Lectures in Quantum Mechanics: Schrodinger Eqn
Lecture 1: The Wave Equation
Lecture 2: Normalization Of The Wave Equation
Lecture 3: The Wave Equation
Lecture 4: The Schrodinger Eqn. "Derived"
Lecture 5: The Schrodinger Eqn. In 1-D (1/3)
Lecture 6: The Schrodinger Eqn. In 1-D (2/3)
Lecture 7: The Schrodinger Eqn. In 1-D (3/3)
Lecture 8: Meaning Of The Wave Eqn.
Lecture 9: What Is The Prob Distribution?
Lecture 10: What Is Normalization? Ex. 1
Lecture 11: What Is Normalization? Ex. 2
Lecture 12: Time & Position Dependencies 1/3
Lecture 13: Time & Position Dependencies 2/3
Lecture 14: Time & Position Dependencies 3/3
Lecture 15: Time & Position Dependencies Ex.*
Lecture 16: How To Use Schrod. Eqn: 1
Lecture 17: How To Use Schrod. Eqn: 2
Lecture 18: Particle In 1-D Box: Gen. Appr.
Lecture 19: Particle In 1-D Box: Example 1/2
Lecture 20: Particle In 1-D Box: Example 2/2
Lecture 21: Prob. Of Finding Particle 1
Lecture 22: Prob. Of Finding Particle 2
Lecture 23: Prob. Of Finding Particle 3
Lecture 24: Prob. Of Finding Particle 4
Lecture 25: Prob. Of A Particle 1-D Box N=1
Lecture 26: Prob. Of A Particle 1-D Box N=2
Lecture 27: Expectation Value=? 1-D Box N=1
Lecture 28: Expectation Value=? 1-D Box N=2
Lecture 29: Expect. Value Momentum=? 1-D Box
Lecture 30: Momentum Eigenvalue=? N=1
Lecture 31: Momentum Eigenfunction Particle*
Lecture 32: Finite Potential Well Part 1
Lecture 33: Finite Potential Well Part 2
Lecture 34: Finite Potential Well Part 3
Lecture 35: Finite Potential Well Part 4
Lecture 36: Finite Potential Well Part 5
Lecture 37: Finite Potential Well Part 6
Lecture 38: Simple Harmonic Oscillator
Lecture 39: What Is The Quantum Oscillator?
Lecture 40: What Is Reduced Mass?
Lecture 41: What Is Zero Point Vibration?
Lecture 42: K=? Of A Diatomic Molecule
Lecture 43: What Is Transition Energy?
Lecture 44: What Is The Selective Rule?
Lecture 45: Quantum Nature Of Oscillator 1
Lecture 46: Quantum Nature Of Oscillator 2
Lecture 47: Why Solid Not Radiate Like Oscillator?
Lecture 48: How Oscillator Increases Energy
Lecture 49: How Oscillators Increase Energy
Lecture 50: What Is Oscillator Amplitude?
Lecture 51: Oscillator Amplitude - Diatomic
Lecture 52: A Closer Look At The Equation
Lecture 53: The Wave Equation
Lecture 54: The Wave Function
Lecture 55: Solution Of The Oscillator
Lecture 56: What Is A Hermite Polynomial?
Lecture 57: Calculating Hermite Polynomial?
Lecture 58: Oscillator Solution Normalized
Lecture 59: Some Handy Integral Solutions
Lecture 60: Normalizing The Oscillator
Lecture 61: Reflection & Transmission
Lecture 62: Transmission Vs Reflection
Lecture 63: Transmission Vs Reflection-Classic
Lecture 64: Transmission-Reflection (Q.M.)
Lecture 65: Wave Constants B=? C=?
Lecture 66: B=? C=? In Terms Of E & V0
Lecture 67: Finding R=? T=? Coefficients
Lecture 68: What Is The Wave Number K=?
Lecture 69: Is This Possible???
Lecture 70: R=? T=? In Terms Of E & Vo
Lecture 71: R=? T=? V0=(1/4)E (Ex. 1 Of 4)
Lecture 72: R=? T=? V0=(1/4)E (Ex. 2 Of 4)
Lecture 73: R=? T=? V0=(1/2)E (Ex. 3 Of 4
Lecture 74: R=? T=? V0=(3/4)E,.(Ex. 4 Of 4)
Lecture 75: Penetration Depth V0, E
Lecture 76: Penetration Depth V0, E: Ex.
Lecture 77: The Barrier: An Overview
Lecture 78: The Barrier: Amplitude
Lecture 79: The Barrier: Amplitude
Lecture 80: Transmission Coeff. Example
Lecture 81: Transmission Coeff., Original Eq
Lecture 82: Barrier: Boundary Conditions
Lecture 83: Transmission Coeff=? 1
Lecture 84: Transmission Coeff=? 2
Lecture 85: Transmission Coeff=? 3
Lecture 86: Transmission Coeff=? 4
Lecture 87: Transmission Coeff=? 5
Lecture 88: Transmission Coeff=? 6
Lecture 89: Which Penetrates Easier?
Lecture 90: A High Energy Proton
Lecture 91: Modeling Polonium-212 Decay
Lecture 92: Modeling Polonium-212 Decay