T1: Free Relativistic Quantum Field Theories Flashcards
How do we move from Lagrangian to Hamiltonian field theories?
Define some generalised coordinate ϕ(x,t)
Define some conjugate π = ∂L/∂ϕ ̇
Define normal ordering
Field ordering such that all energy raising operators appear to the left of of energy lowering operators.
Give the relation between ω k and m
ω_k = sqrt(k^2 +m^2)
Define the Hamiltonian density (and hence Hamiltonian)
H(ϕ,π) = -L + SUM_a πϕ ̇
State the particle commutators (in H and S pictures)
[qa, qb] = 0
[pa, pb] = 0
[qa, pb] = δab
(all at t1=t2 for H)
How do the quantum commutators change for QFT?
[ϕ_a (x,t), π_b (y,t)] = i δ_ab δ(x-y)
How can we show the free complex scalar field behaves as a quantised SHO?
Fourier transform the solution in terms of some new label k. Rewrite the Klein-Gordon in separate terms and act on the state.
Give the commutator relations for the creation annihilation operators with eachother (Q)
[a, a†] = 1
[a, a] = 0
[a†, a†] = 0
Give the commutator relations for the creation annihilation operators with the Hamiltonian (Q)
[H, a†] = ωa†
[H, a] = -ωa
State the Hamiltonian for the SHO (Q)
H = ω/2 (a†a +a a†) = ω(a†a + 1/2)
Give the excited state and energy spectrum for SHO (Q)
(a†)^n |0⟩
H|n⟩ = ω(n +1/2)
State the general solution of ϕ~ for SHO (QFT)
ϕ(k,t) = 1/sqrt(2ω_k) [a_k e^-iωt + b*_k e^iωt]
State the general solution ϕ for the Klein gordon SHO (QFT)
Integrate ϕ~ over d^3k/(2π)^3 and add an e^-k⋅x with each exponential.
Make change of integration variables in t2 sending k to -k
Give the commutator relations for the creation annihilation operators with eachother (QFT)
[a_k, a_k’†] = (2π)^3 δ(k-k’)
State the Hamiltonian for the SHO with frequency ω_k (QFT)
H = ω(a†a + bb†)
ω, a and b have _k
Integrate over d^3k/(2π)^3
