T2: Path integrals in QFT Flashcards
What spacetime dimensions do d = -1 and d = 0 correspond to?
d = -1 ordinary integrals
d = 0 quantum mechanics
Generalise the transition amplitude to N particles
Add a [Dq_n] for each particle from 1,..,n
The action runs over n positions and n conjugate momenta.
2N boundary conditions q_n (t) = q_n and q_n (t’) = q_n’
Generalise the transition amplitude to scalar fields ⟨ϕ’,t’|ϕ,t⟩
N INT [Dϕ] exp[iS]
S = INT_ti ^tf INT d^dx L(ϕ, ∂_μ ϕ)
Define the generating functional Z[J] of the free scalar field theory
Z_0[J] = N exp(1/2 INT d^4x d^4y J(x)G_F^0(x,y)J(y) )
Note, the 4 can be any d+1 dimensions
How do we relate free and interacting scalar field theories
Consider the Lagrangian of the interacting theory as a small perturbation from the free theory
S = S_0 + λS_I
Where |λ|«1
Give the full expression for the generating function of the interacting field theory in terms of Z_0[J]
Z[J] = N exp(iλ INT d^4y L_I δ/δJ(y))Z_0[J]
Draw the propagator G_F^0(x,y) in interacting field theory
X____Y
Draw the loop G_F^0(0) in interacting field theory
0
Draw an external source in interacting field theory
X____ = INT d^4x J(x)
Draw Z_0[J]
Z_0[J] = N exp[1/2 X___X]
Draw the first functional derivative of Z_0[J] wrt to J(y)
= N ∎____X exp(1/2 X____X)
Describe how to take subsequent functional derivatives
Add a cross and connect to a dot or remove a cross from the end of a line and connect to a dot
