LECTURE 16 THE SCHRÖDINGER EQUATION. GUESSING THE SE.

Slides:

Advertisements

Similar presentations

Rae §2.1, B&J §3.1, B&M § An equation for the matter waves: the time-dependent Schrődinger equation*** Classical wave equation (in one dimension):

Advertisements

The Infinite Square Well Now we are ready to solve the time independent Schrödinger equation (TISE) to get ψ(x) and E. (Recall Ψ(x,t) = ψ(x)e −i2  Et/h.

Introduction to Quantum Theory

Chemistry 2 Lecture 2 Particle in a box approximation.

Chapter (6) Introduction to Quantum Mechanics.  is a single valued function, continuous, and finite every where.

Schrödinger Equation in 3d

PHY 102: Waves & Quanta Topic 14 Introduction to Quantum Theory John Cockburn Room E15)

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.

1 Recap T.I.S.E  The behaviour of a particle subjected to a time-independent potential is governed by the famous (1-D, time independent, non relativisitic)

PH 401 Dr. Cecilia Vogel. Review Outline  Particle in a box  solve TISE  stationary state wavefunctions  eigenvalues  stationary vs non-stationary.

Wave Function. Rays and Waves  Optics can often be described by rays. Lenses and mirrorsLenses and mirrors DeterministicDeterministic  Light rays follow.

Dr. Jie ZouPHY Chapter 41 Quantum Mechanics (Cont.)

Wave mechanics in potentials Modern Ch.4, Physical Systems, 30.Jan.2003 EJZ Particle in a Box (Jason Russell), Prob.12 Overview of finite potentials Harmonic.

Ch 9 pages ; Lecture 21 – Schrodinger’s equation.

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

Physics 451 Quantum mechanics I Fall 2012 Sep 10, 2012 Karine Chesnel.

Particle in a Box - 1D (14.3) A simple problem that demonstrates the principles of quantum mechanics is the particle in a box (PIB) Inside the box of a.

Monday, Oct. 22, 2012PHYS , Fall 2012 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #14 Monday, Oct. 22, 2012 Dr. Jaehoon Yu Infinite Potential.

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

LECTURE 21 THE HYDROGEN AND HYDROGENIC ATOMS PHYSICS 420 SPRING 2006 Dennis Papadopoulos.

CHE-20028: PHYSICAL & INORGANIC CHEMISTRY QUANTUM CHEMISTRY: LECTURE 3

مدرس المادة الدكتور :…………………………

Wednesday, Oct. 17, 2012PHYS , Fall 2012 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture #13 Wednesday, Oct. 17, 2012 Dr. Jaehoon Yu Properties.

Lecture 15 Solving the time dependent Schrödinger equation

MODULE 1 In classical mechanics we define a STATE as “The specification of the position and velocity of all the particles present, at some time, and the.

Physics 451 Quantum mechanics I Fall 2012 Sep 12, 2012 Karine Chesnel.

Physics 361 Principles of Modern Physics Lecture 11.

Quantum mechanics unit 2

Physics 361 Principles of Modern Physics Lecture 13.

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.

PHYS 3313 – Section 001 Lecture #18

Chapter 5: Quantum Mechanics

Introduction to Quantum Mechanics

Quantum Chemistry: Our Agenda Postulates in quantum mechanics (Ch. 3) Schrödinger equation (Ch. 2) Simple examples of V(r) Particle in a box (Ch. 4-5)

LECTURE 17 THE PARTICLE IN A BOX PHYSICS 420 SPRING 2006 Dennis Papadopoulos.

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.

Monday, April 13, 2015PHYS , Spring 2015 Dr. Jaehoon Yu 1 PHYS 3313 – Section 001 Lecture # 19 Monday, April 13, 2015 Dr. Jaehoon Yu Refresher:

量子力學導論 Chap 1 - The Wave Function Chap 2 - The Time-independent Schrödinger Equation Chap 3 - Formalism in Hilbert Space Chap 4 - 表象理論.

Principles of Quantum Mechanics P1) Energy is quantized The photoelectric effect Energy quanta E = h  where h = J-s.

1924: de Broglie suggests particles are waves Mid-1925: Werner Heisenberg introduces Matrix Mechanics In 1927 he derives uncertainty principles Late 1925:

Wavefunctions and Quantum Wells

Finite Potential Well The potential energy is zero (U(x) = 0) when the particle is 0 < x < L (Region II) The energy has a finite value (U(x) = U) outside.

Solutions of Schrodinger Equation

Schrödinger Representation – Schrödinger Equation

CHAPTER 5 The Schrodinger Eqn.

Quantum Mechanics.

Quantum Mechanics IV Quiz

PHYS274 Quantum Mechanics VII

+2 or 3 more presentatios. +2 or 3 more presentatios.

Quantum Physics Schrödinger

CHAPTER 5 The Schrodinger Eqn.

قطار التعرج مجلس أبوظبي للتعليم منطقة العين التعليمية

ماذا نعني بأن الطاقة كمية محفوظة؟!

Quantum Mechanics.

Physical Chemistry Week 5 & 6

Quantum Mechanics: Tunneling

Principles of Quantum Mechanics

Particle in a Box.

Joseph Fourier ( ).

Shrödinger Equation.

Simple introduction to quantum mechanics

Particle in a box Potential problem.

More Quantum Mechanics

How does the probability density

Infinite Square Well.

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

Wave-Particle Duality and the Wavefunction

Clicker Questions Lecture Slides Professor John Price, Spring 2019

Presentation transcript:

LECTURE 16 THE SCHRÖDINGER EQUATION

GUESSING THE SE

the potential expression for kinetic energy kinetic plus potential energy gives the total energy

Global Phase  If solution of SE then gives the same physical predictions, i.e. same probabilities of measurements Relative phase:  and  don’t represent the same physical state

Coulomb potential of a proton Probability to find electron outside the box is zero

Fig. 6-5, p. 201

Remember our guitar string? We had the boundary condition that the ends of the string were fixed. Quantum mechanical version- the particle is confined by an infinite potential on either side. The boundary condition- the probability of finding the particle outside of the box is ZERO!

Fig. 6-6, p. 201