De thi vat li quoc te IPHO nam 20071

1.1) One may use any reasonable equation to obtain the dimension of the questioned quantities. Especially, it is.. independent of the Planck constant h which is characteristic of qua[r]

1.1) One may use any reasonable equation to obtain the dimension of the questioned

quantities

I) The Planck relation is hν =E ⇒ [h][ν]=[E] ⇒ [h]=[E][ν]−1 =ML2T−1 (0.2)

III) = 2 ⇒ [G]=[F][r2][m]−2 =M−1L3T−2

r

m m

G

IV) E=K Bθ ⇒ [K B]=[θ]−1[E]=ML2T−2K−1 (0.2)

1.2) Using the Stefan-Boltzmann's law,

4 θ

σ

=

Area

Power

, or any equivalent relation, one obtains:

(0.3)

]

[ ]

[

]

[σ K4 = E L− 2T− 1⇒ σ =MT− 3K− 4 (0.2)

1.3) The Stefan-Boltzmann's constant, up to a numerical coefficient, equals

, δ γ

β

α

σ =h c G k B where α,β,γ,δ can be determined by dimensional analysis Indeed,

, ] [ ] [ ]

[

]

[

]

[σ = hα c β G γ k B δ where e.g [σ]=MT−3K−4

4

3 − − α − β − − γ − − δ α − γ + δ α + β + γ + δ − α − β − γ − δ − δ

MT

(0.2) The above equality is satisfied if,















−

=

−

−

=

−

−

−

−

= + +

+

= +

−

⇒

,

4

, 3 2 2

, 0 2 3 2

, 1

δ

δ γ β

α

δ γ β

α

δ

γ

α

(Each one (0.1)) ⇒















=

=

−

=

−

=

4

, 0

, 2

, 3

δ γ β

α

(Each one (0.1))

3 2 4

h c

k B

=

σ

2.1) Since A , the area of the event horizon, is to be calculated in terms of mfrom a

classical theory of relativistic gravity, e.g the General Relativity, it is a combination of

c , characteristic of special relativity, and G characteristic of gravity Especially, it is

independent of the Planck constant h which is characteristic of quantum mechanical

phenomena

γ

β

α

m

c

G

A=

Exploiting dimensional analysis,

γ β

=

=

⇒

=

] [ ] [ ]

[

]

(0.2) The above equality is satisfied if,











=

−

−

=

+

=

+

−

⇒

, 0 2

, 2 3

, 0

β

α

β

α

γ

α

(Each one (0.1)) ⇒











=

−

=

=

, 2

, 4

, 2

γ β

α

(Each one (0.1))⇒

4

2 2

c

G m

A=

2.2)

From the definition of entropy

θ

dQ

dS = , one obtains [S]=[E][θ]−1 =ML2T−2K−1(0.2)

2.3) Noting η=S A, one verifies that,











=

=

=

=

−

−

−

−

− + + + + +

−

−

−

−

, ]

[ ] [ ]

[

]

[

]

[

, ]

][

[

]

[

2 2 2 2 3

1 2 1

δ δ γ β α δ γ β α δ β α δ

γ β α

η

η

K T

L M

k c h

G

K MT A

S

B

(0.2)

Using the same scheme as above,

⇒















=

−

=

−

−

−

−

= + + +

= + +

−

, 1

, 2 2 2

, 0 2 2

3

, 1

δ

δ γ β α

δ γ β α

δ β α

(Each one (0.1))















=

=

−

=

−

=

⇒

, 1

, 3

, 1

, 1

δ γ β

α

(Each one (0.1))

3

h G

k

c B

=

3.1)

The first law of thermodynamics is dE=dQ+dW By assumption, d W =0 Using the definition of entropy,

θ

dQ

dS= , one obtains,

, 0 +

Using,











=

=

,

, 2 2

mc

E

m ch

k G

[(0.1) for S]

one obtains,

1 2

−













=













=

=

dm

dS c dE

dS dS

dE H

Therefore,

m k G

h c

B H

1 2













=

3.2) The Stefan-Boltzmann's law gives the rate of energy radiation per unit area Noting that E=mc2 we have:





















=

=

=

−

=

,

2

4

2

2

3

2

4

4 ,

, /

mc

E

c

G

m

A

h

c

k

A dt

dE

B

H

σ

σθ

2 2 4 3

3 2

4 2

c

G m m k G

h c h c

k t

d

m d c

B

B













−

= (0.2)

16

1

2 2 4

m G

h c t

d

m

d

−

= (0.1) (for simplification) + (0.2) (for the minus sign)

3.3)

By integration:

1 16

1

2 2

4

m G

h

c

t

d

m

d

−

G

h c dm

⇒

2

4 2

, 16

3 ) 0 ( )

4 3

3

t G

h c m

t

At t=t* the black hole evaporates completely:

0

)

(t* =

2

* 3

16

m h c

G

t =

⇒ (0.2)+(0.1) (for the coefficient)

3.4) C V measures the change in E with respect to variation of θ

(0.2)















=

=

=

m

k

G

h

c

c

m

E

d

E

d

C

B

V

1

2

,

,

3

2

θ

θ

⇒ 2 m2

h c

k G

V =− 0.1)+(0.1) (for the coefficient)

4.1) Again the Stefan-Boltzmann's law gives the rate of energy loss per unit area of the

black hole A similar relation can be used to obtain the energy gained by the black hole due to the background radiation To justify it, note that in the thermal

equilibrium, the total change in the energy is vanishing The blackbody radiation

is given by the Stefan-Boltzmann's law Therefore the rate of energy gain is given

by the same formula









=

+

−

=

,

2

4 4

c

m

E

A A

t

d

E

d

B

σθ σθ

3 8 2 2 2

4 1

G m G

hc dt

dm

B

Bθ

+

−

4.2)

Setting =0

dt

dm

, we have:

1

16

2 4 3

8

2 2

2

4

= +

h c

G m

G

hc

B

and consequently,

B

B

k

G

h

c

m

θ

1

2

3

4.3)













−

−

=

⇒

4 2

2 4

*

3

1 1 16

1

m m

G

hc dt

dm m

k

G

h

c

B

B

4.4) Use the solution to 4.2,

B B

k

G

h

c

m

θ

1

2

3

B m k G

h c

θ

3

One may also argue that m*corresponds to thermal equilibrium Thus for m=m*the black hole temperature equalsθB

Or one may set =− ( 4 − 4)A=0

t d

E d

B

θ θ

(0.2)

(0.2)

(0.1) + (0.4) (For the first and the second terms respectively)

4.5) Considering the solution to 4.3, one verifies that it will go away from the

⇒













−

−

4 2

2

4

1 1

m

m m

G

hc

dt

dm













<

⇒

<

>

⇒

>

0

0

*

*

dt

dm m

m

dt

dm m

m