Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download α | Q | β 〉= Q (t) . 〈 Review
Document related concepts
EPR paradox wikipedia , lookup
Matter wave wikipedia , lookup
Density matrix wikipedia , lookup
Bell's theorem wikipedia , lookup
Compact operator on Hilbert space wikipedia , lookup
Quantum electrodynamics wikipedia , lookup
Identical particles wikipedia , lookup
Self-adjoint operator wikipedia , lookup
Wave–particle duality wikipedia , lookup
Quantum field theory wikipedia , lookup
Quantum chromodynamics wikipedia , lookup
Hidden variable theory wikipedia , lookup
Atomic theory wikipedia , lookup
Perturbation theory (quantum mechanics) wikipedia , lookup
Perturbation theory wikipedia , lookup
Topological quantum field theory wikipedia , lookup
Elementary particle wikipedia , lookup
Renormalization wikipedia , lookup
Yang–Mills theory wikipedia , lookup
Scalar field theory wikipedia , lookup
Symmetry in quantum mechanics wikipedia , lookup
History of quantum field theory wikipedia , lookup
Transcript
Chapter 3 : Green’s functions and field
theory (fermions)
Review
♱
The predictions of a quantum theory
depend entirely on matrix elements;
〈 α | Q | β 〉= Qαβ(t) .
H = ∫ ψ♱(x) T(x) ψ(x) d3x
♱
6. PICTURES
3
3
+½ ∫∫ ψ (x) ψ (x’) V(x,x’) ψ(x’) ψ(x) d xd x’
Now which parts of the theory (i.e., states or
operators) depend on time?
{ψ(x) , ψ(x’)} = 0
Schroedinger picture: the states depend on time
and the operators do not depend on time.
{ψ(x) , ψ♱(x’)} = δ3(x-x’)
Heisenberg picture: the operators depend on time
and the states do not depend on time.
(spin indices are suppressed)
ΑΒΓΔΕΖΗΘΙΚΛΜΝΞΟΠΡΣΤΥΦΧΨ
Ω
αβγδεζηθικλμνξοπρςστυφχψω
+<=>±×⁄←↑→↓⇒⇔∇∏∑−∓∙√∞
≤≥≪≫∫∲∂≠〈〉ħ ♱
Interaction picture: both states and operators
depend on time.
The matrix elements , and hence predictions,
must be equal in all three pictures. For example,
〈αS(t) | QS | βS (t)〉= 〈αH | QH (t) | βH〉.
6a. The Schroedinger picture
(the most familiar)
6b. The interaction picture
(useful for perturbation theory)
6c. The Heisenberg picture
(important for proving general theorems)
Perturbation theory and the interaction
picture ...
Assume H = H0 + H1 ,
where H0 is solvable and H1 is a set of
interactions, possibly having small
effects.
{Usually H0 is a single particle operator;
and H1 is a two-particle operator
describing the interactions between
particles.}
How can we calculate the effects of H1 ?
6d. Adiabatic “switching on”
6e. Gell-Mann & Low theorem
Assume H = H0 + H1 e−ε|t|
This is a bit of a technicality.
and let ε ⟶ 0 at the end of the
calculations.
It implies that the limiting process
ε ⟶ 0 is OK in spite of singularities.
Acceptable results must have valid limits
as ε ⟶ 0 .
Formally, the state defined by this ratio
The initial and final states ,
i.e., as t ⟶ −∞ and +∞,
are free particles,
i.e., eigenstates of H0.
The state experiences the interactions H1
during the time -1/ε ≲ t ≲ +1/ε .
| ψ0 ( t=0 ) >ε /
< ϕ0 | ψ0 ( t=0 ) >ε
is well defined as ε ⟶ 0 ;
and it is an eigenstate of the full
Hamiltonian, H.
( ϕ0 means the free particle state at
t = −∞.)
