PHYS 130B Homework Solutions#
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A self-contained collection of homework problems with worked solutions, one page per lesson. This index lists the problems for each lesson so you can jump directly to the one you need.
Contents#
Chapter 1 — Qubit#
Born rule and probabilities
State reconstruction from probabilities
Global phase invariance
Bloch sphere parametrization
Quantum information
Distinguishing non-orthogonal states
Photon polarization vs. transmon qubit
1.1.2 State and Representation
Qubit state decomposition
State reconstruction from Pauli expectations
State representation in different bases
Bloch vector calculation
Antipodal states on Bloch sphere
Bloch vector rotation
Spin expectation along an arbitrary axis
Parametrization of n-level systems
Spectral decomposition of a two-level Hamiltonian
Hermitian and anti-Hermitian decomposition
Bloch vector from amplitudes
Eigenstate of spin along an arbitrary axis
Pauli decomposition of a 2x2 Hermitian operator
Non-Hermitian eigenstates
Pauli square along an arbitrary axis
Pauli multiplication from commutator and anti-commutator
Measurement probabilities and collapse
Sequential measurements and filters
Measurement of a non-Pauli observable
State inference from measurement frequencies
Phase erasure by complementary measurement
Quantum interference
Filter vs measurement misconception
1.2.2 Uncertainty and Incompatibility
Most general operator commuting with Z
Robertson relation on a specific state
Spin commutator along arbitrary axes
Total Pauli uncertainty for a pure qubit
Sharp observable does not violate Heisenberg
Saturation and maximum of the Robertson bound
Maximising the Z-uncertainty
Minimum of the X-Z uncertainty product
Spin-axis projector
Born rule via projector formula
Spectral decomposition
Two-qubit measurement
Sequential projectors and non-commutativity
Repeatability from idempotence
Operator functions via spectral decomposition
Conservation of observables commuting with H
Exponential of a Pauli matrix
Extracting the generator
Two-level Hamiltonian
Normalization and unitarity
Unitary as Bloch-sphere rotation
Superposition time evolution
Composition and the time-evolution group
Observable evolution in time
General Bloch precession
Larmor evolution of a Y-basis eigenstate
Survival probability
Two-pulse phase-accumulation sequence
Pi-pulse implements the NOT gate
Sequential pulses about different axes
Larmor precession vs Rabi oscillation
Three-state evolution
Picture equivalence on a concrete example
Heisenberg evolution under a tilted Hamiltonian
Pauli precession as a cross product
Harmonic oscillator dynamics
Conservation at the expectation level
SU(2) generator and operator rotation
Cyclic evolution and the half-angle
Algebra of conserved quantities
Chapter 2 — Identical Particles#
Identifying entangled states
Operator products via the mixed-product rule
The SWAP operator
Expectation in product states
Single-body and two-body Z measurements
Heisenberg interaction matrix
Pauli string decomposition
Hilbert-space parametrization
Three-particle statistics
Exchange projectors
Generalized Pauli exclusion
Bosonic normalization factor
Insertion and deletion as inverses
Slater determinant overlap
Fermion counting
Boson counting
Fock states from the vacuum
Number-ladder commutators
Coherent states
Stimulated emission and the boson enhancement factor
Slater determinant from creation operators
Particle-hole conjugation
Two-mode boson tunnelling
Fock space dimensions
Equal partition theorem
Schwinger boson
2.2.1 Angular Momentum Algebra
Spin-1 verification of the angular-momentum algebra
j=3/2 multiplet by repeated lowering
Ladder formula via Schwinger bosons
Ladder action: termination and verification
Transverse variance on an angular-momentum eigenstate
Robertson uncertainty for angular momentum
Vector model and the tilt angle
Quantum bootstrap
Stern-Gerlach for spin-1
Spin-1 rotation operator via polynomial truncation
Spinor rotation by ninety degrees about x
Spinor 2-pi rotation and neutron interferometry
Spin-j rotation: integer vs half-integer
Higher spin representations
Spin-1 time evolution
2.2.3 Addition of Angular Momenta
Angular momentum addition
Total angular momentum
Coupling scheme
Spin-orbit coupling
Spin-1 and spin-1/2 coupling
Lande g-factor
Two-electron exchange interaction
Chapter 3 — Path Integral#
Reflection from Fermat
Total internal reflection
Stratified index gradient
Stationary versus minimum
Corpuscle versus wave speed
Curved mirror focusing
Optics-mechanics dictionary
Refraction at an interface
Reflection from wavefronts
Layered medium ray tracing
Interference of two paths
Slab in an interferometer
Free particle action
De Broglie wavelength
Optics-mechanics translation
Dimensions of action
Path cancellation
Relativistic action limit
3.2.1 Path Integral Formulation
Wavepacket spreading
Composition test
Free-particle slice action
Slice action with a potential
Phase difference between nearby slices
Functional equation from composition
Zeroth Gaussian moment
Second Gaussian moment
Verifying the slice normalization
Slice propagator approaches a delta function
Probability conservation
Higher moments do not matter
Phase-space spreading: loss of minimum uncertainty
Potential placement freedom
3.2.3 Free Particle Propagator
Dispersion relation
Momentum-space form of the free propagator
Direct Gaussian integration
Slice agreement (1D)
Action conjugate relations
Phase velocity vs group velocity
Magnitude and normalization
Macroscopic phase factors
3.3.1 Stationary Phase Approximation
Gaussian check
Cubic phase
Stationary-region width
Second variation
Validity breakdown
Mexican-hat saddles
Harmonic oscillator from SPA
Correspondence principle
Hamilton-Jacobi from WKB
Allowed and forbidden regions
Validity criterion
Square-barrier tunneling (heuristic)
Penetration depth
Airy connection formula
Double-well tunnel splitting
3.3.3 Bohr-Sommerfeld Quantization
Harmonic oscillator
Particle in a box
Linear potential
Anharmonic oscillator
Two-dimensional anisotropic oscillator
Hydrogen atom (circular orbits)
Correspondence principle
Chapter 4 — Phase and Gauge#
Diagnosing redundancy
Plane-wave gauge transform
Covariance of derivatives
Gauge on punctured plane
What gauge transformations cannot do
Second-order bilinear covariance
Gauge connection on links
4.1.2 Electromagnetic Coupling
Velocity for the Pauli Hamiltonian
Velocity uncertainty in B
Cyclotron motion from Heisenberg
Symmetric gauge verification
Field strength tensor components
Gauge-transforming an observable
Probability current
Canonical momentum shifts
Energy under gauge transformation
Coulomb gauge residual freedom
Gauge-invariant classification
Static orthogonality
Reality of the Berry connection
Gauge transformation of the connection
Spin-1 Berry phase
Two gauges on Bloch sphere
Berry phase in Bloch band
Invisible solenoid
Which path matters
Gauge dependence of single paths
Surface independence
AB phase as Berry phase
Electric Aharonov-Bohm
Toroidal magnet
Persistent current at finite temperature
Many fermions on the ring
Half-flux doublet under perturbation
Cooper pair versus electron
Flux-dependent tunneling
SQUID magnetometry
Ground state phase transition
Dimensional analysis
Chapter 5 — Perturbation Theory#
Accuracy window
Inverse design
Basis rotation: energies vs states
Controlled asymmetry
Avoided crossing width
Misconception test
Near-degeneracy diagnosis
5.1.2 Non-degenerate Perturbation Theory
Gauge choice and normalization convention
Three-level perturbation
Coupling over gap
Second-order energy correction and sign
Diagonal and off-diagonal perturbation
Harmonic oscillator with linear perturbation
Selection rules and parity
Near-degeneracy and breakdown
5.1.3 Degenerate Perturbation Theory
Why the old formula fails
Block first, levels later
Effective Hamiltonian and dark state
Hydrogen Stark splitting
Residual degeneracy
When to switch methods
Flux ring with cosine perturbation
Expectations across pictures
Transition frequencies
Choosing a picture
Operator-picture transformation
Two-level system under monochromatic drive
Misconception check
Volterra integral form
Iteration to second order
Time-ordering identity
Bare Green’s function
Schrödinger-picture Dyson series
Recursive Dyson equation
Two-level Feynman diagrams
Three-level virtual transition
Phase cancellation
Sinc-squared properties
Sinc-to-delta
Density of states
Adiabatic ramp Lorentzian
Adiabatic to static perturbation
Three-level Raman (long-time limit)
Minimal Kubo exercise