Fundamental formulas of physics

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Fundamental formulas (or formulae) of Physics are pragmatically defined as “those mathematical formulae that have a well-defined physical interpretation related to verifiable and reproducible physical experiments, and that are in use by the largest majority of physicists and mathematicians involved in both the practice and study of physics, and also its engineering applications”. In short, fundamental formulas are the most important, essential mathematical formulae in Physics that have a well-understood physical content and interpretatation, which thus provide the basis for either specific areas of physics or general/ theories of Physics.

Suggested outline:

1. Basic mathematical formulas used in physics;
2. Physical constants;
3. Statistics and Probability theories;
4. Nomograms;
5. classical mechanics;
6. Sound and Acoustics
7. Geometric Optics;
8. Electromagnetism;
9. Electronics and applications
10. Electrical engineering and telecommunications
11. Nanoelectronics and Nanomaterials
12. Netwon's theory of Gravitation
13. photoelectric effect and Einstein's explanation/ formulae
14. Solar photovoltaics
15. Einstein's special relativity theory
16. Einstein's General Relativity theory
17. quantum mechanics;
18. quantum field theories (QFT), TQFT and HQFT
19. quantum fields on a Lattice (QFL) and quantum theories on a lattice (QTL)
20. Computational, theoretical physics
21. quantum logics and Quantum Logic Algebras
22. algebraic quantum field theory
23. quantum automata and Quantum Computing
24. Standard Model (SUSY)
25. supersymmetry and supergravity theories
26. radioactivity, Atomic and nuclear physics
27. Harmonic oscillator and coupled oscillators;
28. fluid dynamics and Rheology;
29. Kinetic theory of gases and Classical statistical mechanics
30. Molecular Physics, heat and Thermodynamics
31. quantum statistical mechanics (QS)
32. High energy physics and Elementary Particles
33. Ergodic systems Information theory and Irreversible Thermodynamics
34. Mathematical Physics
35. quantum electrodynamics (QED)
36. Quantum Chromodynamics (QCD)
37. quantum gravity (QG)
38. Complex system dynamics (CSD)
39. Chaotic Systems and Chaos
40. Mathematical and theoretical biophysics
41. Semiconductors, Hall effect and Josephson effect
42. superconductivity and superconductors
43. Crystal Lattices and Symmetry
44. Paracrystals and paracrystal theory
45. Noncrystalline materials and glasses
46. applied physics
47. Physical Mathematics and Physical Applied Mathematics
48. Ax
49. Ay
50. Az

References/ Bibliography

Bibliography

1

D. H. Menzel. Fundamental Formulas of Physics. Vol. 1 and 2, 1965