Calculating Scattering Cross Sections

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The discussion focuses on calculating the scattering cross sections of alpha particles incident on a gold foil. Participants address the integration of the differential cross-section formula and the correct application of units, emphasizing the importance of using SI units consistently. The integration limits are clarified to reflect the small angular width of the detector for both 10 and 45 degrees. Corrections to the number density of gold are discussed, with a conversion to kg/m² and the use of Avogadro's number to find accurate values. Ultimately, the expected counts per second for the detector are confirmed as 4020 for 10 degrees and 11.4 for 45 degrees.
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Homework Statement



A beam of \alpha-particles, of kinetic energy 5.3 MeV and intensity 10^{4} particle/sec, is incident normally on gold foil with thinckness 1 x 10^{-5} cm. (The density, atomic weight and atomic number of gold are 19.3 g/cm, 197 and 79 respectively.) A particle counter of area 1 cm^{2} is placed on the opposite side of the foil from the incoming beam at a distance of 10 cm. Suppose \theta is the angle between the center of the foil and the center of the detector. How many counts should we expect per second if the detector registers all particles passing through it at \theta=10 degrees and \theta=45 degrees?

Homework Equations



\frac{d\sigma}{d\Omega}=(\frac{1}{4\pi\epsilon_{0}})^{2} (\frac{zZe^{2}}{2Mv^{2}})^{2} I n \frac{1}{sin^{4}(\frac{\theta}{2})}

where n is the number of nuclei per unit area, and I is the incident intensity.

also told that:

2 \pi sin(\theta) d\theta=d\Omega

and

dN=\frac{d\sigma}{d\Omega} d\Omega

The Attempt at a Solution



First I calculated the constant:

(\frac{1}{4\pi\epsilon_{0}})^{2} (\frac{zZe^{2}}{2Mv^{2}})^{2}

where I had 2Mv^{2}=4(5.3 MeV), z=2, Z=79

Then I found n:

n=\frac{19.3g}{cm^{3}}\frac{1}{197amu}1 x 10^{-5}cm

now's where I have a problem... I'm trying to integrate:

2\pi(\frac{sin(\theta)}{sin^{4}(\frac{\theta}{2})})d\theta

but I don't know what angles to integrate thru... when I draw a diagram, I get a pretty small angular range and my answer comes out too small.


the answers are:

for 45 degrees = 11.4 counts/sec.
and for 10 degrees = 4020 counts/sec.

I could really use some help on seeing how these answers are obtained... thanks!
 
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Haven't looked in detail at your attempt. First, make sure you're using the correct units, and consistently. Usually safest to work in SI units unless an equation specifies to use some non-standard units. Next, your integration region is indeed the small angular width of the detector (10deg-small amount to 10deg+small amount and similarly for 45deg case). For the integration, you can define \theta&#039;=\theta/2 and use the trig identity \sin(2\theta&#039;)=2\sin\theta&#039; \cos\theta&#039;. Then d\theta=2d\theta&#039; and the cosine can be "brought into the differential": <br /> \cos\theta&#039; d\theta&#039;=d \sin\theta&#039;.
 
i am doing that exact integral now. i just posted it in cal.analysis. i am trying to use the substitution u=cos(theta/2) but it hasnt produced anything of value yet.
 
ok i finally finished this problem. you have to find d(omega), not by integrating the sin stuff u have above. use d(omega) = INTEGRAL of dA/r^2 so you pull out the r^s terms using 10^2 cm^2, and use 1 cm for the area A. youll get 1/100.second thing is you have to correct your n value. i converted the density to kg/m^2. then i divided it 197, and multiplied it by avagad's number to arrive at 5.897x10^28. crunching all this then youll get close. you should get 6...x10^-5 x 1/sin^4(theta/2). the last trick ill leave for you to do. remember you have to find the counts per hr. but the equation will be in s^-1.
good luck.
 
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