Schroedinger’s Equation...an historical, heuristic approach.

Slides:



Advertisements
Similar presentations
The 4 important interactions of photons
Advertisements

Quantum Mechanics AP Physics B.
Electrons as Waves Sarah Allison Claire.
Lecture Outline Chapter 30 Physics, 4th Edition James S. Walker
Quantum Mechanics Chapter 7 §4-5. The de Broglie Relation All matter has a wave-like nature… All matter has a wave-like nature… Wave-particle.
Knight - Chapter 28 (Grasshopper Book) Quantum Physics.
Ch 9 pages ; Lecture 20 – Particle and Waves.
The electromagnetic (EM) field serves as a model for particle fields
„There was a time when newspapers said that only twelve men understood the theory of relativity. I do not believe that there ever was such a time... On.
PHY 102: Quantum Physics Topic 3 De Broglie Waves.
Quantum One: Lecture 4. Schrödinger's Wave Mechanics for a Free Quantum Particle.
Quantum Theory of Light A TimeLine. Light as an EM Wave.
Review of waves T = period = time of one cycle  = 2  f = angular frequency = number of radians per second t Waves in time: f = 1/T =  /2  = frequency.
The electromagnetic (EM) field serves as a model for particle fields  = charge density, J = current density.
Chem 125 Lecture 7 9/14/05 Projected material This material is for the exclusive use of Chem 125 students at Yale and may not be copied or distributed.
Classical ConceptsEquations Newton’s Law Kinetic Energy Momentum Momentum and Energy Speed of light Velocity of a wave Angular Frequency Einstein’s Mass-Energy.
Modern Physics lecture 3. Louis de Broglie
Heisenberg Uncertainty Principle Heisenberg (1926) thought about measuring simultaneously the position and momentum (velocity) of an electron. Realization.
Ch 9 pages ; Lecture 21 – Schrodinger’s equation.
PHYSICAL CHEMISTRY - ADVANCED MATERIALS Particles and Waves Standing Waves Wave Function Differential Wave Equation Something more about…. X=0 X=L Standing.
Incident transmitted reflected III. Heisenberg’s Matrix Mechanics 1924: de Broglie suggests particles are waves Mid-1925: Werner Heisenberg introduces.
Wave Mechanics and Orbitals. The quantum theory provided many improvements in the understanding of different electron energy states within an atom. HOWEVER,
These notes were typed in association with Physics for use with the IB Diploma Programme by Michael Dickinson For further reading and explanation see:
Physics Department Phys 3650 Quantum Mechanics – I Lecture Notes Dr. Ibrahim Elsayed Quantum Mechanics.
Bohr Model Since the energy states are quantized, the light emitted from excited atoms must be quantized and appear as line spectra. After lots of math,
Quantum Theory Chapter 5. Lecture Objectives Indicate what is meant by the duality of matter. Indicate what is meant by the duality of matter. Discuss.
Lecture 14: Schrödinger and Matter Waves. Particle-like Behaviour of Light n Planck’s explanation of blackbody radiation n Einstein’s explanation of photoelectric.
Mullis1 Arrangement of Electrons in Atoms Principles of electromagnetic radiation led to Bohr’s model of the atom. Electron location is described using.
(1) Experimental evidence shows the particles of microscopic systems moves according to the laws of wave motion, and not according to the Newton laws of.
1 Chapter 7 Atomic Structure. 2 Light n Made up of electromagnetic radiation n Waves of electric and magnetic fields at right angles to each other.
Physics 2170 – Spring The Schrödinger equation Next homework assignment is available I will be giving a.
The Quantum Theory of Atoms and Molecules The Schrödinger equation and how to use wavefunctions Dr Grant Ritchie.
Year 2 - Quantum Mechanics Lecture 2 Paul Dauncey 13/10/20081Paul Dauncey - Quantum Mechanics.
What’s coming up??? Oct 25The atmosphere, part 1Ch. 8 Oct 27Midterm … No lecture Oct 29The atmosphere, part 2Ch. 8 Nov 1Light, blackbodies, BohrCh. 9 Nov.
Objective 6: TSW explain how the quantum mechanical model evolved from Bohr’s model.
DUALITY PARTICLE WAVE PARTICLE DUALITY WAVE © John Parkinson.
A QUANTUM LEAP IN MATH By Michael Smith.
Free particle in 1D (1) 1D Unbound States
The Quantum Atom Weirder and Weirder. Wave-Particle Duality Louis de Broglie ( )‏
Orbitals: What? Why? The Bohr theory of the atom did not account for all the properties of electrons and atoms.
Review of EM wave  particle EM wave behave as particle: EM wave behave as particle: Proof: Proof: Blackbody radiation. Plank proposes ??? to solve ???
Phase Velocity and Group Velocity
More on waves Announcements: Historical quote:
Modern Physics lecture X. Louis de Broglie
Introduction to Modern Physics A (mainly) historical perspective on - atomic physics  - nuclear physics - particle physics.
Physics 213 General Physics Lecture Exam 3 Results Average = 141 points.
An equation for matter waves Seem to need an equation that involves the first derivative in time, but the second derivative in space As before try solution.
Nature of a wave  A wave is described by frequency, wavelength, phase velocity u and intensity I  A wave is spread out and occupies a relatively large.
Topic I: Quantum theory Chapter 7 Introduction to Quantum Theory.
Principles of Quantum Mechanics P1) Energy is quantized The photoelectric effect Energy quanta E = h  where h = J-s.
Louis de Broglie, (France, ) Wave Properties of Matter (1923) -Since light waves have a particle behavior (as shown by Einstein in the Photoelectric.
1924: de Broglie suggests particles are waves Mid-1925: Werner Heisenberg introduces Matrix Mechanics In 1927 he derives uncertainty principles Late 1925:
1 HEINSENBERG’S UNCERTAINTY PRINCIPLE “It is impossible to determine both position and momentum of a particle simultaneously and accurately. The product.
Particle wave duality 1 Particle - Wave Duality. particle wave duality 2 Einstein’s Famous Idea in Equation Form Einstein knew that energy is involved:
Principles of Quantum Mechanics What is Quantum Mechanics? QM is the theory of the behavior of very small objects (e.g. molecules, atoms, nuclei, elementary.
(b) = 0.18 cm In this case the wavelength is significant. While the De Broglie equation applies to all systems, the wave properties become observable only.
Postulates of Bohr model
Preamble to the Constant Alpha
Quantum Mechanics.
(b) = cm In this case the wavelength is significant.
Ch25 Modern Optics and Matter Waves
Postulates of Bohr model
Compton Effect Physics 12Adv.
Schroedinger’s Equation
Wave Particle Duality Light behaves as both a wave and a particle at the same time! PARTICLE properties individual interaction dynamics: F=ma mass – quantization.
Quantum Model of the Atom
Quantum One.
General Physics (PHY 2140) Lecture 31 Modern Physics Quantum Physics
Phase Velocity and Group Velocity
Quantum Mechanics IB Physics.
Presentation transcript:

Schroedinger’s Equation...an historical, heuristic approach

Radical view of light Planck and Einstein re-introduced the particle notion for light a wave “becomes” a particle and still a wave … hmmm

de Broglie... If light (ie “a wave”) can be a particle then maybe a particle (electron?) can “be a wave” - what are the implications of this “leap of reason”?

Compare and contrast: Waves & Particles Waves are extended Waves are continuous Waves conform to wave equations Waves diffract and interfere Waves have amplitude, frequency and velocity Particles are points Particles are discontinuous Particles obey equations of mechanics Particles “bounce” Particles have mass, size(?) and velocity

ParticleWaves, Wavicles or just Weirdness … If de Broglie is correct then we can ascribe a wavelength to a particle:

Schroedinger... Once at the end of a colloquium I heard Debye saying something like: “Schroedinger, you are not working right now on very important problems… why don’t you tell us some time about that thesis of de Broglie’s… in one of the next colloquia, Schroedinger gave a beautifully clear account of how de Broglie associated a wave with a particle, and how he could obtain the quantization rules… When he had finished, Debye casually remarked that he thought this way of talking was rather childish… To deal properly with waves, one had to have a wave equation. Felix Bloch, Address to the American Physical Society, 1976

Schroedinger’s key assumptions concerning a quantum-mechanical wave equation... 1It must incorporate the relations: 2Since normal waves “add” linearly (principle of superposition), so too must the solutions to the qm- wave equation. This means the solutions must be linear.

from the first assumption... Kinetic + Potential = Total Energy

from the second assumption... Introduce “psi” as the solution to a wave equation. It could include terms like: where “psi” is the wavefuntion

now, assume that psi describes a travelling wave... Psi should have the form: The derivatives should produce the expressions listed in the 1st assumption, so...

from assumption 1... We get our “lambda-term” from a 2nd spatial derivative, ie since we need a We get the “nu-term” from the 1st time derivative, ie

Also, since contains a potential term V(x,t), our equation should contain a V(x,t) factor… hence we are led to “guess” an equation of the form: we now must solve for  and .

wrinkles (there are ALWAYS wrinkles!) It will be left as an exercise for you to show why will not work, instead we will try this… With a little bit of work we find:

so, without further delay...