Calculating Lifetimes in a Three-Level System with Einstein A & B Coefficients?

[bananabandana]

Homework Statement

Homework Equations

The Attempt at a Solution

Very confused by this problem. For one thing, it doesn't specify if there is or isn't any light present to drive the stimulated emission/absorbtion. I guess there's no reason to assume that there is no light - but since the question is asking about lifetimes, that would seem more sensible...[plus introducing an unspecified $\rho(\omega_{0})$ seems odd]

Assuming there is no light involved, then this is just a three level system, with three sets of coupled differential equations describing the behaviour - let $N_{i}$ be the number of atoms in state $i$:
(1) $$ \frac{dN_{A}}{dt} = -(A_{ac}+A_{ab})N_{A} $$
(2) $$ \frac{dN_{B}}{dt} = A_{ab}(N_{A} -N_{B}) $$
(3) $$ \frac{dN_{C}}{dt} = A_{ac}N_{A}+A_{bc}N_{B} $$
[Though,one of them is made redundant by the fact that total particle number must be constant.]

We can easily solve the first equation:
$$ N_{A} = N_{A0}exp\bigg[ - (A_{ac}+A_{ab})t) \bigg] $$
By substituting this into the equation (2), we can then solve for $N_{B}$:

$$ \frac{dN_{B}}{dt} +N_{B}A_{ab} = A_{ab}N_{A0}exp\bigg[ - (A_{ac}+A_{ab})t) \bigg] $$

So by using the standard method of integrating factors:
$$ N_{B} = Cexp(-A_{ab}t)-\frac{A_{ab}}{A_{ac}}N_{A0}exp(-A_{ac}+A_{ab}t) $$
But how am I meant to define a lifetime for that?, Assuming $N_{B}(t=0)=0$, i.e:
$$ N_{B} =\frac{A_{ab}}{A_{ac}}N_{A0}exp(-A_{ab}t)\bigg[1-exp(-A_{ac}t)\bigg]$$
Do we take the dominant exponential to define the lifetime?

 

[Simon Bridge]

You are only told to consider the decays a-c and b-c.
The presence of photons is not relevant to the lifetime calculation for a state ... check the definition of "lifetime" in your notes.

 

[bananabandana]

You are only told to consider the decays a-c and b-c.
The presence of photons is not relevant to the lifetime calculation for a state ... check the definition of "lifetime" in your notes.

Ah,okay, so lifetimes are generally defined to only involve the Einstein $A$ coefficients.
So I can just ignore completely $\psi_{A} \rightarrow \psi_{B}$? I wasn't sure the question implied that... I guess if it does:

$$ \frac{dN_{A}}{dt} = -A_{ac}N_{A} $$
$$ \frac{dN_{B}}{dt} = -A_{bc} N_{B} $$

Implying that $\lambda_{a} = A_{ac}$ $\lambda_{b} = A_{bc}$. We know that $\frac{1}{\tau} = \lambda$ where $\tau$ is the lifetime, so:
$$ \frac{\tau_{A}}{\tau_{C}} = 2 $$

and then the information about the matrix element is completely redundant? It's that simple??
[Edit : I mean, it tells us the same thing]
Thanks!

 

[Simon Bridge]

Well done.

 

[bananabandana]

Oh dear, that's embarrassing.. Ah well, many thanks for the help, much appreciated!