1000 Solved Problems in Modern Physics

(Tina Meador) #1

6.3 Solutions 341


and at the counter C
Ic=IAexp (− 2 d/γβcτ)(2)

∴Ic=

IB^2

IA

=

(470)^2

1000

= 221

(b) Take logarithm on both sides of (1) and simplify.
τ=

d
γβcln(IA/IB)

(3)

γ= 1 +T/mc^2 = 1 + 140 / 140 = 2. 0
β=(γ^2 −1)^1 /^2 /γ= 0. 866
d=10 m;c= 3 × 108 m/s
ln(IA/IB)=ln(1000/470)= 0. 755
Substituting the above values in (3),
τ= 2. 55 × 10 −^8 s
The accepted value is 2. 6 × 10 −^8 s

6.36 The stationary object will appear to move with velocity−βctoward the
observer. The object moving with velocityαctoward the stationary object
would appear to have velocity
(αc−βc)/(1−αβ), as seen by the observer. If these two velocities are to be
equal then (αc−βc)/(1−αβ)=βc
Cross multiplying and simplifying we get the quadratic equation whose
solution isβ=[1−(1−α^2 )^1 /^2 ]/α


6.37
(i) t=


L

βc

(1)

N 2 =N 1 exp[−t/γτ]=N 1 exp

[


L

γβcτ

]

(2)

Therefore (2) becomes
exp

[

L
γβcτ

]

=N 1 /N 2

Take logarithm on both sides
L
γβcτ=ln

(

N 1
N 2

)

Butγβ=


γ^2 − 1
Thereforeτ= L
ln

(N
N^1
2

)√

γ^2 − 1 c

(ii) γ= 1 /(1−β^2 )^1 /^2 = 1 /(1− 8 /9)^1 /^2 = 3
τ=

200

ln

(

10 , 000
8 , 983

)√

32 − 1 × 3 × 108

= 2. 2 × 10 −^6 s.
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