1000 Solved Problems in Modern Physics

(Tina Meador) #1

286 4 Thermodynamics and Statistical Physics


p=

1

3

ρ<ν^2 >
whereρis the mass density. In the case of photon gas, the speed of all photons
is identical being equal toc. Furthermore, from Einstein’s relation
u=ρc^2
whereuis the energy density. Replacing<ν^2 >byc^2
prad=

1

3

ρc^2 =

u
3

4.64 LetTandT 0 be the Kelvin temperatures of the body and the surroundings.
Then, by Stefan–Boltzmann law, the rate of loss of heat per unit area of the
body is
dQ
dt


=σ(T^4 −T 04 )

=σ(T−T 0 )(T+T 0 )(T^2 +T 02 )
If (T−T 0 ) be small, (T≈T 0 ), and
dQ
dt

=σ(T−T 0 )× 4 T 03

SinceT 0 is constant,
dT
dt

∝(T−T 0 ); (Newton’s law of cooling).

4.65 The energy densityuand pressurepof radiation are related by


p=

u
3
Furthermore,u= 4 σT^4 /c
Eliminatingu,

T=

(

3 cp
4 σ

) 1 / 4

=

(

3 × 3 × 108 × 4 × 108 × 1. 013 × 105

4 × 5. 67 × 10 −^8

) 1 / 4

= 2 × 107 K

4.66 (a)Power,P=σAT^4 = 4 πR^2 σT^4


= 4 π(7× 108 )^2 (5. 67 × 10 −^8 )(5,700)^4
= 3. 68 × 1026 W

Mass lost per second,m=P/c^2 =

3. 68 × 1026

(3× 108 )^2

= 4. 1 × 109 kg/s

(b) Time taken for the mass of sun (M) to decrease by 1% is

t=

M

100

×

1

m

=

2 × 1030

100

×

1

4. 1 × 109

= 4. 88 × 1018 s

=

4. 88 × 1018

3. 15 × 107

= 1. 55 × 1011 years
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