I tried calculating the mass of the target particle of the first peak in my energy spectra M_{2} and then the number of particles per cm^2 Nt. However, the numbers that I found do not seem to be correct:
K = \frac{E_{1}}{E_{0}}=\left ( \frac{M_{1}cos\theta + \sqrt{M_{2}^{2}-M_{1}^{2}\left ( sin^{2}\theta \right )} }{M_{1}+M_{2}} \right )^{2}
Looking at the first peak of my example spectra, I took
M_{1}= 4 (Helium)
E_{0}= 1 MeV
E_{1}= 125 KeV
\theta= 165 degrees
So the equation becomes:
\frac{.125 MeV}{1 MeV}=\left ( \frac{4*cos(165) + \sqrt{M_{2}^{2}-4^{2}\left ( sin^{2}(165)\right )} }{4+M_{2}} \right )^{2}
And I find that M_{2}=8.545 Amu. So would this correspond with Beryllium?
Now knowing the atomic number of Beryllium, I can calculate the areal density Nt_{Be} using the relation
\frac{A_{Be}}{A_{Bi}}=\left (\frac{Z_{Be}}{Z_{Bi}} \right )^{2}\frac{Q_{Be}*Nt_{Be}}{Q_{Bi}*Nt_{Bi}}
Where A_{Be},Q_{Be},Nt_{Be},and Z_{Be} come from a reference experiment with the quantities:
A_{Be} = 24000(Number of particles detected)
Nt_{Be} = 5.65*10^{15} Atoms/cm^{2} (Given quantity)
Z_{Be} = 83
We are provided a given dose = 10\mu c and I0 ~ 70 nA:
Q_{Be} = \frac{Dose}{Charge of Helium} = \frac{10^{-5} C}{2e} (Number of incident particles) Is this how one calculates Q?
Nt_{Be}=\frac{A_{Be}}{A_{Bi}}\left (\frac{Z_{Bi}}{Z_{Be}} \right )^{2}\frac{Q_{Bi}*Nt_{Bi}}{Q_{Be}}=\frac{22000}{24000}\left (\frac{83}{4} \right )^{2}{5.65*10^{15}}=2.23*10^{18} Atoms/cm^{2}
This does not seem to be right. Any help that you could provide me would be greatly appreciated!
