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Particle in a box or a sphere From Last Time… • Simple in 1D(or 2,3D) box • Hydrogen atom in 3D – Fit n half wavelengths in the box L – Electron has a particle and wave nature and is spread out over space • More complex in the hydrogen atom – Wave nature must interfere constructively to exist – Satisfies 3 conditions for constructive interference – Box, the force that keeps the electron near the nucleus, is the coulomb force – Coulomb force is spherically symmetric - the same in any direction – Still 3 quantum numbers Today • Meaning of the hydrogen atom quantum numbers • Quantum jumps and tunneling HW #8: Chapter 14: Conceptual: # 10, 24, 29, 33 Problems: # 2, 5 Due: Nov 15th 1 Phys107 Fall 2006 Hydrogen Quantum Numbers 2 Phys107 Fall 2006 Hydrogen Quantum Numbers • Quantum numbers, n, l, ml • What do they mean? • n: how charge is distributed radially around the nucleus. Average radial distance. • Quantum numbers, n, l, ml • l: how spherical the charge is the distribution – l = 0, spherical, l = 1 less spherical… – n must be bigger than 1, need more room for non spherical distributions – This determines the energy since it’s dependent on the potential energy of the coulomb force and the wavelength (how many fit around) n=1 n=1 2s-state Hydrogen Quantum Numbers 4 Phys107 Fall 2006 Uncertainty in Quantum Mechanics • Quantum numbers, n, l, ml • n: rotation of the charge – If the charge is distributed such that it can rotate around the nucleus does it rotate clockwise, counterclockwise and how fast? – n > 1 and n > 0 – Need a non spherical distribution – Need a clear axis to spin around 2p-state 2p-state Phys107 Fall 2006 n = 2, l = 1, ml = ±1 n = 2, l = 1, ml = 0 3 Phys107 Fall 2006 n = 2, l = 1, ml = 0 2p-state 2p-state 2s-state 1s-state Position uncertainty = L (Since =2L) Momentum ranges from h h h h to + :range = 2 = L = 2L One halfwavelength L Reducing the box size reduces position uncertainty, but the momentum uncertainty goes up! n = 2, l = 1, ml = ±1 5 The product is constant: (position uncertainty)x(momentum uncertainty) ~ h Phys107 Fall 2006 6 1 More unusual aspects of quantum mechanics The wavefunction and quantum ‘jumps’ • Quantum jumps: wavefunction of particle changes throughout all space when it changes quantum state. • Superposition: quantum mechanics says wavefunction can be in two very different configurations, both at the same time. • Measurements: The act of measuring a quantum system can change its quantum state • Quantum Tunneling: particles can sometimes escape the quantum boxes they are in • Entanglement: two quantum-mechanical objects can be intertwined so that their behaviors are instantly correlated over enormous distances. • A quantum system has only certain discrete quantum states in which it can exist. • Each quantum state has distinct wavefunction, which extends throughout all space • It’s square gives probability of finding electron at a particular spatial location. • When particle changes it’s quantum state, wavefunction throughout all space changes. 7 Phys107 Fall 2006 8 Phys107 Fall 2006 Hydrogen atom quantum jump n=4 n=3 n=2 Photon emitted hf=E3-E1 The electron jumps from one quantum state to another, changing its wavefunction everywhere. During the transition, we say that the electron is briefly in a superposition between the two states. n=1 Wavefunction changes from 3p to 1s throughout all space. 9 Phys107 Fall 2006 10 Phys107 Fall 2006 Quantum mechanics says something different! Unusual wave effects • Classically, pendulum with particular energy never swings beyond maximum point. • This region is ‘classically forbidden’ • Quantum wave function extends into classically forbidden region. In quantum mechanics, there is some probability of the particle penetrating through the walls of the box. Low energy Classical state Low energy Quantum state Classically forbidden region Phys107 Fall 2006 End of swing Nonzero probability of being outside the box! 11 Phys107 Fall 2006 12 2 Two neighboring boxes The tunneling distance • When another box is brought nearby, the electron may disappear from one well, and appear in the other! • The reverse then happens, and the electron oscillates back an forth, without ‘traversing’ the intervening distance. ‘high’ probability Low probability 13 Phys107 Fall 2006 Example: Ammonia molecule 14 Phys107 Fall 2006 Atomic clock question N H H H • NH3 • Nitrogen (N) has two equivalent ‘stable’ positions. • It quantum-mechanically tunnels between 2.4x1011 times per second (24 GHz) • Was basis of first ‘atomic’ clock (1949) Phys107 Fall 2006 Suppose we changed the ammonia molecule so that the distance between the two stable positions of the nitrogen atom INCREASED. The clock would A. slow down. B. speed up. C. stay the same. N H H H 15 16 Phys107 Fall 2006 Quantum version Classical particle in a box • Quantum state is both velocities at the same time • Box is stationary, so average speed is zero. • But remember the classical version = 2L One halfwavelength L L momentum h h p= = 2L • Ground state is a standing wave, made equally of – Wave traveling right ( positive momentum +h/ ) – Wave traveling left ( negative momentum - h/ ) • Particle bounces back and forth. – On average, velocity is zero. – But not instantaneously – Sometimes velocity is to left, sometimes to right Phys107 Fall 2006 17 Quantum ground state is equal superposition of two very different motions. Phys107 Fall 2006 18 3 The wavefunction Making a measurement Suppose you measure the speed (hence, momentum) of the quantum particle in a tube. How likely are you to measure the particle moving to the left? • The wavefunction for the particle is an equal ‘superposition’ of the two states of precise momentum. • When we measure the momentum (speed), we find one of these two possibilities. A. 0% (never) B. 33% (1/3 of the time) • Because they are equally weighted, we measure them with equal probability. C. 50% (1/2 of the time) Phys107 Fall 2006 • Wavefunction = = |moving to right> + |moving to left> 19 A Measurement Phys107 Fall 2006 20 Double-slit particle interference • We interpret this as saying that before the measurement, particle exists equally in states – momentum to right – momentum to left • When we measure the momentum, we get a particular value (right or left). • The probability is determined by the weighting of the quantum state in the wavefunction. • The measurement has altered the wavefunction. The wavefunction has ‘collapsed’ into a definite momentum state. Phys107 Fall 2006 21 • With single photons at a time • Which slit does the photon go through? Phys107 Fall 2006 22 Photon on both paths Which slit? Path 1: photon goes through left slit Path 2: photon goes through right slit In the two-slit experiment with one photon, which slit does the photon go through? Wavefunction for the photon is a superposition of these two states. A. Left slit B. Right slit C. Both slits Quantum mechanics says photon is simultaneously on two widely separated paths. Phys107 Fall 2006 23 Phys107 Fall 2006 24 4 Superposition of quantum states Measuring which slit • We made a localized state made by superimposing (‘adding together’) states of different wavelength (momenta). • Quantum mechanics says this wavefunction physically represents the particle. • The amplitude squared of each contribution is the probability that a measurement will determine a particular momentum. • Copenhagen interpretation says that before a measurement, all momenta exist. Measurement ‘collapses’ the wavefunction into a particular momentum state (this is the measured momentum). Phys107 Fall 2006 25 Measure induced current from moving charged particle • Suppose we measure which slit the particle goes through? • Interference pattern is destroyed! • Wavefunction changes instantaneously over entire screen when measurement is made. Phys107 Fall 2006 26 What is object before the measurement? A superposition state • Margarita or Beer? • What is this new drink? • Is it really a physical object? • Exactly how does the transformation from this object to a beer or a margarita take place? • This is the collapse of the wavefunction. • This QM state has equal superposition of two. • Each outcome (drinking margarita, drinking beer) is equally likely. • Actual outcome not determined until measurement is made (drink is tasted). Phys107 Fall 2006 27 Phys107 Fall 2006 28 Not universally accepted • Historically, not everyone agreed with this interpretation. • Einstein was a notable opponent – ‘God does not play dice’ • These ideas hotly debated in the early part of the 20th century. • However, led us to the last piece necessary to understand the hydrogen atom Phys107 Fall 2006 29 5