7.3 Solutions 403
7.30 The fraction of particles scattered in brass at angles exceedingθis given
byΔN/N =(π/4)(1. 442 /T^2 )
(
0. 7 Z 12 /A 1 + 0. 3 Z 22 /A 2
)
ρtN 0 cot^2 θ/ 2 ×
10 −^26 whereZ 1 =29 for copper andZ 2 =30 for Zinc,A 1 = 63 .55 and
A 2 = 65 .38 are the atomic masses, respectively, andN 0 = 6. 02 × 1023 is the
avagadro’s number,T= 1 .5MeV,ρt= 2 × 10 −^3 gcm−^2 andθ= 450 .The
factor 10−^26 is introduced to convert fm^2 into cm^2. Using these values in the
above equationΔN/N= 6. 78 × 10 −^4
7.31 (a)Δσ=σ(90◦, 180 ◦)=(π/4)(1. 44 zZ/T)^2
UsingΔσ= 0 .6kb=60 fm^2 ,z= 2 , Z=79 and solving forT, we get
T= 3 .36 MeV
(b)σ(θ)=(1/16)(1. 44 zZ/T)^21 /sin^4 (θ/2)
Putθ = 90 ◦ andT = 3 .36 MeV to findσ(90) = 1 ,146 fm^2 /sr =
11 .46 b/sr.
7.32 First we work out in the CMS and then transformσ(θ∗)intheCMStoσ(θ)
in the LS.
Rutherford’s formula in CMS is
σ(θ∗)=(1/4)(zZe^2 /μv^2 )^2.^1 /sin^4 (θ/2) (1)
where the reduced mass
μ=mM/(m+M)=m/(1+γ)(2)
wheremandMare the masses of the incident and target masses, respectively,
andγ=m/M.
Further
sin^4 (θ∗/2)=(1/4)(sin^4 θ∗)/(1+cosθ∗)^2 (3)
and
tanθ=sinθ∗/(γ+cosθ∗)(4)
Squaring (4) and expressing it as a quadratic equation and solving it
cosθ=γ sin^2 θ±cosθ(1−γ^2 sin^2 θ)^1 /^2 (5)
Nowσ(θ)=(1+γ^2 + 2 γcosθ∗)^3 /^2 /| 1 +γcosθ∗| (6)
Combining (1), (2), (3), (5) and (6) and after some algebraic manipulations
we get
σ(θ)=
(
zZe^2
2 T
) 2
1
sin^4 θ
[cosθ±(1−γ^2 sin^2 θ)^1 /^2 ]^2
(1−γ^2 sin^2 θ)^1 /^2
Ifγ<1, the positive sign only should be used before the square root. If
γ>1, the expression should be calculated for positive and negative signs and
the results added to obtainσ(θ). Forγ= 1 ,σ(θ)=
(
zZe^2
T
) 2
cosθ
sin^4 θ