Berkeley Physics Course: Quantum physics

A-particle amplitude angular momentum approximation assume barrier baryon beam binding energy Bohr Broglie wave Chap charge classical collision consider constant corresponding counter cross section crystal decay defined derived describe diffraction electric dipole electromagnetic electron electrostatic elementary particles emission emitted energy levels ensemble excited experiment experimental expression field figure fine structure constant frequency gamma rays given hydrogen atom incident intensity interactions ionization isotope kinetic energy Klein-Gordon equation light linear macroscopic magnetic magnitude mass measurements mirror molecule motion nature neutrons nucleon nucleus observed oscillator photon pion Planck's Planck's constant plane polarization positron potential prediction problem quantity quantum mechanics quantum physics radiation reader region resonance scattering Schrödinger equation Schrödinger theory shown in Fig shows slit solution space stationary statistical ensemble temperature term scheme tion total energy transitions uncertainty relation unit variable vector velocity wave function wave train wavelength zero