E-Books durchsuchen

Introduction: The Particle World <italic>Versus</italic> the Wave World

The Birth of Quantum Mechanics: Arriving of the Photon Concept

Derivation of the Planck’s Relation, the de Broglie Relation, and Heisenberg’s Uncertainty Principle Based on the Maxwell Theory

The Merging of the Particle and Wave Concepts: Evidence Suggesting that the Sub-atomic Particle is a Quantized Excitation Wave

The Mechanism of Wave Excitation and the Physical Nature of the Vacuum Medium

The Vacuum is a Dielectric Medium According to the Maxwell Theory; Its Basic Field is the Electric Vector Potential Z

Derivation of the Quantum Wave Equations Based on Wave Excitation in the Vacuum

Derivation of the Dirac Equation from the Wave Equation of the Vacuum

Derivation of the Schrödinger Equation: What is the Physical Meaning of Its Wave Function?

A New Understanding on Wave-Particle Duality: Comparing the Quantum Wave Model with the Copenhagen Interpretation and Other Alternative Models

Why Can <italic>Mass</italic> and <italic>Energy</italic> Be Converted Between Each Other? <italic>Energy</italic>, <italic>Momentum</italic>, and <italic>Mass</italic> Have Geometrical Meanings in the Wave View

The Quantum Origin of the So-Called “Relativistic Relations”

The Physical Basis of Lorentz Transformation and Minkowski’s Four-Dimensional Space–Time

Experimental Tests on the Principle of Relativity and the Twin Paradox

A Quantum View of Photon Gravity: Implications of the Quantum Wave Model on General Relativity

Further Thoughts on Quantum Physics

Investigating the Quantum Properties of Nucleons from a Wave View

Exploration in Cosmology from the Quantum Wave View: Is There a Beginning or an End to Our Universe?

Conclusion: Matter is Composed of Waves