Mathematical Principles of Theoretical Physics

416 CHAPTER 7. ASTROPHYSICS AND COSMOLOGY

Hereα,ψ,Tsatisfy equations (7.1.79)-(7.1.80) with the boundary conditions (7.1.81)-(7.1.84).
The detailed derivation of (7.2.9)-(7.2.10) will be given hereafter.
Theσ-factor (7.2.10) can be expressed in the following form, to be deduced later:

σ(r) =

c^2 r 03 ( 1 −δ)β

2 κ^2 r^2

eζ(r)

eζ(^1 )

·( 1 −δr^2 −η)·

(

1

r^2

δr^2 +η

1 −δr^2 −η

+rξ

)

(7.2.11)

·

(

A−

1

κ

∫ 1

r

r^2 Q

1 −δr^2 −η

dr

)

for 0≤r≤ 1 ,

where

(7.2.12)

η=

1

2 r

∫r

0

r^2 ψ′φ′

α ψ

dr,

ζ=

∫r

0

(α

r

+rξ

)

dr,

ξ=

8 πG

c^2

αp+φ′′−

α′φ′

2 α

for 0≤r≤ 1 ,

δis called theδ-factor given by

(7.2.13) δ=
2 mG
c^2 r 0

,

andm,r 0 are the mass and radius of the star.

2.Formula for the relativistic effect. The termFGPin (7.2.7) can be expressed in the
following form:

(7.2.14) FGP=









−ν

(

δ+η

′

2 r

)

∂

∂r(rPθ)

−ν(δ+η

′

2 r)

∂

∂r(rPφ)

ν

2

(

( 2 δr+η′)^2

1 −δr^2 −η+^2 δ+η

′′

)

Pr+ν 2 ( 2 δr+η′)∂∂rPr







,

whereη,δare as in (7.2.12) and (7.2.13).
The forceFGPis of special importance in studying supernovae, black holes, and the
galaxy cores. In fact, by the boundary conditions (7.1.81)-(7.1.83), we can reduce that the
radial component of the force (7.2.14) on the stellar shell is as

fr=

(

2 ν δ^2

1 −δ

+δ+φ′′( 1 )

)

Pr+δ ν

∂Pr

∂r

,

which has

(7.2.15) fr∼

2 ν δ^2

1 −δ

Pr→∞ as δ→ 1 (forPr> 0 ).

The property (7.2.15) will lead to a huge supernovae explosions as they collapse to the radii
r 0 → 2 mG/c^2. It is the explosive force (7.2.15) that prevents the formation of black holes;
see Sections7.2.6and7.3.3.