Articles in Physics

San José State University

applet-magic.com Thayer Watkins Silicon Valley & Tornado Alley USA

Physics

Quantum Theory

Nuclear Structure

Nuclear Force

Spectro scopy

Solid State

Particle Physics

Magnet -ism

Optics

Bio- mechan.

Relativ -ity

Math. Physics

Stat. Mech.

Misc. Physics

Quantum Theory

A Comparison of the Properties of a Muonic Hydrogen Atom and an Electronic One

Nuclear Structure

General

The Nature and History of Quantum Chromodynamics

The Statistical Explanation of the Masses of Nuclides

On the Conservation of Nucleonic Charge in Neutron Decay

A Statistical Investigation of the Angular Momenta of Nuclei

The Quantization of the Magnetic Moments and Angular Momenta of Nuclides: Part II

The Quantization of the Magnetic Moments and Angular Momenta of Odd p, Even n Nuclides

The Quantization of the Magnetic Moments and Angular Momenta of Even p, Odd n Nuclides

The Quantization of the Magnetic Moments and Angular Momenta of Odd-Odd Nuclides

The Quantization of the Magnetic Moments and Angular Momenta of Even-Even Nuclides

The Magnetic Moments of Nuclides as a Function of the Number of Neutrons They Contain

The Statistical Explanation of the Magnetic Moments of Nuclides

The Magnetic Moments of the Odd p, Odd n Nuclides

The Magnetic Moments of the Even p, Odd n Nuclides

The Magnetic Moments of the Even p, Even n Nuclides

The Magnetic Moments of the Odd p, Even n Nuclides

The Magnetic Moments of the Odd p, Even n Nuclides from Iodine (53) to Berkelium (97)

The Magnetic Moments of the Odd-Odd Nuclides from Iodine (53) to Einsteinium (99)

The Magnetic Moments of the Even-Even Nuclides from Tellurium to Uranium

The Statistical Explanation of the Magnetic Moments of Nuclides

The Magnetic Moments of the Even n Odd p Nuclides from Hydrogen (1) to Antimony (51)

The Magnetic Moments of the Even p Odd n Nuclides from Helium to Tin

The Magnetic Moments of the Odd-Odd Nuclides from Hydrogen to Antimony

The Magnetic Moments of the Even-Even Nuclides from Helium to Tin

The Diiferences in the Nuclear Binding Energies Due to the Formation of the Three Types of Nucleonic Spin Pairs

On the Basis for the Exclusivity of the Spin Pairing of Nucleons

A Plausible Connection between the Binding Energy of a Composite Object and the Potential Energy Lost Upon its Formation

A Testing of the Conventional Model of Nuclear Structure Which Involves the So-Called Strong Force

Studies concerning the Spin Pairing of Nucleons

The Separation Distance In Spin Pairs of Like-Nucleons

The Existence of a Magnetism-like Force Associated with the Motion of Any Charged Particles

The Analogue of the Magnetic Field for the Nucleonic Force Field

The Spin Pairing of Nucleons Due to the Magnetic Fields Generated by their Spinnings

Binding Energy per Nucleon and Nuclide Size

Positron emission and protons not paired with neutrons (Version 2)

Positron emission and protons not paired with neutrons enrico fermi 1933 theory beta rays correspondence static dynamic appearnces objects in motion why free neutron-neutron or free proton-proton do not exist introduction to physics of higgs field principles of invariance in physics

Minimum Energy Nuclear Composition and Nuclear Stability

An explanation of why free neutron-neutron or free proton-proton pairs do not exist

The Nature of the Published Figures for the Binding Energies of Nuclides

The Net Nuclear Strong Force of Objects

To What Extent is the Development of Particle Physics Dependent upon there being an Attractive Interactive Force Acting between all Nucleons?

The Nature of the So-Called Nuclear Strong Force

Confirmation of the Proposition that the Stability of Neutrons within Nuclei as Opposed to the Instability of Free Neutrons is Due to Their Being Paired with Protons

Explanation of Why Neutrons in a Nucleus are Stable but Free Neutrons are not Stable

The Statistical Explanation of the Incremental Binding Energies of Neutron Spin Pairs

The Statistical Explanation of the Incremental Binding Energies of Proton Spin Pairs

The Binding Energy of Nuclei Due to the Interaction of Proton Pairs

The Binding Energy of Nuclei Due to the Interaction of Neutron Pairs

A Preliminary Analysis of the Binding Energy of Nuclei Due to the Interaction of Neutron Pairs

Comparisons of the Interaction Binding Energies of Nucleons in Various Shells Based upon Increments in the Incremental Binding Energies

Estimates of the Interaction Binding Energies of Nucleons in Various Shells Based upon Increments in the Incremental Binding Energies of Protons

Estimates of the Interaction Binding Energies of Nucleons in Various Shells Based upon Increments in the Incremental Binding Energies of Neutrons

An Extensive Demonstration that the Interaction Binding Energies of Two Nucleons Depends Only Upon the Shells the Two Belong To

On the Interaction Binding Energies of Two Nucleons Being a Function of the Shells They Occupy

On the Equality of the Cross Differences in the Binding Energies of Nuclei

The Evidence for the Formation of Proton Spin Pairs Within Nuclei

The Evidence for the Formation of Neutron Spin Pairs Within Nuclei

Two Theorems for Isolating the Interactions of Particles in Terms of Second Differences

Protons repel each other not only through the electrostatic force but also through the nuclear strong force, as do neutrons. Nuclei are held together by the formation of nucleon spin pairs and the attraction between protons and neutrons.

The Binding Energies of Nuclides with Halo Proton Pairs

The Binding Energies of Nuclides with Halo Neutron Pairs

Confirmation of 6 and 14
as proper nuclear magic numbers

What holds a nucleus together? Version 2

Possible Direct Evidence for the Alpha Module Structure of Nuclei

The Regularities and Irregularities of the Binding Energies of Alpha Module Nuclides

The Conventional Concept of a Nuclear Strong Force is a Colossal Blunder

The Statistical Explanation of the Binding Energies of Nuclides Based Upon a Four-Way Classification of Nucleon Shell Occupancies

The Statistical Explanation of the Binding Energies of Nuclides Based Upon a Three-Way Classification of Nucleon Shell Occupancies and Allowing for a Possible Error in the Mass of the Neutron

The Statistical Explanation of the Binding Energies of Nuclides Based Upon a Three-Way Classification of Nucleon Shell Occupancies

The Statistical Explanation of the Binding Energies of Nuclides Based Upon a Two-Way Classification of Nucleon Shell Occupancies

The Mass and Binding Energies of Nuclides and their Quarkic Composition

The Statistical Explanation of the Binding Energy of Nuclei in Terms of the Quarks They Contain

String Theory and String Rotation

Energy, Energy, Binding Energy and Half-life Statistics for Positron Emitters

Energy, Binding Energy and Half-life
Statisti for Pure Beta Emitters

An Investigation of the Changes in Binding Energy that would Result from the Conversion of a Neutron in a Nucleus into a Proton and an Electron

An Investigation of the Stability of Neutrons in Nuclei

A Comparison of the Binding Energies Due to the Formation of the Three Types of Nucleon Spin Pairs

What's wrong with the conventional theory of the nucleus

How a nucleus can break into two nuclei under the impact of a neutron

An Estimate of the Binding Energy Due to the Formation of a Neutron-Proton Spin Pair

Estimation of the Binding Energy Associated with the Formation of a Proton Spin Pair

Estimation of the Binding Energy Associated with the Formation of a Neutron Spin Pair

The Statistical Explanation of the Binding Energies of Nuclides in terms of their Pair Formations and the Interactions of their Nucleons through the Strong Force and Taking into Account Heteroskedasticity and an Error in the Mass of the Neutron

The Energies of the Electrical Fields of Charged Particles and their Charge Radii

The Nature of Charged Particles

The Binding Energie Associated with the Addition of a Neutron-Neutron and Proton-Proton Spin Pair to the Alpha Nuclei

The Binding Energy Associated with the Addition of a Neutron-Proton Spin Pair to the Alpha Nuclei

The Statistical Explanation of the Binding Energies of Nuclides in terms of their Pair Formations and the Interactions of their Nucleons through the Strong Force

The Number of Nuclides of Various Compositions

The Mass and Rate of Rotation of a Protoplanet Sweeping Up Material in a Ring Around a Star

The Incremental Binding Energy Relationships Among Nuclides Consisting of only Alpha Modules and Proton Spin Pairs

The Estimation of the Nucleonic Charge of a Neutron Relative to that of a Proton Using Data Based on Nuclei made up of Alpha Modules and Neutron Spin Pairs Starting with the Incremental Binding Energies of Neutron Spin Pairs

Alan Turing's Brilliant Explanation of Animal Coat Patterns

The Chamber of the Apple Seeds

The Incremental Binding Energies Due to the Interactions of Alpha Modules and Neutron Spin Pairs

The Analysis of the Binding Energy of Nuclei in Terms of the Quarks They Contain

An Estimation of the Nucleonic Charge of a Neutron Relative to that of a Proton Using the Ratios of Second Differences
to Cross Differences

An Estimation of the Nucleonic Charge of a Neutron Relative to that of a Proton Using the Ratios of Second Differences

What holds a nucleus together?

The Force Internally Due to a Charge Uniformly Distributed on a Sphere When the Force Law is not a Strictly Inverse-Distance-Squared Law

The Correspondence Between Statically and Dynamically Determined Force Fields with Multiple Particles

A Generalization of the Correspondence Between Statically and Dynamically Determined Fields

An Extension of the Correspondence Between Statically and Dynamically Determined Force Fields

A Correspondence Between Statically and Dynamically Determined Force Fields

The Binding Energies Due to the Interaction of Proton Spin Pairs with Other Proton Spin Pairs

The Binding Energies Due to the Interaction of Neutron Spin Pairs with Other Neutron Spin Pairs

An Investigation of What Can Be Said About the Interaction of a Nuclear Particle with Other Particles of the Same Type in the Same Shell

The Binding Energies Due to the Interaction of Neutron Spin Pairs with Proton Spin Pairs

A Generalization of the Theorem that the Second Difference of the Interaction Energies of Nuclides with Respect to the Number of Particlesof a Particular Type Is Equal to the Interaction Energy of the Last Particle of that Type with the Next-to-Last Particle of the Same Type in the Nuclide

A Generalization of a Theorem on Cross Difference of the Excess Binding Energies

Attraction and Repulsion in Nuclides Composed Entirely of Alpha Modules and Neutron Spin Pairs

A Comparison of the Incremental Binding Energies of Alpha Modules in Alpha Nuclides and Nuclides Which Are Made Up of Alpha Modules and One Neutron Spin Pair

The Testing of the Alpha Module Model of Nuclear Structure on the Nuclides Composed Entirely of Alpha Modules and One Neutron Spin Pair

The Testing of the Alpha Module Model of Nuclear Structure on the Nuclides Composed Entirely of Alpha Modules

Some Preliminary Analyses of the Measured Electric Quadrupole Moments of Nuclides

Nuclear Rotations of Alpha Module Rings

Nuclear Rotations

The Force Internally Due to a Charge Uniformly Distributed on a Sphere When the Force Law is not a Strictly Inverse-Distance-Squared Law

The Profile of Magnetic Dipole Moments of the Nuclides of the Same Proton Number as a Function of their Neutron Number

The Magnetic Dipole Moments of the Nuclides from Nitrogen through Silicon and their Implications Concerning Nuclear Rotations

The Magnetic Dipole Moments of the Lighter Nuclides and their Implications Concerning Nuclear Rotations

The Magnetic Dipole Moment of Deuteron and Its Implications Concerning Nuclear Structure

Nuclear Rotations of an Alpha Particle

Nuclear Rotations of a Deuteron

The Evidence for the Formation of Neutron-Proton Spin Pairs

The Evidence for the Formation of Proton-Proton Spin Pairs

The Evidence for the Formation of Neutron-Neutron Spin Pairs

The Significance of the Nonexistence of Neutron and Proton Spin Pairs Outside of Nucleis

The Empirical Performance of the Alpha Module Model of Nuclear Structure Using the Dataset of All Nuclides

Scale Effects in the Quantum Mechanics of a Cluster-Rotor Model of Small Nuclei

Nuclear Models and the Proposition that Accelerated Charges Radiate Electromagnetic Waves

The Empirical Performance of the Alpha Module Model of Nuclear Structure

Tests of the Equality of the Cross Differences of Nuclear Binding Energies

Demonstration that like nucleons repel each other through the strong nuclear force and unlike nucleon attract through the strong force

Nuclear Subshells and Numbers of Stable Isotopes and Isotones

Magic Numbers for Nuclear shells and Subshells

The Binding Energy of an Alpha Module anywhere in a Nucleus is equal to that of an Alpha Particle

The Distribution of the Enhancements to Binding Energy Due to the Formation of Neutron-Neutron Spin Pairs and Neutron-Proton Spin Pairs

Further Corroboration of the Alpha Module Model of Nuclear Structure

The Adjustment of the Statistical Testing of the Alpha Module Model of Nuclear Structure for Heteroskedasticity

Two General Nuclear Phenomena Provide Confirmation for the Alpha Module Model of Nuclear Structure

The Origin of the Near-Spherical Appearance of Nuclei

The Binding Energy Associated with the Formation of a Neutron-Proton Spin Pair

The Binding Energy of Protons Which is Due to the Interaction of a Proton with the others Nucleons Through the Nuclear Strong Force

The Binding Energy of Nuclides Which is Due to the Interaction of its Nucleons Through the Strong Force

The Binding Energies Due to the Formation of Neutron-Neutron Spin Pairs and Proton-Proton Spin Pairs

The Binding Energetics of Nuclei with 12 Protons or Neutrons

The Binding Energetics of Nuclei with 24 Protons or Neutrons

The Apparent Shapes of Nuclei

The Magnetic Dipole Moment and Rotational Kinetic Energy of a Deuteron

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells with the Proton-Proton Interactions Treated Separately

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells: The Four Shells Case for Small Nuclides

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells: The Four Shells Case

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells: Separate Analysis for Light and Heavy Nuclides

A Proposed Experimental Test of Repulsion Between Neutrons

The Binding Energy of Nuclides in Relation to the Filling of Neutron/Proton Shells

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among the Nucleons in their Shells

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among their Nucleons (Revised Version)

The Binding Energies of Nuclei as Determined by the Energy of Formation of their Substructures and the Interactions Among their Nucleons

The Search for the Increment in Binding Energy Due Strictly to the Formation of an Alpha Module

An Exhaustive Display of the Cross Differences for the Nuclear Binding Energy of a Proton Pair with a Neutron Pair Starting with the Incremental Binding Energies of Proton Pairs

An Exhaustive Display of the Cross Differences for the Nuclear Binding Energy of a Neutron Pair with a Proton Pair

A Proposition Concerning the Second Differences of the Binding Energies of Neutron and Proton Spin Pairs: That They Are Equal to the Interaction Energy of the Last Particles of Each Type with the Next-to-Last Particle of the Same Type

A Proposition Concerning the Cross Differences of the Binding Energies of Neutron and Proton Spin Pairs: That They Are Equal to the Interaction Energy of the Last Particles of Each Type with Each Other

An Exhaustive Demonstration that Protons Repel Each Other Through the Nuclear Strong Force As Well As Through the Electrostatic Force

An Exhaustive Demonstration that Neutrons Repel Each Other Through the Nuclear Strong Force

A Statistical Regression Equation for the Binding Energies of Nuclei Taking Into Account the Heteroskedasticity of the Random Term

The Binding Energies of Nuclei as Determined by their Substructures and the Interactions Among their Nucleons

The Forces Between the Substructures of Nuclei: Neutron and Proton Spin Pairs, a Singleton Neutron or Singleton Proton and Alpha Modules

The Forces Between Nucleons: Spin Pairing, Nuclear Strong Force and Electrostatic (Coulomb)

Empirical Investigation of the Alpha Module Model of Nuclear Structure

The Classical and Quantum Mechanics of a Thin Ring Spinning About Two Axes

An Analysis of Quantization in a Rotating 2Ngon of Particles

An Old Quantum Mechanical Analysis of a Simple Model of the Alpha Particle

Further Investigations of the Possibility that the the Nucleons of Nuclei are, Where Possible, Organized into Alpha Particles: The Proton Data

Further Investigations of the Possibility that the the Nucleons of Nuclei are, Where Possible, Organized into Alpha Particles: The Neutron Data

The Second Difference of the Excess Binding Energies with Respect to the Number of Alpha Particles Is Equal to the Interaction Energy of the Last Alpha Particle with the Next to Last Alpha Particle in the Nuclide

The Cross Differences of the Excess Binding Energies Is Equal to the Interaction Energy of the Last Alpha Particle with the Last Neutron in the Nuclide

An Analysis of the Changes in the Relationship between the Binding Energy Involved in the Formation of Proton-Proton Spin Pairs and the Number of Protons in the Nuclide as the Number of Neutrons in the Nuclide Varies

An Analysis of the Changes in the Relationship between the Binding Energy Involved in the Formation of Neutron-Neutron Spin Pairs and the Number of Neutrons in the Nuclide as the Number of Protons in the Nuclide Varies

An Estimation and Analysis of the Binding Energy Involved in the Formation of Neutron-Neutron Spin Pairs

An Estimate of the Nuclear Strong Force Charge of a Neutron Relative to that of Proton Based Upon the Pattern of the Scatter Diagram of the Proton and Neutron Numbers of Nuclides

The Net Nucleonic Charge Explaining the Incremental Binding Energy of Protons Due to Their Interaction Through the Strong Force in Nuclides

The Functional Form of the Incremental Binding Energy of Protons as a Function of the Number of Protons and Neutrons in the Nuclide

The Functional Form of the Incremental Binding Energy of Neutrons as a Function of the Number of Protons and Neutrons in the Nuclide

The Functional Form of the Incremental Binding Energy of Neutrons as a Function of the Number of Neutrons in the Nuclide

The Second Difference of Binding Energies with Respect to the Numberof Protons Is Equal to the Interaction Energy of the Last Proton with the Next to Last proton in the Nuclide

The Second Difference of Binding Energies Is Equal to the Interaction Energy of the Last Neutron with the Next to Last Neutron in the Nuclide

The Statistical Testing of the Cross Differences in Binding Energies for Dependence on the Number of Nucleons in the Nucleonic Shells

A Rough Approximation of the Spatial Structure of the Nucleonic Shells of Nuclei

The Separation of the Cross Differences in Binding Energy into the Component Due to Pair Formation and the Component Due to the Interaction Through the Nuclear Strong Force as a Function of the Number of Neutrons in the Nuclide

The Cross Differences in Binding Energy as a Function of the Number of Protons in the Nuclide

Illustrations of the Effect of Double Pairing on the Incremental Binding Energy of Protons

Illustrations of the Effect of Double Pairing on the Incremental Binding Energy of Neutrons

The Functional Form of the Incremental Binding Energy of Neutrons as a Function of the Number of Protons in the Nuclide

The Cross Differences of Binding Energies Is Equal to the Interaction Energy of the Last Neutron with the Last Proton in the Nuclide

The Equality of the Cross Difference Ratios for a Binary Function

The Interactive Energies of Protons with Neutrons

The Interactive Energies of Neutrons with Protons in Shells Below Their Own

The Interaction of Nucleons in Nuclear Shells

A Comparison of the Relationships Between the Incremental Binding Energy of Neutrons and Protons and the Number of the Other Nucleons in the Nuclide

The Functional Form of the Incremental Binding Energy of Protons as a Function of the Number of Neutrons in the Nucleus Over the Full Range of Proton Numbers

The Functional Form of the Incremental Binding Energy of Neutrons as a Function of the Number of Protons in the Nucleus Over the Full Range of Neutron Numbers

The Functional Form of the Incremental Binding Energy of Protons in the Second Shell as a Function of the Number of Neutrons in the Nucleus

The Functional Form of the Incremental Binding Energy of Neutrons in the Second Shell as a Function of the Number of Protons in the Nucleus

he Functional Form of the Incremental Binding Energy of Neutrons as a Function of the Number of Protons in the Nucleus

The Functional Form of the Incremental Binding Energies of Nucleons in Nuclides

Evidence Concerning Alpha Particle Substructures in Nuclei from Changes in the Number of Protons

The Relationship Between the Effects on Binding Energy of Adding and Subtracting Neutrons and Protons

Evidence Concerning Alpha Particle Structures in Nuclei

The Spatial Structure of the Nucleonic Shells of Nuclides

The Explanation of the Binding Energy of the Triteron, the Hydrogen 3 Nuclide

The Enhancement of Incremental Binding Energies Due to Neutron Pair Formation

The Enhancement of Incremental Binding Energies Due to Proton Pair Formation

A Model for explaining the Relatively High Binding Energy of the Helium 4 Nuclide (Alpha Particle) Among the Smallest Nuclides

The Division of the Binding Energy of the Alpha Particle, the Helium 4 Nuclide, Between That Due to the Strong Force and That Due to Nucleon Spin Pair Formation

On the Relatively High Binding Energy of the Alpha Particle

Revision of the Estimates of the Parameters of the Nuclear Force Formula based upon the Separation Distance of the Centers of the Nucleons in a Deuteron

The Estimation of the Enhancement of Binding Energy Due to the Formation of a Neutron-Proton Pair

The Estimation of the Enhancement of Binding Energy Due to the Formation of Nucleonic Pairs

The Division of the Binding Energy of the Helium 3 Nuclide Between That Due to the Strong Force and That Due to Nucleon Spin Pair Formation

The Division of the Binding Energy of the Triteron Between That Due to the Strong Force and That Due to Nucleon Spin Pair Formation

A Revision of the Estimates of the Parameters of the Nuclear Force Formula based upon the Difference in the Nucleonic Charge of the Neutron Compared to the Proton With the Results Applied to the Estimation of the Binding Energy of the formation of a Neutron-Proton Spin Pair

The Influence of Additional Neutrons on the Incremental Structural Binding Energies of Alpha Particles in the Third and Second Shells

The Influence of Additional Neutrons on the Incremental Structural Binding Energies of Alpha Particles in the Fourth Shell

The Influence of Additional Neutrons on the Incremental Structural Binding Energies of Alpha Particles in the Fifth Shell

The Incremental Structural Binding Energies of Alpha Particles in Nuclides With Varying Numbers of Additional Neutron Pairs

The Structural Binding Energies of Nuclides and the Effect of an Error in the Mass of a Neutron on Their Computation

The Structural Binding Energies of the Alpha Nuclides as a Function of their LImited Range Intra- and Intershell Interactions

The Structural Binding Energies of the Alpha Nuclides as a Function of their Intra- and Intershell Interactions

The Attraction/Repulsion of Alpha Particles for Each Other and for Neutrons

Estimation of the Nucleonic Charge of a Neutron Relative to That of a Proton

The Testing of the Nucleonic Charge Hypothesis

The Net Force Between Alpha Particles and other Substructures of Nuclei

The Substructures of Nuclei and Their Interactions

The Evidence for the Formation of Nucleon Spin Pairs in Nuclei

More Evidence for the Substructured Model of Nuclei

Investigations of the Radii of Shells of Alpha Particles in Nuclei

The Number of Interactions and the Incremental Structural Binding Energies of Alpha Particles in Nuclides

The Binding Energies of Small Nuclides

A Comparison of the Effects of a Neutron and a Proton on the Structural Binding Energies of Alpha Nuclides

The Structural Binding Energy of Nuclides as a
Function of the Number of Alpha Particles and
the Excess Neutrons and Protons They Contain

The Effects of an Extra Neutron or Extra Proton on the Structural Binding Energies of Alpha Particles

The Effect of Excess Neutrons on the Incremental Structural Binding Energies of Alpha Particles in Nuclides

The Incremental Structural Binding Energies of Alpha Particles in Nuclides

The Spatial Structure of Nuclei

The Density of Nuclear Matter

On the Spatial Structure of Nuclear Shells

The Dimensionality of Nucleon Shells

The Quantum Mechanics of a Pseudo-deuteron: Two Protons and an Electron

The Relative Magnitudes of the Forces Involved in the Three Types of Nucleonic Interactions

An Investigation of What Binding Energies of Nuclides Imply About Their Spatial Structure

Evidence for Alpha Particle Substructures in Nuclides

Bonds, Pairing and Binding Energies Among the Small Nuclides

The Explanation for the Jump in Incremental Binding Energy of Neutrons When the Number of Protons Equals or Exceeds the Number of Neutrons

The Statistical Explanation of the Relationship Between Incremental Binding Energy and the Proton Number for all Nuclides

The Absence of Higher Energy States for the Deuteron

The Nuclear Strong Force Between Protons is Repulsion, Just as is that of the Electrostatic Force

The Statistical Explanation of the Relationship Between Incremental Binding Energy and the Proton Number of a Nuclide

The Incremental Binding Energy versus Proton Number at the Transition to a Higher Neutron Shell

The Relationships of Incremental Binding Energies of the Neutrons in the Third Neutron Shell to the Number of Protons in the Nuclide

On the Extention of the Bohr Model to Nuclides

The Functional Form of the Relationship Between the Incremental Binding Energy of Neutrons and the Net Attractive Force They Are Subject To

Neutrons repell each other, as do protons. Nuclei are held together by the attractions of neutrons and protons.

Quantum Theory

Nuclear Structure

General

Mass Deficits (Binding Energies)

Nuclear Force

Spectroscopy

Solid State Physics

Particle Physics

Magnetism

Optics

Biomechanics

Relativity

Mathematical Physics

Statistical Mechanics

Miscellaneous Physics