficulties were experienced by Santilli in the experimental verification of his new species, not only because of the deplorable conditions of analytic chemistry at the end of the 20th century for which no basic novelty was believed as being possible. Hence, when faced with anomalous results, rather than admitting possible novelty, analysts would enter into incredible gyrations and manipulations of the equipment for the specific intent of eliminating any possible novelty, and then claiming lack thereof.

A typical example in gas chromatography is the reduction of a peak in the mass spectrum, let us say, at 250 atomic mass units (amu) to its components H2, CO, etc., and then claim absence of a new species, when the detected conventional molecules are the constituents of the peak at much lower amu, thus resulting in a pure "experimental belief" without scientific content.

Additional difficulties were created by the widespread practice of conducting only one detection and then claiming a final "experimental result," while in reality no result can be claimed to be scientific on serious grounds without at least a second verification with a different instrument. This practice is particularly insidious for magnecules because "experimental beliefs" obtained with one analytic equipment can be solely dismissed with a second independent verification.

Following a systematic study of all available equipment, Santilli selected the use of a Gas Chromatographer Mass Spectrometer equipped with an InfraRed Detector (GC-MS/IRD) because that instrument allows the study of the same cluster, firstly, in the mass spectrum and, secondly, under the IRD. In the event the GC-MS and the IRD are used separately, the MS peak would not generally appear in the IRD when of magnecular nature, thus leading to manipulations of experimental data and illusions of scientific process.

Santilli then conducted a nation wide search for a GC-MS/IRD to discover that no academic or commercial analytic laboratory in the U.S.A. had none since GC or GC-MS alone are very effective for molecular detections, thus leading to the widespread tendency of avoiding any verification of the results via a different equipment. Continued search revealed that military and forensic laboratories do generally have GC-MS/IRD due to stringier requirements for verification and accuracy.

Following such an extensive search, Santilli finally located the availability at the McClellan Air Force Base near Sacramento, California, of a GC-MS/IRD consisting of a HP GC model 5890, a HP MS model 5972, equipped with a HP IRD model 5965. Santilli visited said basis on June 19, 1998, with samples of gas produced via an arc between graphite electrodes submerged within distilled water. Following confirmation of the needed equipment, the GC-MS/IRD had to be used in way rather unusual for molecular tests, such as:

1) The feeding line had to be the largest available because feeding lines with small sectional area (of a fraction of 1 mm2), that work perfectly well for molecular species, do not allow the passage of magnecular species with large amu due to an anomalous adhesion of magnecules to the internal walls of the feeding line;

2) The temperature of the column had to be the lowest possible because high column temperature, while excellent for rapid detection of molecules, destroy in part or in full the magnecular species to be detected;

3) The elusion time had to be the longest admitted by the instrument (and set at 21 minutes) to allow the proper separation of magnecules into clusters appearing in the mass spectrum, while short elusion times so effective for the separation of molecules, may provide the superposition of magnecular clusters without proper separation, thus with ambiguous results.

Following considerable perplexities due to the unusual character of the requests, the analysts at the McClellan Air Force Base did implement all unusual requests by Santilli and, in so doing, produced on June 19, 1998 the first experimental evidence on the existence of the new chemical species of magnecules reported in the figures below.




Figure 4.12. The historical printouts on the original detection of Santilli magnecules achieved on June 19, 1998, at the analytic laboratories of McClellan Air Force Basis near Sacramento, CA, via a HP GC model 5890, and a HP MS model 5972 equipped with a HP IRD model 5965. The test was conducted on a gas with magnecular structure produced by Santilli via an electric arc between graphite electrodes submerged within distilled water. According to quantum chemistry, the heaviest expected species was CO2 at 44 amu. For this reason, the analysts set the scan between 40 amu and 400 amu, the latter being the instrument upper limit. At the appearance of the numerous unexpected species of the top figure, all much heavier than 44 amu and in macroscopic percentages, the analysts showed some surprise. Hence, they requested the computers of the Air Force Basis (containing all known molecules in excess of 500,000 species) to identify the peaks. At the failure of identifying any of the anomalous peaks (see the example in the middle), the analysts indicated to Santilli that he had apparently produced "new molecules" not yet known to them. At that point, Santilli requested the analysts to inspect the same anomalous peaks under the IRD. Following due procedures, the scan at the bottom appeared solely showing the IR signature of CO2. The evidence that none of the mass peaks of the top scan had any IR signature as in the bottom scan caused considerable excitement due to clear impossibility for these large mass peaks to be molecules since only the hydrogen and very few other light molecules have the perfectly spherical shape necessary to have no IR signature. The analysts of the McClellan Air Force Basis expressed their congratulations to Santilli and released a signed statement of novelty reproduced in the historical 1998 paper as well as in FHC.

An additional experimental evidence is given by the anomalous adhesion of gases with a magnecular structure, namely, their adhesion to solid or liquid substances irrespective of whether paramagnetic or diamagnetic. This anomalous characteristics is established by the blanks of GC-MS that, following the flushing of the magnecular gas with an inert gas, show essentially the same peaks as those of the scan with the gas, to such an extent to require flushing with an inert gas at high temperature to recover conventional blanks, namely, those with no appreciable peaks except for background (see Figure 4.21 below). This feature evidently confirms the magnetic polarization of the gases here considered as well as its existence at the level of individual atoms, a condition necessary for adhesion via polarization by induction to both paramagnetic and diamagnetic substances. The feature also has a number of important industrial applications, such as the elimination of the seepage through containers walls for hydrogen when treated to have a magnecular structure (see Section 4.4E).

For additional experimental verification, we refer the serious scholar to the literature in the field, such as:

"Foundations of Hadronic Chemistry,
with Applications to New Clean Energies and Fuels"

R. M. Santilli,
Kluwer Academic Publishers (2001)

Hadronic Mathematics, Mechanics and Chemistry, Volume V:
R. M. Santilli,
International Academic Press (2008)

The novel magnecular species of hydrogen and oxygen with increased specific weight and energy content
R. M. Santilli,
Intern. J. Hydrogen Energy Vol. 28, 177-196 (2003)

Figures 28-29 of the latter references are significant because they present the scan of a GC-MS/IRD similar to that at the McClellan Air Force Bases, operated by a forensic laboratory in Largo, Florida with similar results (unknown heavy peaks in the MS without IR signature), although with the accumulation of the MS peaks due to the short elusion time.


4.3D. Magnecular structure of H3 and O3 (1998)

As it is well known, GC-MS routinely detect the species H3 at 3 amu and O3 at 48 amu. Their interpretation in quantum chemistry is that via a conventional valence bond.

Santilli never accepted such an interpretation for various reasons. To begin, the deep correlation-bond of valence electrons is in single couplings as in Figure 4.2, thus creating a boson with total spin 0. Consequently, Santilli argues that it is impossible for quantum mechanics and chemistry that a fermion with spin 1/2, the electron, can bond to a boson with spin 0, the isoelectronium valence pair.

As recalled in Section 4.1, the notion of valence in quantum chemistry is not quantitative for various insufficiencies, including the absence of the correlation-bond of the valence electrons, specifically, to electron pairs. It is then evident that, in the absence of such a restriction, the species H3 and O3 can have a valence bond. However, such an interpretation is faced with serious inconsistencies, such as the prediction that all substances are paramagnetic (Section 4.2C).

Additionally, nature establishes beyond doubt that the valence bond is for electron pairs. Hence, the valence bond for the species H3 and O3 requires that only two out of three atoms are bonded at any given time. Santilli has proved that such an interpretation is disproved by the binding energies of H3 and O3, namely, the predicted binding energy is in dramatic disagreement with experimental values.

In view of the above and other evidence, Santilli proposed in FHC that the species H3 and O3 have a magnecular structure of the type

(4.27) H3 = (H - H) x H, O3 = (O - O) x O,

namely, they comprise ordinary molecules H2 and O2 with valence bond plus a third atom with magnecular bond (see Figure 4.13), thus being magnecules according to their definition. In any case, it is known that ozone O3 is formed under electric discharges precisely as needed for the production of magnecules (Section 4.3B), and a similar mechanism holds for the H3.


Figure 4.13. Quantum chemistry suggests that the valence, in one of its various nomenclatures without quantitative treatments, is responsible for all possible species existing in the universe, expectedly, until the end of time. Consequently, for quantum chemistry the species H3 and O3 are characterized by valence bonds. Santilli has identified numerous inconsistencies of such an interpretation and shown that said species have instead a magnecular structure comprising conventional molecules H2 and O2 with a third atom under magnecular bond as shown in the figure. In fact, ozone O3 is formed under intense electric discharges that separate O2 molecule as a condition to have a free oxygen atom, jointly polarize the O2 molecule, and align them as in Figure 4.10, thus providing a natural representation of its formation, let alone of its structure in a way compatible with experimental data. The same holds for H3.


4.3E. Magnecular structure of liquids and solids (1998)

Another notion of quantum chemistry rejected by Santilli since his graduate studies is the interpretation of the water liquid state as being due to "H-bridges" or similar conjectures, because, as it is the case for the valence, the notion is a pure nomenclature without the explicit identification of a force binding the water molecules together, without the proof that such a force is indeed attractive, and without showing that such an attractive force represents experimental data.

In his historical monograph FHC, Santilli proposed that the liquid state of water as well as of other liquids has a magnecular structure, namely, the bond between the water molecules is of dominant magnetic character, evidently with an inevitable component originating from electric polarizations. The view was based on various reasons, such as:

1) An inspection of the water molecule in its natural state as depicted in Figure 4.7, reveals that the orbitals of the H atoms do not have a spherical distribution, but instead have a toroidal one, thus possessing a natural magnetic field North-South along the symmetry axis. The same must occur for the orbitals of the corresponding valence electron of the O atom much along the Santilli-Shillady strong valence bond of Figure 4.5. It is then quite natural to interpret the bond between water molecules in the liquid state as caused by attractive, opposite, magnetic polarities North-South-North-South of the toroidal polarizations of the H and O orbitals, as in Figure 4.14.

2) All available valence electrons in the water molecule are strongly bonded, as established by the high value of energy needed for molecular separation. Consequently, any belief that the liquid state might originate from valence bonds is purely nonscientific. The water molecule is also neutral and, consequently, the sole use of electric polarizations as the entire origin of the bond for the water state fails to provide any quantitative representation of experimental data, such as the energy needed for the breaking of the liquid state into a gaseous form. These occurrences leave magnetic polarizations as the sole possible or otherwise plausible origin of the bond in the liquid state.

3) The breaking of the liquid state at the boiling temperature is a confirmation of its magnecular character, since all magnetic bonds cease to exist at a given temperature. As a matter of fact, the boiling temperature of water, 100o C, is the Curie temperature of the magnecular structure of liquid water.


Figure 4.14. A schematic view of the magnecular structure of the liquid state of water discovered by Santilli and presented in FHC. The magnecular structure can be confirmed via a mere inspection of the presence of magnetic fields in the natural state of the water molecule as in Figure 4.7, whose coupling via opposing polarities North-South-North-South results precisely in the magnecular structure of this figure.

In FHC Santilli provides experimental evidence obtained via Liquid Chromatographers Mass Spectrometers equipped with Ultra Violet Detectors (LC-MS/UVD, the equivalent for liquids of the GC-MS/IRD for gases) of the formation of various liquid magnecules via the use of magnetic fields, including a bond between oil and water. We regret to be unable to reproduce here this vast experimental evidence.

In FHC Santilli also presents evidence of solid magnecules, such as fullerines, consisting of hard carbon composites that sublimate at a sufficient high temperature, thus confirming the magnecular (rather than the valence) character of the bond. Additional examples of solid magnecules are given by certain calcium composites initiating with accretion, then bonding under pressure via magnetic induction, and finally resulting in the formation of a solid. Additional examples of gaseous liquid and solid magnecules are nowadays identified rather frequently.


Figure 4.15. The top picture depicts under a 10X magnification a liquid magnecule composed of a bond between fragrance oil and water, the lower picture showing its 100X enlarged view. The pictures were obtained by the Givaudain-Roure Research Laboratories in Dubendorf, Switzerland. It should be indicated that the bubbles are partially fragrance oil and partially water, while the magnecule is the entire dark area of the pictures, which area was transparent water prior to Santilli's formation of the magnecular bond. Therefore, liquid magnecules may have specific weights of 10,000 amu or more, and are generally visible to the naked eye. It is instructive to know that tests at the same laboratory via an LC-MS conventionally set to identify oil fragrance molecules, showed no presence at all of any magnecular species because the analysts refused to use the largest available feeding line. In so doing, the analysts prohibited the admission in the LC-MS of the very species to be detected. This occurrence, rather frequent for analysts whose mind remains set at molecular detections, is confirmed by the fact that the LC-MS did detect the fragrance oil and water, but failed to provide any detection at all of the dark liquid of the pictures.

In Table 8.31, page 371 of FHC, Santilli presents experimental measurements conducted by the SGS Testing Laboratory of Fairfield, NJ, according to which liquids and solids exposed to intense magnetic field exhibit an increase of their density. This important feature is currently under industrial development for the production, e.g., of carbon composites with increased specific weight that are of great importance for automotive and other applications.


4.4 INDUSTRIAL REALIZATION OF FUELS WITH MAGNECULAR STRUCTURE

4.4A. Catastrophic forecasts facing mankind

As it is well known, mankind is nowadays extremely dependent on petroleum fuels, with about one billion cars, five millions trucks, five hundred thousand planes in daily use, plus an unknown number of military, industrial and agricultural vehicles, with clear trends for rapid increase of fuel consumption.

As it is equally well known, world petroleum reserves and production either have already reached their peak, or their maximal capacity is only a question of a few years, with catastrophic risks for mankind due to the expected exponentially increasing costs under shortages of petroleum fuels, to such a level to cause disruptions of the very fabric of our societies, all the way to nuclear wars.

Only totally irresponsible people can sit and wait for these disasters to occur and do nothing, since NOW is the time to initiate corrective measures. Along these lines, the only possible, or otherwise credible way to prevent said catastrophes is to develop an alternative fuel that, as Santilli puts it, to be really effective, must verify the following::

CONDITION I: The alternative fuel must be suitable for use in existing engines without structural modifications, as a prerequisite to really have a serious control of our future. For instance, fuel cells operated car, while fully commendable, cannot provide a real solution because they cannot replace one billion existing cars prior to the indicated catastrophes. Similarly, hydrogen as a fuel for internal combustion engines, even though equally warranted for development, is not a solution because its use requires a structural change of existing engines, and similar occurrences hold for other alternative fuels.

CONDITION II: The alternative fuel must be produced from a widely available feedstock other than petroleum or food. This condition eliminates ethanol produced from corn and similar alternative fuels as viable alternatives. In any case, a large scale production of a fuel from food would cause per se catastrophic problems in food shortage, price, etc.

CONDITION III: The production of the alternative fuel must be energy efficient, in the sense that the energy content of the fuel must be bigger than the energy used for its production. This condition eliminates ethanol., hydrogen and other alternative fuels under their current production methods since their energy content is a fraction of the energy used for their production.

CONDITION IV: The alternative fuel must be cost effective as a necessary prerequisite for its actual use by individuals with consequential prevention of the indicated catastrophes. This condition eliminates ethanol, hydrogen and other fuels as a viable alternatives because they are currently more expensive than gasoline for the same energy content and are predicted to remain so under known production technologies..

CONDITION V: The alternative fuel must be environmentally acceptable on global grounds, including production, storage and combustion. This condition eliminates hydrogen as currently produced from fossil fuels or via the electrolytic separation of water under commercially available electricity because in both case the pollution caused by hydrogen production is bigger than that caused by gasoline production and combustion. Additionally, current methods for hydrogen production and combustion cause "oxygen depletion," one of the most serious environmental problems I introduced at the 2000 World Hydrogen Conference in Munich, Germany, consisting of the permanent removal of breathable oxygen in our atmosphere and its conversion into forms not usable for breathing. In fact, fossil fuel combustion converts O2 into CO2 that is no longer recycled by our plants due to the enormous volumes of daily production. Hydrogen is a beautiful fuel when is produced from:

1) Renewable energy sources, such as solar, wind or hydro-energy;

2) Via the electrolytic separation of water; under the additional condition that

3) The produced oxygen is freely released in the atmosphere for being recaptured by hydrogen combustion as a necessary condition to maintain the current oxygen percentage in our atmosphere.

By contrast, the oxygen produced in electrolytic separation of water is nowadays sold and used for fertilizers, food, metal cutting, and other uses none of which make oxygen available for hydrogen combustion. Under these conditions, hydrogen combustion causes a very serious oxygen depletion evidently given by the conversion of atmospheric oxygen into H2O, that is not appreciably recycled by plants into breathable oxygen also in view of the very large volume of water existing in our planet.

To understand the gravity of oxygen depletion, responsible individuals should note that we have accumulated in our atmosphere an estimated number of one billion tons of excess CO2 from fossil fuel combustion and hydrogen production. The O2 in CO2 was originally breathable oxygen and it is now no more. But O2 constitutes about 72 % of CO2. Therefore, we have eliminated from our planet an estimated number of 720 million tons of breathable oxygen.

In the event hydrogen is allowed to have a large scale automotive and other uses, because of the depletion of oxygen into CO2 caused by its current production plus the depletion of oxygen into H2O caused by its combustion, human life on Earth would be extinct in a few years because of the reduction of breathable oxygen below the level needed to sustain human life.

The understanding of Santilli's discoveries by responsible individuals requires the knowledge that his fuels with magnecular structure, generically called magnegases, are the only known fuels meeting Conditions I-V while being industrially available NOW. Additional understanding of the societal relevance of Santilli's discoveries will be presented in the next chapters in relation to truly new and clean energies.


4.4B. Santilli hadronic reactors (1998)

Submerged electric arcs were discovered in the 19th century for the repair of metal ships. The production of a gas and its combustible character were discovered at the same time by sailors who used to lit up the gas emerging from underwater welding and called it "fire on water." The clean burning character of the gas was also known at that time. Despite the above promising features, submerged electric arcs did not reach industrial relevance for the production of a combustible gas since their discovery in the the 19th century until Santilli's studies in the late 1990s.

Recall from Section 4.3 that Santilli had selected submerged electric arcs for the production of his new magnecular species. Therefore,. he initiated the systematic study of submerged electric arcs in 1998. By proceeding with his typical analytic method, Santilli first identified the main limitations of submerged electric arcs, and then conducted systematic theoretical and engineering studies for their resolution by using his knowledge of hadronic mechanics and chemistry.

In essence, electric arcs submerged within a stationary liquids have a very low Efficiency E defined as the ratio between the volume V in scf of gas produced and the electric energy Eelec needed for its production expressed in Wh

(4.28 ) E = V / Eelec.

Elctric arcs between carbon electrodes are indeed very efficient in the separation of water molecules by producing a plasma of mostly ionized H, O and C atoms around the electrode tips. However, the passage of the arc through the H and O atoms causes their combustion into H2O via an implosion, thus resulting in a very low efficiency E, with consequential excessive cost for the combustible gas, because most of the separated water molecules are then recombined.

Stationary submerged electric arcs have additional shortcomings, such as the production in the plasma of an excessive percentage of CO2, measured up to 18 % prior to combustion (and 27 % in the combustion exhaust), due to the synthesis of CO in the presence of O atoms while being traversed by the arc.

Santilli conducted systematic engineering studies for the resolution of the above insufficiencies by developing a new method called PlasmaArcFlow (PAF, patented and international patents pending), consisting in continuously flowing the liquid feedstock through the arc, then controlling the cooling down of the plasma in the surrounding liquid, and controlling the formation of the combustible gas with magnecular structure, while the latteris cleaned by its bubbling through the liquid. This new PAF process does indeed allow the production of a clean burning, cost competitive magnecular gas ready for combustion at the time of its production without any need for additional refining.

PlasmaArcFlow Refineries are known scientifically as Santilli hadronic reactors because of their conception and engineering realization via the use of hadronic mechanics and chemistry due to excessive divergences between the predictions of quantum theories and experimental data outlined in Figure 4.16 and Chapter 6. In this respect, Santilli states:

As an editor of various journals, I continue to receive papers to this day attempting to represent the structure of the hydrogen atom with Newtonian mechanics despite the availability for about one century of its exact quantum solution. Therefore, it is very easy to predict that the manifestly nonlinear, irreversible and non-Hamiltonian processes caused by submerged electric arcs will indeed continue to be studied with the manifestly linear, reversible and Hamiltonian special relativity and quantum mechanics, despite the availability of numerically exact and invariant solutions via the nonlinear, irreversible and non-Hamiltonian genomechanics, thus resulting in the mere illusion of serious research.


Figure 4.16. A beautiful picture of a DC electric arc between graphite electrodes submerged in distilled water that constitutes, jointly with the valence and other events, a case of clear inapplicability of 20th century theories. To begin, Maxwell's equations and special relativity are certainly applicable to an arc in vacuum (or at best in air), but they are fundamentally inapplicable for the same arc when submerged in water because of the impossibility of representating: the dielectric character of water; the existence of the longitudinal, attractive, Ampere force between the two electrodes (that is basically incompatible with Maxwell's equations); the collapse of the resistance under a closed arc; and other aspects. Similarly, quantum chemistry predicts that the gas produced under the considered conditions is composed of close to 50% hydrogen and 50% carbon monoxide plus traces of carbon dioxide and other substances, a prediction that is dramatically disproved by GC-MS analyses (see Figure 4.12). Additionally, quantum, chemistry predicts the absence of oxygen in the exhaust, while experimental measurements show the presence in the exhaust of up to 14 % breathable oxygen, plus having additional deviations from quantum predictions with errors of the order of at least ten time the experimental data (see FHC for details). Hadronic mechanics and chemistry have resolved these insufficiencies for which reason the equipment producing magnecular gases via submerged electric arcs are called "Santilli hadronic reactors."

A main feature of Santilli hadronic reactors is their high efficiency with an energy output that is a multiple of the used electric energy. This important feature is due to the fact that the primary source of energy of hadronic reactors is not the electric energy of the arc, but carbon combustion in the plasma. As a matter of fact, Santilli conceived his reactors for the primary purpose of developing a new, cleaner and more efficient carbon combustion.

In the plasma of an electric arc between carbon electrodes submerged in water we have all chemical reactions of the conventional combustion of carbon in air, such as the synthesis of CO with the release of 288 Kcal/mole, the synthesis of CO2 with the release of 87 Kcal/mole, and others. Additionally, in the plasma of hadronic reactors we have the synthesis of H2 with the release of 110 Kcal/mole that does not occur in conventional carbon combustion in air, thus showing that Santilli's combustion of carbon in the plasma of an arc has a bigger energy output of the combustion of the same carbon in air. The environmental qualities of a carbon combustion via a submerged arc is evident because all solids and liquid contaminants are trapped in the liquid and then eliminated by the arc.

To study these aspects, Santilli has introduced first the Scientific Efficiency (SE) of hadronic reactors given by the total energy output (as the sum of the energy in the gas Egas plus the heat acquired by the liquid Eliquid) divided by the total energy input (as the sum of the used electric energy Eelectr and the energy of carbon combustion Ecarb), which Scientific Efficiency is always smaller than 1, and we write

(4.29) SE = (Egas + Eliquid) / (Eelectr + Ecarb) smaller than 1.

However, hadronic reactors recycle liquid wastes that are generally very rich in carbon, such as engine oil waste, cooking oil waste, etc. In this case, the carbon brings an income, rather than carrying a cost. As a result, Santilli introduced the Commercial Efficiency (CE) given by the Scientific Efficiency without the carbon energy in the denominator. Since the latter is a large multiple of the electric energy (see FHC for details), it is then evident that the Commercial Efficiency is much bigger than 1, and we write

(4.30) CE = (Egas + Eliquid) / Eelectr bigger than 1.

In fact, small hadronic reactors (say with 50 kW) have a Commercial Efficiency of the order of 5, namely, for each unit of electric energy input, the reactors produce up to five units of energy output as a combination of thermal energy in the combustible fuel and heat acquired by the liquid feedstock.




Figure 4.17. Views of some of the various hadronic reactors built by Santilli for pure research purposes. The top view shows the first manually operated hadronic reactor built in late 1998 to test the PlasmaArcFlow principle with minimal costs. Because of encouraging results, Santilli built a series of sequentially improved research reactors to test the various aspects of the new technology, the middle picture showing a completely automatic 50 Kw hadronic reactor built in 2001. Numerous additional research reactors followed. The bottom pictures shows a large 500 Kw research reactor built in 2005 and still used by Santilli for various tests, particularly those of nuclear character outlined in Chapter 6 (the bottom pictures shows from the left Santilli and three of his technicians: Michael Rodrigujez, John T. Judy, and Eugene West).

As we shall see in Chapter 6, the above high efficiency cannot be numerically explained via the sole use of conventional chemical reactions, such as the synthesis of CO, CO2, etc., and requires the admission of novel nuclear processes, that, if properly enhanced, can give an energy output 50 times ot more the used electric energy.

In regard to cost of the magnegas fuel produced with hadronic reactors, we recall that, in their industrial version with a minimum of 300 Kw power, operating in the "total mode" at a minimum pressure of 100 psi, at the temperature of 200o F while processing an oil-base liquid feedstock, hadronic reactors require approximately 70 W = 220 BTU of electricity for the production of 1 scf of fuel with about 900 BTU/scf, plus 300 BTU of heat acquired by the liquid feedstock with a total CE = 5.95, the excess energy originating from the chemical and nuclear reactions in the plasma of the hadronic reactor.

One gasoline gallon contains about 110,000 BTU. Therefore, the Gasoline Gallon Equivalent (GGE) of magnegas is given by 110,000/900 = 122 scf. The production of one GGE of magnegas requires 122 x 70 W = 8.5 kWh that, at the current rate of $0.08/kWh yields the electricity cost of $0.68/GGE.

The computation of the total direct cost of one GGE of Magnegas requires the addition of 30% for other direct costs, including carbon electrodes, service and amortment of purchase prize over 15 years, yielding the total direct cost of $1.08 per GGE, less the income for the recycling of the liquid waste that generally reduces considerably the direct costs and, in certain special case, can be bigger than the direct cost.


4.4C. Industrial realization of MagneGas fuel (1998)

Following the above basic research, Santilli conducted systematic engineering work for the optimization of the PAF method and industrialization of the process into completely automatic and remote controlled PlasmaArcFlow Refineries of various dimensions and powers for the gasification of a variety of liquid wastes into MagneGas fuel of which he introduced the name as well as the chemical symbol MG.

In so doing, Santilli obtained the U.S. Patents 6,926,872, 6,673,322, 6,663,752, 6,540,966, and 6,183,604 whose study is suggested for any in depth knowledge of this new technology. A U. S. corporation was set up with public listings of its stock that is now in production and sale of MagneGas in the American continent, Magnegas Corporation with affiliated companies for the development of the Magnegas Technology in India, Europe, Australia and other countries.




Figure 4.18. A view of various industrial hadronic reactors built by Santilli: the top view shows a 50 Kw MagneGas Refinery on a trailer operated by Richard Lyons, one of Santilli's technicians; the middle view shows a 100 Kw refinery on a trailer operated by John T. Judy; and the bottom view shows the PlasmarcFlow Module of a 500 Kw floor mounted industrial Magnegas Refinery.

MagneGas does indeed verify Conditions I-VI of Section 4.4A for an effective progressive replacement of petroleum fuels in view of the following main aspects:

1. MagneGas can be effectively used in all existing gasoline engines (see Picture 4.19 on various cars currently using magnegas);

2. MagneGas is produced from liquid waste available everywhere in unlimited volumes, such as engine oil waste, cooking oil waste, city, farm and factory liquid wastes, etc;

3. MagneGas production is energy efficient, because its energy content is bigger than the electric energy needed for its production, as outlined in the preceding sections via the notions of Scientific and Commercial Efficiencies;

4. MagneGas is less expensive than fossil fuel when produced in sufficient volume by assuming an income for the recycling of the liquid waste, as also outlined in the preceding section;

5. Magnegas is environmentally acceptable because it admits complete combustion, thus having no HC, CO or other contaminants in its exhaust (see Figiure 4.20).

Additionally, one should bear in mind that MagneGas is industrially available now. In fact, it is in regular production and sale in various countries. For additional information, one may visit the following links:

Fox News video on the Magnegas Technology

Video by Dunedin Water Treatment Plant

Invited presentation at the United Nations

Video by Magnegas Corporation





Figure 4.19. A view of some of the numerous cars prepared by Santilli to operate on MagneGas. The picture from the top shows Santilli with a Ferrari 308 GTSi 1981 he converted to operate on MagneGas while being tested in 2001 at various Florida race tracks, including Sebring, Moroso and others, to show that the car accelerates faster and revs higher than the same car running on gasoline due to the high octane of MagneGas (about 130), the lower temperature of the combustion exhaust (about 30% lower) due to about 50% of water vapor in the same exhaust, and other factors. The middle picture shows a Ford Contour 1999 bifuel (namely, operating on gasoline and natural gas, with a switch on the dash for the change of fuel), operated on MagneGas in lieu of natural gas without any change, while being tested at the Race Track in Monza, Italy, in June 2008. The bottom picture shows a Chevrolet Suburban 1994 produced for the sole operation on gasoline, with the additional equipment needed to operate on MagneGas that is daily used by Santilli, gasoline being used for refueling when MagneGas is depleted.

As Santilli puts it: During WWII, Germany had no major petroleum reserves and synthesized most of its fuel in both their gaseous and liquid forms for use in cars, tanks as well as airplanes. In fact, the catalytic liquefaction of gaseous fuels, today called Fisher-Tropsch, was discovered in Germany during that period. A country synthesizing its fuels to fight the rest of the world some sixty years ago is incontrovertible evidence that, today, some sixty years later, our dependence on petroleum fuels is a purely political occurrence, since there is no possible or otherwise credible doubt on the technical capability today by any country achieving fuel independence.


Figure 4.20. A picture of the reading of an exhaust analyzer showing the combustion exhaust of the cars of the preceding figure, the exhaust being sensed at the manifold, thus prior to the catalytic converter. The data show the main characteristic of MagneGas of being a fuel with complete combustion, thus without contaminants in the exhaust. In fact, MagneGas exhaust is composed of about 50% water vapor, 12% to 14% breathable oxygen, 5% to 7% carbon dioxide, and the rest is given by atmospheric gases. We should note that the detected HC originate from the seepage of engine oil through the piston rings in a rather old car, since MagneGas is produced at 10,000 degrees C at which temperature no HC can survive. Similarly, CO is produced by the combustion of fossil fuels, while CO is a fuel component for MagneGas. Therefore, any presence of CO in the MagneGas exhaust is equivalent to the presence of gasoline in the exhaust of a gasoline operated car, namely, both are evidence of lack of proper combustion (for detail see the quoted specialized literature).

4.4D. Industrial realization of the HHO fuel (2006)

Another fuel with a magnecular structure studied in detail by Santilli is that produced via a special electrolyzer that turns distilled water into a very powerful, combustible, and gaseous form for which he introduced the chemical name of HHO. Prior to Santilli's studies, a similar gas was known under the name of Brown gas but referred to a perfect stochiometric mixture of 2/3 ordinary hydrogen and 1/3 ordinary oxygen gases.

However, Santilli showed that a 70-30 mixture of H2 and O2 does not possess the special features of the HHO gas, such as that of instantaneously melting tungsten and bricks at flame contact. Hence, he conducted systematic experimental measurements establishing that at least a percentage of the HHO gas has a magnecular structure. Such a percentage is then crucial for the stability of the gas, e.g., to avoid the perfect stochiometric ratio of hydrogen and oxygen for selfcom,bustion. The results of the studies have been reported in the historical paper (we cannot possibly review here for brevity)

A new gaseous and combustion form of water
R. M. Santilli,
Intern. J. Hydrogen Energy Vol. 31, pages 1113-1128 (2006)

It should be stressed that, due to two years of delays between the date of acceptance of the above paper and that of its publication, a considerable confusion resulted and the above quoted printed version is NOT the final version approved by Santilli but that of uncorrected galleys with several garblings such as those in the symbols as well as misprints. For the correct version, we refer the reader to the monograph

The New Fuels with Magnecular Structure
Ruggero Maria Santilli

International Academic Press (2008)
200 pages
Italian translation by Giovanna Bonfanti and Michele Sacerdoti, published by Editori Riuniti, Roma, Italy, and available at
I Nuovi Carburanti con Struttura Magnecolare



Figure 4.21. Experimental evidence of the magnecular structure of the HHO gas: a printout of the blank following completion of the scans with a GC-MS and removal of the gas from the instrument. For all conventional molecular gases, the black solely shows background data none in macroscopic percentage. By contrast, the blank of this figure is essentially similar to the ordinary scan under the precautions indicated in Section 4.3 (sufficiently large feeding line, low column temperature, longest possible elusion time, etc.). Since the HHO gas was removed from the instrument, the above printout establishes the magnecular character of the gas via its anomalous adhesion to the walls of the instrument. Additionally, the scan shows a number of species in macroscopic percentage other than H2 and O2 that can only be explained as magnecular clusters comprising combinations of H or O, HO, H2, O2, and H2O, since the gas originates from distilled water.

The research herein considered was conducted by Santilli as a scientific consultant of the American company Hydrogen Technology Applications, Inc. which company is the owner of all intellectual rights and is currently producing and selling the HHO gas on a world wide basis under the commercial name of AquygenTM. More details can be obtained from the website

Hydrogen Technology Applications, Inc.


4.4E. Industrial realization of MagneHydrogen fuel (2003)

Santilli has been very supporting of hydrogen as a fuel to such an extent that he dedicated years of research to the field. In particular, he supports the environmentally acceptable production and combustion of hydrogen consisting of:

1) Hydrogen should be produced via clean renewable sources of electricity, such as those of wind, solar of hydro-origin;

2) The clean electricity is used for the electrolytic separation of water; and, above all,

3) The oxygen produced in the process is released in the atmosphere so that the combustion of hydrogen reacquires said oxygen by mantaining unchanged the oxygen balance in our planet.

In reality, the current production and use of hydrogen is dramatically different than the above sound environmental lines, by causing the following serious environmental problems:

A. Hydrogen is generally produced from electrolytic separation of water via currently available, environmentally unacceptable sources of electricity. Alternatively, hydrogen is produced via the reformation of fossil fuels that notoriously cause a pollution bigger than that caused by gasoline combustion. Since the energy needed for hydrogen production is bigger than its energy content, under the condition here considered there is no real environmental or other gain in the use of hydrogen as fuel.

B. In case hydrogen is produced from the electrolytic separation of water, the produced oxygen is captured and sold for various scopes, rather then released in the atmosphere, in which case the oxygen balance in our plan et is lost at the time of oxygen combustion. For instance, when oxygen is sold for metal cutting, it is turned into iron oxides. Consequently, the combustion of hydrogen, whether in an engine or a fuel cell, causes oxygen depletion (Section 4.4A), namely, the permanent removal of breathable oxygen from our planet and its conversion into water vapor.

C. Assuming that the above environmental aspects are solved, hydrogen remains with serious additional problems, such as that of seepage through the walls of containers due to its extremely small size, thus causing known storage problems.

D. Hydrogen is the ligthest gas in nature. Therefore, when released in the atmosphere due to seepage or other reasons, it rises very rapidly to the ozone layer where it causes the additional environmental problem called ozone depletion, namely, the permanent removal of ozone from our atmosphere with consequential increase of skin and other forms of cancer, due to the very fast chemical reaction (that has no equivalent for other fuels and their exhaust)

(4.31) H2 + O3 → H2O + O2

E. Additionally, hydrogen has a limited amount of energy content, thus causing known storage problems to reach a desired range. In fact, hydrogen has 300 BTU/scf., while gasoline has about 110,000 BTU/g. Consequently, the Gasoline Gallon Equivalent (GGE) for hydrogen is 110,000/300 = 360 scf. It then follows that to reach the same range of a tank with 30 gallons of gasoline, there is the need of 30 x 360 = 10,800 scf, namely, a volume of hydrogen so large that it cannot be effectively stored in a car. This limitation has requested the cryogenic liquefaction of hydrogen by some automakers, which liquefaction renders the cost of hydrogen simply prohibitive for the foreseeable future since hydrogen liquefies close to the absolute zeros degree temperature. Additionally, hydrogen must be continuously maintained at the liquid state irrespective of whether the car is used or not, thus causing additional costs as well as danger in the event the on board cryogenic system fails, since in this case there is an explosive transition from the liquid to the gas form due to the very fast change of volume, rather than combustion.

With his typical research style, Santilli addressed systematically all the above problems and searched for their solution in support of hydrogen as a fuel. Firstly, he developed the MagneGas Technology also in support of hydrogen since MagneGas contains a minimum of 60 % hydrogen in a mixture with other gases, thus being of easy separation via membranes or other separation processes. This new form of hydrogen production has numerous advantages over conventional producton, such as:

I) An acceptable energy efficiency, since the energy needed for hydrogen production is smaller than its energy content thanks to the very high efficiency of hadronic reactors, thus alleviating the use of environmentally unacceptable electricity for hydrogen production;

II) A significant reduction or elimination of oxygen depletion, because MagneGas is rich of oxygen originating from liquids, rather than from the atmosphere; and

III) A major reduction or elimination of the ozone depletion, because the hydrogen produced from MagneGas has no seepage due to its magnecular structure that seals the walls of all containers via layers of atoms bonded by magnetic induction, as established by various tests.

Additionally, Santilli developed yet another fuel with a magnecular structure under the name of MagneHydrogen, today known under the chemical symbol MH. The objective was to avoid the cryogenic liquefaction of hydrogen via the increase of its specific weight because, in the event the specific weight of hydrogen can be increased by a factor of 3, the "heavy" species of MH would reach an energy content equivalent to that of natural gas, thus avoiding any need for cryogenic liquefaction, with evident benefits for the hydrogen industry, such as dramatically reduced costs, increased range, etc.

As it is well known, there is no possibility of increasing the specific weight of hydrogen under a valence bond because valence electrons couple in pairs, resulting in the conventional molecular structure H2 = H-H with specific weight 2.016 amu. By contrast, magnecular bonds have no theoretical limit in the number of bonded atoms, the limit being set by the temperature and other conditions. It is then evident that the only possibility for increasing the specific weight of hydrogen is that via magnecular bonds, hence the name of MagneHydrogen.

Santilli also searched for means to produce a form of MagneHydrogen with specific weight bigger than 2.016 amu. Following various trials and errors, he developed a process consisting in passing MagneGas through a zeolite selected for hydrogen purification; collection the hydrogen released; and then passing it again at pressure through the same zeolite seven consecutive times. The species of hydrogen produced in this way resulted to have about seven times the specific weight of conventional hydrogen (see Figure 4.22 for more details).

The research herein outlined was conducted by Santilli as scientific advisor of the U. S. corporation Clean Energies Tech, Inc. that is the sole owner of all intellectual rights. A vast industrial effort is under way at this writing (Spring 2009) to organize the industrial production of MagneHydrogen.



Figure 4.22. The measurements of the new species of MagneHydrogen (MH) produced under Santilli's directions by independent U. S. laboratories, whose directors released signed statements that have been included in the historical paper of 2003 quoted below. As one can see, the top measurements indicates that the species is composed of 99.2 % hydrogen while having the specific weight of 15.06 amu, that is, 7.4 times that of hydrogen. This evidence seals in a final and incontrovertible way the existence of Santilli magnecules, by disqualifying as nonscientific any theoretical or theological doubt since only a basically new species, that is, a species with a basically new bond other than the valence, can provide a credible representation of the results.

To clarify the discovery, the hydrogen collected following the first passage of MagneGas through the zeolite is expected to have indeed a magnecular structure, but with a minimal increase of the specific weight over that of the hydrogen. The subsequent passages of the species through the same zeolite essentially cause the accumulation under pressure of polarized hydrogen clusters along opposite polarities North-South-North-South-..., resulting in a sequence of magnecular clusters of the type

(4.32) MH1 = H,

(4.33) MH2 = H-H + HxH,

(4.34) MH3 = (H-H)xH + HxHxH,

(4.35) MH4 = (H-H)x(H-H) + Hx(H-H)xH + HxHxHxH, etc.

whose main limitation is that of their breakdown due to collisions caused by temperature.

The main reference of the discovery of MagneHydrogen is the additional historical paper of 2003 whose pdf file contains copies of the signed laboratory reports

The novel magnecular species of hydrogen and oxygen with increased specific weight and energy content
R. M. Santilli,
Intern. J. Hydrogen Energy Vol. 28, 177-196 (2003)

as well as the monographs previously quoted.


4.4F. Molecular and magnecular combustions (1998)

Yet another branch of quantum chemistry that was never accepted by Santilli as of final character is that pertaining to conventional combustions, with reference to statements, e.g., that the combustion of hydrogen and oxygen yields 57.5 Kcal/mole,

(4.36) H2 + O2/2 → H2O + 57,5 Kcal/mole.

Santilli's argument is that the two H-atoms are widely and permanently separated in the H2O= H-O-H molecule, as clearly shown in Figure 4.7. Therefore, he argues that the combustion of hydrogen and oxygen releases much more energy than 57.5 Kcal/mole, the biggest portion of which is used by nature to separate the H2 = H-H and the O2 = O-O molecules, and the measured amount of 57.5 Kcal/mole is merely the small final energy residue.

In fact, we have the following well established and known separation energies

(4.37) H2 → H + H - 104.2 Kcal/mole,

(4.38) O2/2 → (O + O)/2 - 119.1/2 Kcal/mole

Consequently, in Santilli's view, the belief that the combustion of hydrogen and oxygen solely produce 57.5 Kcal/mole violates the sacred principle of conservation of the energy since separations (4.37) and (4.38) would then occur by academic fiat and not via physical or chemical laws.

Santilli argues that, as a necessary condition to verify the principle of conservation of the energy, the combustion of hydrogen and oxygen must produce 221.25 Kcal/mole (rather than the claimed 57.5 Kcal/mole) so as to provide the energy necessary for the separation of H2 and O2 plus the 57.5 Kcal/mole residue, according to the combustion law for molecular hydrogen and oxygen

(4.39) H2 + O2/2 → (H + H) + (O + O)/2 + 221.25 Kcal/mole - 104.2 Kcal/mole - 59.5 →

→ H2O + 57.5 Kcal/mole.

Once the real combustion law has been understood, it is easy to see the environmental and industrial importance of Santilli's fuels with magnecular structure because they contain individual atoms under a bond weaker than the valence bond. Therefore, magnecular fuels yield an energy output greater than that of molecular fuels with the same of atoms. To clarify these new combustions notions, Santilli has introduced the following definitions:

MOLECULAR COMBUSTION: is that for fuels whose atoms are entirely under a molecular bond, such as hydrogen. methane, gasoline, etc.

MAGNECULAR COMBUSTION: is that for fuels whose atoms are at least in part, under a magnecular bond, and the rest under a molecular bond, such as MagneGas, HHO, MagneHydrogen and others.


Figure 4.23. A picture of MagneGas produced from distilled water with 70% H-atoms, 30% O-atoms and 30% C-atoms that cuts a 2" (5 cm) thick metal place at double the speed of acetylene. The belief that said MagneGas has a conventional molecular structure would imply the gas to have 236 BTU/scf, while acetylene possess 2,400 BTU/scf, thus exiting the boundaries of science in favor of theologies. The sole possible quantitative interpretation is that the MagneGas here considered has Santilli's magnecular structure with a percentage of atoms being weakly bounded, thus ready for combustion, plus toroidal polarizations of the orbitals discussed in the text.

The superior energy output of magnecular fuels with respect to molecular fuels with the same atomic composition is beyond any possible or otherwise credible doubt. Consider, for instance, MagneGas produced from distilled water that contains 70% H-atoms, 30% O-atoms and 30% C-atoms, plus impurities in ppm here inessential. Recall that H2 contains about 300 BTU/scf, while CO contains about 89 BTU/scf. Consequently, the fuel with conventional chemical composition of 70% H2 and 30% CO contains (0.7 x 300 + 0.3 x 89) BTU/scf = 236 BTU/scf. It is beyond doubt that such a molecular fuel cannot possibly cut metal faster than acetylene, as any skeptic is requested to verify experimentally, as Santilli does, prior to venturing nonscientific theologies.

By comparison, the gas with the same atomic structure, but with a magnecular structure as currently in production and sale, cuts metal at double the speed of acetylene that contains 2,400 BTU/scf. Any continued belief on the dominance of the valence bond for all possible substances existing in the universe until the end of time, causes the existing of quantitative science and the passage to theologies. The only possible explanation of the energy output of MagneGas being bigger than acetylene is that via Santilli's principles of combustion based on the presence individual atros under a wek bond..

A fully similar situation occurs for the HHO gas that, according to quantum chemistry, should contain 210 BTU/scf, namely, an output of energy immensely insufficient for the instantaneous melting of tungsten and bricks. The same excess energy output occurs for MagneHydrogen and all gases with Santilli magnecular structure.


Figure 4.24. In the year 2000, Santilli tested hydrogen separated from MagneGas in an experimental fuel cell and obtained the increase of power output shown in the above picture. Similar increases of power were obtained via a conventional hydrogen treated with a special PlasmaArcFlow gaseous hadronic reactor (patented and international patnts pending). The principle of the increased power is precisely that of Santilli's magnecular combustion and it is due to the substantial decrease of energy lost in molecular separation, thus yielding a greater energy output. The above tests were halted by Santilli because of extreme lack of interest by all fuel cell industries and laboratories he contacted, due to the widely adopted belief in academia and industry according to which, as Santilli's puts it: "Novelty does not exist; novelty cannot exist; and if novelty is proposed for test, it is a fraud." At any rate, the above scan as well as numerous others have been available in the internet since 2000 and no fuel fell industry has shown to date any interest whatsoever in even considering the verification or denial of a substantial increase of their energy output via the use of Santilli magnecular fuel, nowadays widely known in academia and the industry. Because of this lack of interest, Santilli left the fuel cell industry essentially to its own state, that of the past century.

To initiate a quantitative analysis, A. K. Aringazin and R. M. Santilli assume that the H-atom is bonded magnecular with a yet unknown value of s Kcal/mole. Therefore, we have the following data for the combustion of MH2 = HxH in oxygen

(4.40) HxH → H + H - s Kcal/mole,

(4.41) O2/2 → (O + O)/2 - 59.55 Kcal/mole,

(4.42) HxH + O2/2 → H2O + (161.7 - s) Kcal/mole,

where one should keep in mind that the value s = 0 is expected at the combustion temperature.

It is easy to see that all mixtures of molecular H2 and magnecular MH2 yield a combustion energy output bigger than 57.5 Kcal/mole. As an example, a mixture of 10% MH2 and 90% H2 would yield (62.71 - s) Kcal/mole. For more details, we refer the interested chemist to

Rudiments of molecular and magnecular combustions
A. K. Aringazin and R. M. Santilli,
Preprint of the Eurasian University (2009) to be published

It should be stressed that the studies on Santilli's magnecular combustion are just at their infancy. For instance, Santilli stresses that the sole energy output of reactions (4.39), (4.42) remains basically insufficient to explain quantitatively how MagneGas cuts metal faster than acetylene. This requires additional studies, not only on the presence of weakly bounded atoms, but also that such atoms have a toroidal rather than spherical polarization, since solely the latter may explain the very fast penetration of hydrogen within the deep layers of steel, with consequential melting and cutting much faster than acetylene whose molecules remain at the surface due to their size.


4.5. SANTILLI DISCOVERY IN BIOLOGY

4.5A. Historical notes

There is no doubt that Santilli achieved his most advanced discoveries in biology whose foundations are outlined in the monograph

"Isotopic, Genotopic and Hyperstructural Methods in Theoretical Biology"
R. M. Santilli,
Ukraine Academy of Sciences (1997)

In this section we shall attempt a conceptual review of these advances with the understanding that such a task is faced with serious difficulties due to the complexity of the conceptions as well as of the mathematics used for their quantitative treatment. Another difficulty of this review is that Santilli has not published a number of advances in biology that have been made available to us as notes not completed for publication, although we have been told that the completion of these papers and their publication are expected in the near future.

On historical grounds, Santilli has been one of the leading scientists to establish the basic insufficiencies of quantum mechanics and chemistry for biological structures. As he puts it: Any belief of conducting serious quantitative studies of biological structures with quantum mechanics and chemistry raises issues of scientific ethics and accountability because first year graduate students know that said theories predict biological entities to be perfectly rigid, perfectly eternal and with no reproductive capacity. Therefore, the selection of the applicable "generalization" of quantum mechanics and chemistry should indeed be subject of scientific debates, but not its need.

It is our opinion that the year 1997 of publication of the above quoted monograph will be remembered by ethically sound scholars as signaling the transition from rudimentary studies in biology to fundamentally new and dramatically more complex scientific vistas with truly vast horizons and outcome beyond our predictive capacity.

In closing, Santilli has requested to remember Prof. Bakunin, the lady who taught him organic chemistry at the University of Naples, Italy, during his undergraduate studies in the 1950s, since his interest in biology originated from her teaching.


4.5B. Deformability, irreversibility, and multi-valuedness of biological structures.

The first and perhaps most important contribution by Santilli to biology has been the identification of the following main characteristics of biological structures, which identification sets the basis for the discovery of the generalized mathematics needed for quantitative treatments:

DEFORMABILITY. Santilli often initiates lectures in the field by squeezing in front of the audience a small rubber ball and stating: This simple deformation of a rubber ball is incompatible with special relativity and quantum mechanics because it violates their central pillar, the rotational symmetry, from which there is a consequential inevitable violation of the Lorentz symmetry. He then moves his fingers and states: A main feature of biological structure is deformability requiring a dramatic departure from the 20th century theories. In the absence of a theory representing deformability from its main axioms, we know today that no invariant quantitative treatment is possible..

IRREVERSIBILITY. Santilli then projects in the lecture screen a representative biological event, such as the birth and death of a flower, and states: Yet another main feature of biological structures is their irreversibility over time. This feature, alone, is sufficient to rule out all dominant theories of the 20th century, since they were conceived , developed and tested to represent systems reversible over time, such as the structure of nuclei, atoms and molecules. Again, without methods that are irreversible in their basic axioms, we merely have the illusion of quantitative studies in biology.

MULTI-VALUEDNESS. Santilli then recalls the studies by the Australian biologist Chris R. Illert who showed that a three-dimensional Euclidean space can indeed represent all shapes of seashells, but the computerized use of the same space to represent the growth of seashells causes the latter first to grow in a deformed fashion and then crack. Santilli then states: The basic axioms of the Euclidean space at the foundation of the 20th century theories not only provide an axiomatization of perfect rigidity and reversibility, but also the representation axes are single valued, that is, they grant one single value for each point. By comparison, Illert has shown that a more accurate representation of the growth of seashells occurs via the use of a six-dimensional space, that is, a space in which each axis is doubled. It is evident that, when passing from the relatively "simple" seashells to complex bio;logical structures such as a DNA, the number of dimensions needed for a quantitative treatment may become beyond our intuitional capacities. For more details, one should consult Illert's contributions in the monograph

"Foundation of Theoretical Conchology"
C. R. Illert and R. M. Santilli,
Hadronic Press (1995)



Figure 4.25. A conceptual rendering of Illert's representation of seashells growth with the doubling of the Euclidean reference axes.


4.5C. Representation of biological structures via Santilli's deformable, irreversible and multi-valued hypermathematics

Illert's doubling (in 1995) of the three Euclidean axes for the representation of seashells growth motivated the discovery in 1996 by Santilli of hypermathematics presented in the historical mathematical memoir

Nonlocal-integral isotopies of differential calculus, mechanics and geometries
R. M. Santilli,
Rendiconti Circolo Matematico Palermo, Suppl. Vol. 42, 7-82 (1996).

and summarized in Chapter 2. As Santilli's put's it: When we observe a seashell in our hands, we can fully perceive its growth via our three Eustachian lobes. The sole way to reconcile the six-dimensionality of seashell growth with our three-dimensional sensory perception is via a hyper-Euclidean space with three dimensions in which each axis is two-valued. At the abstract, realization-free level, there is no distinction between the two-valued hyper-Euclidean space and the conventional space, thus allowing our senses to perceive the seashell growth in three dimensions. By contrast, the use of a six-dimensional space would lead to irreconcilable incompatibilities between the mathematical representation and our perception of reality.

Additionally, the multi-valued hyperspace must be irreversible as a necessary condition not to violate causality. This requirement can be implemented via the adoption of Santilli's multi-valued genospaces, as presented in the above quoted mathematical memoir and outlined in Chapter 2. As the reader will recall, irreversibility is set at the most primitive level, the basic hyperunits, that are different for different directions of time, thus assuring lack of violation of causality.

Once a multi-valued irreversible genospace is assumed as the carrier space, the invariant representation of deformations follows from Santilli's multi-valued hyperrotational symmetry, namely, the isorotational symmetry at the foundation of isorelativity and hadronic mechanics (Sections 3.10 and 3.11) in which the basic isounits are first differentiated for motions forward and backward in time, and then they are assumed to be multi-valued. The invariant representation of deformability under multivaluedness then follows, jointly with the bypassing of the Theorems of catastrophic Inconsistencies outlined in Section 3.7.

A comprehensive study of the isorotational symmetry and related isotrigonometry is available in the following monographs

"Elements of Hadronic Mechanics", Vol. I: "Mathematical Foundations"
R. M. Santilli
, Ukraine Academy of Sciences (1993),

"Elements of Hadronic Mechanics" Vol. II: "Theoretical Foundations"
R. M. Santilli,
Ukraine Academy of Sciences (1994)

The deformable, irreversible and multi-valued hyperrotational symmetry is then achieved via the reformulation of isomathematics into the hypermathematics outlined below.

We assume the reader is aware of the differences between Santilli's hypermathematics and the conventional hyperstructures. Both are multi-valued, but the former consists of a comprehensive, multi-valued irreversible lifting of the entire mathematics, including units, numbers, spaces, symmetries, algebras, geometries, topology, etc., all based on conventional operations. By contrast, hyperstructures are generally reversible over time, are based on abstract hyperoperations and do not possess left and right units, under which conditions there is no direct and consistent application to experimental measurements.

For clarity, hypermathematics that can be outlined, separately, for hypertimes and hyperspaces.

SANTILLI HYPERTIMES
The need for the representation of biological structures via Santilli deformable, irreversible and multi-valued hypermathematics has been confirmed by various different approaches. One of them is by identifying the notion of time needed for biological structures. Illert has shown that a necessary condition for a seashell to form bifurcations is to master all directions of time that, contrary to popular belief, are four, being given by: motions forward and backward in future time and in past times.


Figure 4.26. The slicing of a small seashell showing the various bifurcations despite its small size. The notion of time needed for a quantitative representation of the construction by the seashells of all these bifurcations is so complex to be truly beyond human comprehension. It can be represented via Santilli's hypertime consisting of the ordered set of four motions in future and past time, each one being multi-valued.


The sole known rigorous representation of the above occurrence is via Santilli multi-valued hypermathematics and its isodual. In fact, the conjugation of widespread use in the 20th century, time inversion, can only represent the transition from motion forward to future times into backward in past time (represented with upper "f" and "b", respectively). The sole known way to achieve the remaining two directions of time is via Santilli isoduality (2.9) (represented with an upper "d"). We have in this way the following Santilli's four different hypertimes

(4,43) t = {tf, tb, tfd, tbd}, t

(4.44) tf: Motion forward in future times,

(4.45) tb: Motion backward in past times,

(4.46) tfd: Motion forward in past times,

(4.47) tbd: Motion backward in future times.

Eqs. (4.43)-(4,47) merely initiate the illustration of the complexities of biological structures. In fact, Santilli's hypermathematics is based on hyperunits, as shown in Chapter 2, that are generally different for different times (as well as different space components), and we have the following time hyperunits

(4.48) It = {Itf, Itb, Itfd, Itbd},

Therefore, the four different times (4.43) are not measured with respect to the conventional unit of time, say, 1 sec, but each hypertime is measured with respect to its own hyperunit, by continuing to illustrate the complexity of biological structures. In fact, the four hypertimes, to be hypernumbers, must have the explicit structure

(4.49) tf = t1 Itf, tb = - t2 Itb, tfd = - t3 Itfd, tbd = t4 Itbd.

where tk, k = 1, 2, 3, 4, are conventional positive numbers. The complexity of biological structures is further illustrated by the fact that each hypertime and related hyperunit can be multi-valued,

(4.50) It = { (Itf1, Itf2, ...), (Itb1, Itb2, ...),

(Itfd1, Itfd2, ...), (Itbd1, Itbd2, ...) }

But, each hypertime characterizes its own hyperspace. Thus, already at this introductory level we see the need for four-values hyperspaces, and we write,

(4.51) St = {Sf, Sb, Sfd. Sbd},

each component being multi-valued. But we perceive the growth of a seashell with our sensory perception based on a unique time evolution. The sole known way to achieve compatibility between the multi-valued mathematics needed for biology and our single-valued evolution in time is that via Santilli hypertime since, at the abstract realization-free level the multi-valued character disappears. Alternatively, we can say that the abstract, realization-free axioms characterize our sensory perception of time, while actual calculations are done with specific multi-valued realizations.

More explicitly, Santilli states that the ordinary time t perceived by us is realized into the four-fold times (4.43) and, correspondingly, our time unit It = 1 sec is factorized into the four hyperunits of Eq. (4.48), each one possibly being multi-valued as in Eqs. (4.50) depending on the complexity of the case at hand. For the case of Illert's seashells, the four hyperunits can be single-valued resulting in the conventional four directions of time (4.44)-(4.47). However, for more complex biological structures, each hyperunit can be multivalued, resulting in eqs. (4.50).

In this way, we are naturally forced to distinguish the observer time, which is our perception of time, and the intrinsic time, which is of such a complexity as being outside our intuition and solely representable with mathematical language.

As an illustration, consider only the forward hypertime. Its hyperunit If can have positive-definite but arbitrarily small or arbitrarily large values. Even though we perceive a seashell in our hands with our observer's time, in its own internal perception the seashell can be in the extreme past or the extreme future. The addition of the remaining three hypertimes illustrates again the inability of our limited mental capacity to understand the complexity of a relatively "simple" biological structure such as a seashell, much bigger complexities being expected for the DNA structure.

SANTILLI HYPERSPACES
Let us pass to the outline of Santilli's hyperspaces. Assume at the abstract level a point P in Euclidean space with coordinates P = {x, y, z} and realize the latter in the following multi-valued space hypercoordinates (each set being ordered),

(4.52) P = {x, y, z} → { (x1, x2, ...), (y1, y2, ...) (z1, z2, ...) },

with corresponding space hyperunits

(4.53) Itot =

{ (I1x = 1/n21x, I2x = 1/n22x, ...), (I1y = 1/n21y, I2y = 1/n22y, ...) (I1z = 1/n21z, I2z = 1/n22z, ...) },

and related hyperproduct as identified in Section 2.2C. The hyperline element left invariant by the hyperrotational symmetry can be written

(4.54) r2 = x2 + y2 + z2

→ r*2 = (x12 n21x + x22 n22x + ...) + (y12 n21y + y22 n22y + ...) + (z12 n21z + z22 n22z + ...),

which line element illustrates in a transparent way the deformability of the original perfect sphere x2 + y2 + z2. The universal invariance is then given by the hyperrotational symmetry as indicated above.

We are regrettably forced to halt here our rudimentary review of Santilli's hypermathematics to prevent excessive length. We limit ourselves to stress, again, that the complexity of biological structures is truly beyond human intuition, as illustrated by the hyperbox of Figure 2.1 reproduced below under a new interpretation.


Figure 4.27: In Figure 2.1 we have described Santilli isobox, while in this figure we describe the hyperbox consisting of a box examined by two observers, an external observer in our time and space, and an internal observer in hypertime and hyperspace. For the case of the isobox, both observers are in a (3+1)-dimensional space, the main differences being the perception of much different shapes in generally different times. For the case of the hyperbox, the differences between the exterior and interior observer become of truly difficult understanding by the limited capacities of the human mind, and can solely treated mathematically, since the exterior observer is in a (3+1)-dimensional space, while the interior observer is in a space with an unlimited number of folds branching into multi-dimensional universes.

4.5D. Hypermolecules, hypermagnecules and hyperliquids

The origin of Santilli's prolific discoveries in so different fields is his conviction that quantitative sciences will never admit final descriptions, a limitation that he applied primarily to his own advances. As an example, following the discovery of the isonumbers (Section 2.2A) that, alone, would have assured his name in the history of mathematics, Santilli identified their limitations and, in so doing, discovered the genonumbers; then he identified their limitations and, in so doing, discovered the hypernumbers; then he identified their limitations and, in so doing, discovered the isodual numbers.

Santilli systematically applied this self-criticism to essentially all his discoveries. Consider, for instance, the achievement t of the first known quantitative representation of molecules and their valence bond with an explicitly identified attractive valence force in complete agreement with experimental data (section 4.2). That achievement, alone, was sufficient to set his name in the history of chemistry. Nevertheless, Santilli remained dissatisfied because he considered the advance excessively limited with respect to the complexities of nature.

Consider, for instance, the water molecule. It is popularly believed that such a molecule has one and only one representation, and that it is the same whether it is in our atmosphere or part of a cell. Santilli considers such a view rather arrogant because it assumes a final knowledge of one of the most complex structures in the universe with capabilities and feature simply beyond our imagination at this writing. In reality, there are reasons to expect that, when all features of a cell are taken into account, including its reproductive capacity, each water molecule of a cell is in some form of communication with all the remaining molecules of the same cell. Additional evidence indicates that one water molecule of one cell may well be in some form of communication with all other cells of a body, and so on.

The only quantitative way of initiating the study of such a complexity is via hypermathematics. In this way, Santilli worked out in a paper made available to the Foundation(and expected to be published soon for uploading in pdf format when completed) his model of hypermolecules essentially consisting in the reformulation of the molecular models of Sections 4.2 via multi-valued hypermathematics.

Santilli then applied the same self-critical analysis to his magnecules to discover, again, their excessive limitations for biological structure. In this way, in an additional paper made available to the Foundation and expected to be published, Santilli introduced his hypermagnecules, namely, nonvalence bonds primarily due to opposing magnetic (and electric) polarizations, each bond being multivalued.

Santilli hyperliquid is, therefore, composed by hypermolecules under hypermagnecular bonds by achieving in this way one of the most complex structures known to the authors, not only for mathematical treatment, but also because of the truly unlimited possibilities of interconnections at a distance, as manifestly necessary for any serious understanding of the complexities of bio;logical systems.


Figure 4.28: The fusion of two gametes to form a zygote and initiate a new life. Santilli argues that the original two individual gametes, generally classified as cells, have in reality an extremely complex structure since they show a specific purpose, movements and action. Hence, their cytoplasm and other components cannot be merely made up of ordinary molecules with quantitatively unknown valence bond and links into a liquid state via quantitatively unknown H-bridges. Hence, he represents each individual genome via his notion of hyperliquid. Additionally, Santilli argues that the two gametes cannot be considered independent one from the other since they seek each other. A representation of this interconnection at a distance is also permitted by the notion of hyperliquid, since the latter allows, in principle, the connection of one cell with all possible cells existing in the universe, of course in a way inversely proportional to the square of the distance, much along the fact that the wavepacket of one electron can be considered to be null only at infinite distance.

4.5E. Deciphering the DNA code?

The deciphering of the code contained in a DeoxiribonNucleic Acid (DNA) is, by far, the most cryptographic problem facing mankind. Santilli felt repugnance to the idea that a code of such a complexity could be understood with the ordinary numbers 1, 2, 3, ... dating back to pre-biblical times. With the understanding that the achievement of a solution will require centuries of studies, Santilli introduced his multi-valued hypernumbers for the specific intent of initiating quantitative studies on the DNA code.

The main argument is that the association of two atoms in a DNA can produce an entire organ, such as the liver, with an extremely large number of constituents. The association of two atoms A1 and A1 in a DNA can be mathematically represented via the multiplication. The multiplicity of the results of the original association then leads, inevitably, to Santilli hypernumbers in which the product of two elements can give rise to an ordered, but unlimited number of results, e.g.,

(4.55) A1 x A1 = { 1.7684, ∫ f(r)dr, 745.344, log(p^er), .......}.

The capability by the hypernumbers of at least initiating the deciphering of the DNA code is evident. Despite these evident possibilities, Santilli call published in the historical 1997 monograph

"Isotopic, Genotopic and Hyperstructural Methods in Theoretical Biology"
R. M. Santilli,
Ukraine Academy of Sciences (1997) as well as in other papers, has remained unanswered by biologists, perhaps due to their limitation to understand Santilli's mathematics. The point is that, without an adequate advanced mathematics, biologists merely have the illusions of advances in their field.


4.5F. Understanding the DNA structure?

Santilli never accepted as final the idea that the DNA has a molecular structure, as stated in the best books in the field (see also wikipedia) because excessive simplistic when compared to the complexities of the structure considered. Therefore,he suggested that the DNA has a magnecular structure, namely, it is characterized by atoms that, in part, are under a molecular bond, and in part under a magnecular bond. The hypothesis is strongly supported by the numerous unknown "H-bridges" in the field, with Santilli magnecular bond with a clearly identified attractive force.

Despite a clear advance over rather simplistic models in the literature, Santilli remained dissatisfied with said magnecular structure because basically insufficient to provide the extremely complex inter-relations needed to explain the production of a large organism from a minute helix of atoms.

In this way, he reached one of his most important notions, that that the DNA has a hypermagnecular structure, as conceptually indicated in the preceding sections. This essentially means the conception of the DNA as being composed of atoms under hypermolecular bonds that, in turn, are under a hypermagnecular bond.

A rather feverish research is ongoing at a number of corporations in the U.S.A. and abroad. We regret the prohibition to report these studies because of expected disruptions by academic chemists usually aimed at halting the funding to suppress undesired advances.


Figure 4.29: Santilli never accepted as final the idea that the DNA is a "molecule" (see wikipedia and advanced references quoted therein) for various reason. To begin, valence electrons can solely bond in pairs under singlet couplings resulting in bosons with null spin (Figure 4.2). A first year graduate student knows that no additional spin 1/2 electron can be credibly bonded to a spin 0 valence electron pair. Therefore, the belief that five hundred million atoms of a DNA could be kept together by valence bonds caused the exiting of science in favor of theology. The next possibility is that a DNA could be a "liquid" since its molecules are admitted in the literature as being bonded by "H-=bridges." However, this alternative hypothesis is faced with gross inconsistencies, e.g., the doubling of cells, the fusion of gamedes, and other basic events deviate from the prediction of liquid structures (e.g., via surface tension), again, to such an extent of causing the exiting of science in favor of theology. Santilli's main stand is that the structure of the DNA is immensely beyond all 20th century knowledge of chemistry. To initiate scientific, that is, quantitative studies, Santilli introduced first the hypothesis that the DNA has a magnecular structure so as to replaced the nomenclature of "H-bridges" with equations and actual attractive forces discussed in Section 4.3E. However, the hypothesis soon turned out to be insufficient, e.g., because of the inability to represent cell interconnections at a distance (Figure 4.28). Consequently, Santilli formulated the broader hypothesis that the DNA has the structure of a hypermagnecule. A rather feverish research is going on at U. S. and foreign companies (rather than academia) along a hierarchy of hypermagnecular structures of increasing complexity, the first one being that bonding together hypermolecules, the second one at the level of chromosomes, and so on. It is regrettable that the current condition of scientific ethics in academic chemistry prevents the disclosure of these industrial studies.


4.5G. A future new cure for cancer?

Self-appointed pseudo-scientist generally dub as "semantic" basic advances without any serious study because beyond their comprehension. This is also the case for Santilli's discoveries in biology, although by a rapidly decreasing number of academicians. The problem for said pseudo-scientist is that all Santilli discoveries have concrete applications under development by the industry and certainly not by academia, with due exceptions, because of the novelty.

Santilli introduced the notion of magneliquid for the specific intent of initiating the transition from microwave ovens exciting individual molecules of a liquid such as water, to a new generation of equipment that disrupts the magnecular bond between molecules. The development of the latter equipment is evidently prohibited by the conventional notion of "H-bridges" due to their pure nomenclature character without quantitative treatment. By comparison magnecular bonds in a liquid can indeed be treated quantitatively. Additionally, all magnetic effects are known to have a temperature at which they disappears (the Curie temperature).

A new equipment that disrupts the magnecular bond between molecules can be attempted in a number of ways, e.g., via microwaves causing the magnecular Curie temperature at the microscopic level of individual molecular couplings, which equipment is currently under development by the industry. One of the most important possible application of these advances is a basically new cure for cancer indicated in Figure 4.30.


Figure 4.30: Santilli's original hand drawing illustrating a possible future elimination of cancer. The principle is the disruption of the magnecular bond between molecules, whether within a cell, a DNA or other structures depending on the case at hand. In the event the procedure is possible, it is predicted not to require surgery because the achievement of the Curie temperature for the disruption of magnecular bonds in a DNA can be achieved by two microwaves that are individually non-disruptive for human tissues, and are disruptive solely at their intersection, as illustrated in the figure. We regret the inability to report the ongoing industrial research in the field to prevent academic disruptions.


4.5H. Cloonan's advances in Santilli Magnecules

The cplex-isoelectronic theory is a new theory of pericyclic chemical reactions and aromatic molecules, within the field of organic chemistry, which is based on an expansion of the Robinson electronic theory of organic chemistry. The cplex-isoelectronic theory is a qualitative and regularity based theory (see http://www.cplex-isoelectronic.com)

The theory was developed as a response to the complexity of chemistry due to the inability of the Schr–dinger equation to be solved precisely for H2 and larger molecules, the resultant use of assumptions and approximations, the formidable and intractable calculations due to the diversity of factors involved and the effect of chaos on complex systems.

The new theory makes different predictions from the present quantum chemical methods and the experimental data, when available, is found to be consistent with these new predictions. See

Application of the Cplex-isoelectronic theory to electrocyclisations, sigmatropic rearrangements, cheletropic reactions and antiaromaticity: Consistent with Santilli's hadronic chemistry.
M. O. Cloonan
Int J Hydrogen Energy, Vol. 32, pages 3026-3039 (2007)

These new predictions include the existence of suprafacial concerted thermal [2 + 2], [4 + 4], [6 + 2] and [6 + 6] cycloadditions, suprafacial concerted photochemical [4+2] and [6+4] cycloadditions, stepwise [2+2+2] cycloadditions of ethyne, diamagnetic ring currents for some cyclic systems with 4np electrons, a stepwise pathway for the conrotatory photochemical ring opening of 1,3-cyclohexadiene, a concerted photochemical electrocyclisation for 1,3-cyclohexadiene via disrotatory motion, a concerted suprafacial [1,5] sigmatropic shift with inversion for norcaradiene, a concerted suprafacial [1,3] carbon shift with inversion and retention, a concerted suprafacial photochemical [1,5] hydrogen migration, a concerted photochemical [3,3] shift, stabilisation of cyclic 4np electron systems by delocalisation and their excess energy is due only to electronic repulsion and strain, the monohomocyclopropenium and cyclopropenyl cations are not ëaromaticí (see the above quoted reference).

These findings are also consistent with Santilliís Hadronic Chemistry which predicts more serious limitations with quantum chemistry especially as the explanation provided by the cplex-isoelectronic theory is completely different from the rational provided by quantum theories for pericyclic reactions and aromatic molecules. Nobel prizes have been awarded for these quantum chemical methods; namely the Woodward Hoffmann Conservation of Orbital Symmetry, Fukui's Frontier Molecular Orbital Theory in 1981 and the ab initio and DFT methods in 1998. Thus the way is paved for new ideas and theories in organic chemistry and thus in biology. Furthermore it highlights the complexity of chemistry and biology, the limitations of quantitative theories and the fact that quantitative science will never admit final descriptions.

Our research into the magnecular bond has confirmed Santilliís claims that magnecules cannot be detected by infrared (IR) and nuclear magnetic resonance (NMR) spectroscopy as well as highlighting some of the reported anomalies from a chemistís vista [reference 4]. Research is ongoing to explore the magnecular bond by separation of the magnecules and their structural elucidation by gas electron diffraction. See

A new electronic theory of pericyclic chemistry and aromaticity is proposed: The Cplex-isoelectronic theory. Consistent with Santilli's hadronic chemistry.
M. O. Cloonan
, Int J Hydrogen Energy, Vol. 32, pages 159-171 (2007)


**********************************