Time-dependent perturbation theory 541UˆI(t;t 0 ) =T[
exp(
−
i
̄h∫tt 0dt′HˆI(t′))]
, (14.2.31)
which is known as atime-ordered exponential. Since eqn. (14.2.31) is just a shorthand
for eqn. (14.2.30), it is understood that the time-ordering operator orders the operators
in each term of an expansion of the exponential.
Given the formalism of time-dependent perturbation theory, we now seek to answer
the following question: If the system is initially in an eigenstate ofHˆ 0 with energyEi,
what is the probability as a function of timetthat the system will undergo a transition
to a new eigenstate ofHˆ 0 with energyEf? To answer this question, we first set the
initial state vector|Ψ(t 0 )〉equal to the eigenvector|Ei〉ofHˆ 0. Then, the amplitude
as a function of time that the system will undergo a transition to theeigenstate|Ef〉
is obtained by propagating this initial state to timetwith the propagatorUˆ(t;t 0 ) and
then taking the overlap of the resulting state with the eigenstate|Ef〉:
Afi(t) =〈Ef|Uˆ(t;t 0 )|Ei〉. (14.2.32)The probability is just the square modulus of this complex amplitude:
Pfi(t) =∣
∣
∣〈Ef|Uˆ(t;t 0 )|Ei〉∣
∣
∣
2. (14.2.33)
Consider first the amplitude at zeroth order in perturbation theory. At this order,
Uˆ(t;t 0 ) =Uˆ 0 (t;t 0 ), and the amplitude is simply
A(0)fi(t) =〈Ef|e−i
Hˆ 0 (t−t 0 )/ ̄h
|Ei〉= e−iEi(t−t^0 )/ ̄h〈Ef|Ei〉, (14.2.34)which clearly vanishes by orthogonality ifEi 6 =Ef. Thus, at zeroth order, the only
possibility is a trivial one in which no transition occurs.
The lowest nontrivial (Ei 6 =Ef) result occurs at first order, where the transition
amplitude is given by
Afi(1)(t) =〈Ef|Uˆ(1)(t;t 0 )|Ei〉=−
i
̄h∫tt 0dt′〈Ef|Uˆ 0 (t;t′)Hˆ 1 (t′)Uˆ 0 (t′;t 0 )|Ei〉=−
i
̄h∫tt 0dt′〈Ef|e−i
Hˆ 0 (t−t′)/ ̄hˆ
H 1 (t′)e−i
Hˆ 0 (t′−t 0 )/ ̄h
|Ei〉=−
i
̄h∫tt 0dt′e−iEf(t−t′)/ ̄h
e−iEi(t′−t 0 )/ ̄h
〈Ef|Hˆ 1 (t′)|Ei〉