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Transcript
Quantum Mechanics History • Beginning in 1900, some experiments showed some disagreement with “classical” mechanics and understanding of light • Planck/Einstein first people to propose a key idea – Light was made up of particles = photons Quantum • Quanta – Latin for little bits • Light is quantized = comes in little bits/particles • Light acts like a wave (interference) • Light acts like a particle (photoelectric effect) Photoelectric effect • Einstein – 1905 – Nobel Prize • Light comes in and hits a metal • Electrons leave the metal with a given energy • Explanation: Photons have a collision with electrons and transfer energy/momentum to the electron • Data matched theory exceptionally well Light • Light has energy/momentum E = hf = hc/l p = E/c = h/l h = Planck’s constant = 6.626 x 10-34 Particle-Wave Duality • If a wave (like light) acts like a particle, can particles act like waves? Electrons as waves • Previous pattern means that electrons interfere with each other – They act like waves – What is their wavelength? • Pattern consistent with a wavelength l = h/p • Same relation as with light • Called the deBroglie wavelength Now what? • If electrons (and other particles) can act like waves, what else can they do? • They can setup standing waves – Waves with particular wavelength/frequency that appear to not be travelling Electron standing waves • Electrons in a box (like strings fixed at both ends) have a standing wave pattern • Different harmonics have different frequencies • Difference frequencies means different energies Standing waves • Recall: E = ½ mv2 and p = mv E = p2/2m p = h/l and l = 2L/n • Put it all together: E = n2h2/(8mL2) • Only certain energies are allowed (n=1,2,3,…) – Energy is quantized Electrons in an atom • Electrons can form standing waves going around a nucleus • Only some wavelengths fit only certain energy levels – nl = 2pr Energy levels • E = ½ mv2 = h2/(2ml2) • Use l = 2pr/n and r = a0 = Bohr radius E = n2h2/(8p2ma02) Theory: Use n = 1 and a0 = 5.29 x 10-11 m E1 = 2.18 x 10-18 J Measured value: 2.176 x 10-18 J Particles as Waves • If particles can be described by waves, they are constantly moving • Location can be described by a wave function – Amplitude of wave given by Y(x,t) – Probability of being at a certain place is given by Y2(x,t) • Theory of quantum mechanics is essentially an equation telling you how to find this wavefunction Schrodinger Equation • Describes where a particle is as a function of time Here it is: Solution is the wavefunction! Only certain solutions allowed for particular values of E Energy is quantized Schrodinger Equation • Can use this to solve the electron in the box and the Hydrogen atom • Gives the solutions that we had before for the energies • What does the wavefunction look like? – Where is the electron? Hydrogen atom • A few solutions for the Hydrogen atom • Look familiar? Atomic orbitals Electron orbitals • The shape of the electron orbitals is given by the solution to the Schrodinger equation • Remember: all came about because energy is quantized because electrons act like (standing) waves Quantum Mechanics Other Quantum Weirdness • Heisenberg Uncertainty principle Can’t measure the position and the velocity/momentum at the same • Meaning: The act of measuring the location an object affects its momentum, so can’t know both at the same time Probability • Everything described by a wavefunction • Tells you probability of where something is can’t tell you for certain • Has some probability that a particle is here and there at the same time – Won’t know until you measure it Schrodinger’s Cat • Put cat in box with a radioactive compound that has some probability of decaying and close the box • Cat has some probability that it dies and some probability that it lives – We say that cat is in a superposition of dead and alive states – Won’t know until we open the box Tunneling • Look at the p orbital • Probability that electron in top half • Probability that electron in bottom half • Node in the middle – no probability • So particle can travel from the top part to the bottom part without going through the middle tunneling
