siifuthun
Sep17-06, 07:09 PM
I need a refresher on calculus need to derive this equation, the question is:
A --> B --> C
and where decay constants:
http://img183.imageshack.us/img183/4403/aki2.jpg
Derive an expression for the activity of B as a function of time.
So what I'm having trouble with is changing the derivation for the number of N when lambda_A = lambda_B so that I derive the activity of B.
Normally we would have:
http://img157.imageshack.us/img157/3501/ajh6.jpg
But because of the condition, we have to go about it differently. So setting the decay constants equal to each other:
http://img182.imageshack.us/img182/192/asa5.jpg
And this is where I get a little stumped trying to change the derivation. When lambda_A doesn't equal lambda_B, the derivation ends up with:
http://img226.imageshack.us/img226/1602/akk1.jpg
The problem I'm having is that I'm not sure what has to be done differently in the original derivation to solve for activity, my calculus skills are a little rusty so if anyone has any suggestions or advice, it's greatly appreciated.
A --> B --> C
and where decay constants:
http://img183.imageshack.us/img183/4403/aki2.jpg
Derive an expression for the activity of B as a function of time.
So what I'm having trouble with is changing the derivation for the number of N when lambda_A = lambda_B so that I derive the activity of B.
Normally we would have:
http://img157.imageshack.us/img157/3501/ajh6.jpg
But because of the condition, we have to go about it differently. So setting the decay constants equal to each other:
http://img182.imageshack.us/img182/192/asa5.jpg
And this is where I get a little stumped trying to change the derivation. When lambda_A doesn't equal lambda_B, the derivation ends up with:
http://img226.imageshack.us/img226/1602/akk1.jpg
The problem I'm having is that I'm not sure what has to be done differently in the original derivation to solve for activity, my calculus skills are a little rusty so if anyone has any suggestions or advice, it's greatly appreciated.