Nanoelectronics Chapter 4 Free and Confined Electrons

Slides:

Advertisements

Similar presentations

Quantum Harmonic Oscillator

Advertisements

Chapter 4 Free and Confined Electrons Lecture given by Qiliang Li Dept. of Electrical and Computer Engineering George Mason University ECE 685 Nanoelectronics.

1 Chapter 40 Quantum Mechanics April 6,8 Wave functions and Schrödinger equation 40.1 Wave functions and the one-dimensional Schrödinger equation Quantum.

Given the Uncertainty Principle, how do you write an equation of motion for a particle? First, remember that a particle is only a particle sort of, and.

Study of Harmonic oscillator eigenstates (all parameters = 1) Since consider a local “coarse grained” momentum: and compare with classical result.

Modern Physics 6b Physical Systems, week 7, Thursday 22 Feb. 2007, EJZ Ch.6.4-5: Expectation values and operators Quantum harmonic oscillator → blackbody.

The Harmonic Oscillator

The Hydrogen Atom Quantum Physics 2002 Recommended Reading: Harris Chapter 6, Sections 3,4 Spherical coordinate system The Coulomb Potential Angular Momentum.

Chang-Kui Duan, Institute of Modern Physics, CUPT 1 Harmonic oscillator and coherent states Reading materials: 1.Chapter 7 of Shankar’s PQM.

Happyphysics.com Physics Lecture Resources Prof. Mineesh Gulati Head-Physics Wing Happy Model Hr. Sec. School, Udhampur, J&K Website: happyphysics.com.

Operators A function is something that turns numbers into numbers An operator is something that turns functions into functions Example: The derivative.

Ch 9 pages Lecture 22 – Harmonic oscillator.

Lecture 20 Spherical Harmonics – not examined

مدرس المادة الدكتور :…………………………

Young/Freeman University Physics 11e. Ch 40 Quantum Mechanics © 2005 Pearson Education.

Bound States Review of chapter 4. Comment on my errors in the lecture notes. Quiz Topics in Bound States: The Schrödinger equation. Stationary States.

Simple Harmonic Oscillator (SHO) Quantum Physics II Recommended Reading: Harris: chapter 4 section 8.

Path Integral Quantum Monte Carlo Consider a harmonic oscillator potential a classical particle moves back and forth periodically in such a potential x(t)=

Physics Lecture 13 3/23/ Andrew Brandt Monday March 23, 2009 Dr. Andrew Brandt 1.Loose ends from Ch. 4 Nuclear Motion+Lasers 2.QM Particle.

Chapter 5: Quantum Mechanics

Harmonic Oscillator (harmosc1.mpg) The wave function at t = 0 has the form  (x,0) = A exp[-x 2 /10 2 ] V(x) = ½ (x/50) 2 & starting v = 0 Which direction.

Monday, Nov. 4, 2013PHYS , Fall 2013 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #15 Monday, Nov. 4, 2013 Dr. Jaehoon Yu Finite Potential.

Physics 452 Quantum mechanics II Winter 2012 Karine Chesnel.

The Hydrogen Atom The only atom that can be solved exactly.

Nanoelectronics Chapter 3 Quantum Mechanics of Electrons

Modern Physics lecture 4. The Schroedinger Equation As particles are described by a wave function, we need a wave equation for matter waves As particles.

1 PHYS 3313 – Section 001 Lecture #20 Monday, Apr. 7, 2014 Dr. Jaehoon Yu 3D Infinite Potential Well Degeneracy Simple Harmonic Oscillator Barriers and.

Review for Exam 2 The Schrodinger Eqn.

Measurement and Expectation Values

One Dimensional Quantum Mechanics: The Free Particle

CHAPTER 5 The Schrodinger Eqn.

Chapter 40 Quantum Mechanics

The Hydrogen Atom The only atom that can be solved exactly.

UNIT 1 Quantum Mechanics.

CHAPTER 5 The Schrodinger Eqn.

Quantum Mechanics.

CHAPTER 5 The Schrodinger Eqn.

Quantum Superposition and Optical Transitions

Wave functions, Energy Levels and Particle in the Box

Funny Quantum energy bank: you can get a no interest loan ΔE for a certain time Δt as long as ΔE Δt < h x where ħ = h/2π, and σx, σp are the standard deviations.

Solving Schrodinger Equation: ”Easy” Bound States

المحاضرة السادسة حل معادلة شرود نجر في بعد واحد (1) الجهد اللانهائي

CHAPTER 5 The Schrodinger Eqn.

Chapter 40 Quantum Mechanics

Quantum mechanics I Fall 2012

Finite Square Well.

Quantum Mechanics.

Particle in a Box.

Physical Chemistry Week 12

Source: D. Griffiths, Introduction to Quantum Mechanics (Prentice Hall, 2004) R. Scherrer, Quantum Mechanics An Accessible Introduction (Pearson Int’l.

PHY 741 Quantum Mechanics 12-12:50 PM MWF Olin 103

Particle in a box Potential problem.

The Schrödinger Equation

CHAPTER 3 PROBLEMS IN ONE DIMENSION Particle in one dimensional box

Solution of the differential equation Operator formalism

PHYS 3313 – Section 001 Lecture #19

Reading: Chapters #5 in Shankar; quantum mechanical systems in 1-dim

Other examples of one-dimensional motion

Chapter 40 Quantum Mechanics

Source: D. Griffiths, Introduction to Quantum Mechanics (Prentice Hall, 2004) R. Scherrer, Quantum Mechanics An Accessible Introduction (Pearson Int’l.

Linear Vector Space and Matrix Mechanics

Quantum mechanics I Fall 2012

Wave-Particle Duality and the Wavefunction

Clicker Questions Lecture Slides Professor John Price, Spring 2019

Clicker Questions Lecture Slides Professor John Price, Spring 2019

PHYS 3313 – Section 001 Lecture #17

The Harmonic Oscillator

Presentation transcript:

Nanoelectronics Chapter 4 Free and Confined Electrons

Read the book

§ Parabolic Well – Harmonic Oscillator

The Schrodinger’s equation is:

§ Parabolic Well – Harmonic Oscillator Let divergent

§ Parabolic Well – Harmonic Oscillator Let

§ Parabolic Well – Harmonic Oscillator Therefore, H(x) grows like exp(x^2), producing unphysical diverging solution. So the coefficients beyond a given n should vanish, the infinite series becomes a finite polynomial. So we should have:

§ Parabolic Well – Harmonic Oscillator n is a non-negative integer: 0, 1, 2, …

§ Parabolic Well – Harmonic Oscillator ladder operator

§ Parabolic Well – Harmonic Oscillator Use ladder operator to find the wave function:

§ Parabolic Well – Harmonic Oscillator Let: Only a 1 is not 0: Similarly, we can find more wavefunction…

§ Parabolic Well – Harmonic Oscillator In (A-B), the particle (represented as a ball attached to a spring) oscillates back and forth. In (C-H), some solutions to the Schrödinger Equation are shown, where the horizontal axis is position, and the vertical axis is the real part (blue) or imaginary part (red) of the wavefunction. (C,D,E,F), but not (G,H), are energy eigenstates. (H) is a coherent state, a quantum state which approximates the classical trajectory.

§ Triangular Well

Example:

§ 4.6 Electron confined to atom See lecture note