Orion1
Jul19-04, 05:19 PM
Tolman, Oppenheimer, Volkov (1939)
Degenerate Neutron Star Equasion of State:
\inline{ \frac{dP}{dr} = - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
Conditions:
\frac{dm}{dr} = 4 \pi r^2 \rho
\rho = \frac{ \epsilon}{c^2} - ideal fluid
m = m(r) = \frac{ E(r' < r)}{c^2}
P = P(\rho) - strong degenerate matter
\frac{dP}{dr} < 0
Integration:
\int_{r = 0(P = P_c)}^{r = R(P = 0) \rightarrow R}
M = m(R) = \frac{E}{c^2}
\rho = \rho(P) \rightarrow \rho(r)
\rho(0) = \rho_c
Neutron Stars Configurations:
M = M( \rho_c ), R = R( \rho_c ),... - stellar mass, radius
Definite integral dr with respect to r from 0 to R:
\inline{ dP = dr \int_{r = 0(P = P_c)}^{r = R(P = 0) \rightarrow R} - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
Definite integral dr with respect to r from 0 to infinity:
\inline{ dP = dr \int_{r = 0(P = P_c)}^{r = \infty(P = 0)} - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
\inline{ dP = -Gm \left( \frac{P}{c^2p} +1 \right) p \left( \frac{ \left( 32 \pi G^3 m^3 P + c^8 p \right) \log \left( c^2 r - 2Gm \right)}{2c^6Gmp} - \frac{c^2 \log \left( r \right)}{2Gm} + \frac{ 4 \pi c^2 P r^2 + 16 \pi GmPr}{2c^4P} \right)}
Definite integral dP with respect to P from 0 to infinity:
\inline{ dr = dP \int_{P = 0}^{P = \infty} - \frac{r^2}{Gm \rho} \left( 1+ \frac{P}{ \rho c^2} \right)^{-1} \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right)^{-1} \left( 1- \frac{2Gm}{c^2r} \right)}
\inline{ dr = \frac{ \left( 1- \frac{ 2Gm}{ c^2r} \right) r^2 \left( \frac{ c^2p \log \left( 4 \pi P r^3 +c^2 P \right) }{ 4 \pi r^3 -1} - \frac{ c^2 \log \left( P + c^2p \right) p}{ 4 \pi r^3 -1} \right) }{Gmp}}
Does anyone know how to demonstrate and perform the first integration listed above, with given conditions to solve an equasion solution from 0 to R, for the Oppenheimer-Volkov Mass Limit and neutron stars configurations?
The best two papers I could locate are incomplete and missing some keys and also the solutions to the final steps in performing the correct integrations.
Note that the Tolman-Oppenheimer-Volkov equasion (TOV) in this paper may contain a mass placement error in the numerator, instead of denominator, listed in the second set of brackets which does not match the equasions listed in previous papers:
www.jlab.org/HYP2003/talks/Bombaci.pdf
Equasional mass error?
\left(1+ \frac{4 \pi r^3P(r)}{c^2} m(r) \right) ???
According to this paper, The solutions of the TOV equasions depend parametrically on the central density:
\rho_c = \rho (r=0)
Boundary conditions:
m(r=0)=0
P(r=R)=P_{sur}
R - stellar radius
TOV solutions:
P = P(r, \rho_c)
m = m(r, \rho_c)
Note that this paper is still incomplete, and the solutions listed are still only conditional solutions. A complete paper would contain the complete formulated equasion with proofs for the TOV mass limit solution estimate.
Note that the more massive a neutron star is, the smaller its radius. Therefore certain physical density geometries cannot be effectively applied.
Reference:
www.itkp.uni-bonn.de/~metsch/STAR/star_pdf.pdf
www.ganil.fr/snns/tina/talks/talk_haensel.pdf
www.jlab.org/HYP2003/talks/Bombaci.pdf
Degenerate Neutron Star Equasion of State:
\inline{ \frac{dP}{dr} = - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
Conditions:
\frac{dm}{dr} = 4 \pi r^2 \rho
\rho = \frac{ \epsilon}{c^2} - ideal fluid
m = m(r) = \frac{ E(r' < r)}{c^2}
P = P(\rho) - strong degenerate matter
\frac{dP}{dr} < 0
Integration:
\int_{r = 0(P = P_c)}^{r = R(P = 0) \rightarrow R}
M = m(R) = \frac{E}{c^2}
\rho = \rho(P) \rightarrow \rho(r)
\rho(0) = \rho_c
Neutron Stars Configurations:
M = M( \rho_c ), R = R( \rho_c ),... - stellar mass, radius
Definite integral dr with respect to r from 0 to R:
\inline{ dP = dr \int_{r = 0(P = P_c)}^{r = R(P = 0) \rightarrow R} - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
Definite integral dr with respect to r from 0 to infinity:
\inline{ dP = dr \int_{r = 0(P = P_c)}^{r = \infty(P = 0)} - \frac{Gm \rho}{r^2} \left( 1+ \frac{P}{ \rho c^2} \right) \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right) \left( 1- \frac{2Gm}{c^2r} \right)^{-1}}
\inline{ dP = -Gm \left( \frac{P}{c^2p} +1 \right) p \left( \frac{ \left( 32 \pi G^3 m^3 P + c^8 p \right) \log \left( c^2 r - 2Gm \right)}{2c^6Gmp} - \frac{c^2 \log \left( r \right)}{2Gm} + \frac{ 4 \pi c^2 P r^2 + 16 \pi GmPr}{2c^4P} \right)}
Definite integral dP with respect to P from 0 to infinity:
\inline{ dr = dP \int_{P = 0}^{P = \infty} - \frac{r^2}{Gm \rho} \left( 1+ \frac{P}{ \rho c^2} \right)^{-1} \left( 1+ \frac{4 \pi r^3 P}{mc^2} \right)^{-1} \left( 1- \frac{2Gm}{c^2r} \right)}
\inline{ dr = \frac{ \left( 1- \frac{ 2Gm}{ c^2r} \right) r^2 \left( \frac{ c^2p \log \left( 4 \pi P r^3 +c^2 P \right) }{ 4 \pi r^3 -1} - \frac{ c^2 \log \left( P + c^2p \right) p}{ 4 \pi r^3 -1} \right) }{Gmp}}
Does anyone know how to demonstrate and perform the first integration listed above, with given conditions to solve an equasion solution from 0 to R, for the Oppenheimer-Volkov Mass Limit and neutron stars configurations?
The best two papers I could locate are incomplete and missing some keys and also the solutions to the final steps in performing the correct integrations.
Note that the Tolman-Oppenheimer-Volkov equasion (TOV) in this paper may contain a mass placement error in the numerator, instead of denominator, listed in the second set of brackets which does not match the equasions listed in previous papers:
www.jlab.org/HYP2003/talks/Bombaci.pdf
Equasional mass error?
\left(1+ \frac{4 \pi r^3P(r)}{c^2} m(r) \right) ???
According to this paper, The solutions of the TOV equasions depend parametrically on the central density:
\rho_c = \rho (r=0)
Boundary conditions:
m(r=0)=0
P(r=R)=P_{sur}
R - stellar radius
TOV solutions:
P = P(r, \rho_c)
m = m(r, \rho_c)
Note that this paper is still incomplete, and the solutions listed are still only conditional solutions. A complete paper would contain the complete formulated equasion with proofs for the TOV mass limit solution estimate.
Note that the more massive a neutron star is, the smaller its radius. Therefore certain physical density geometries cannot be effectively applied.
Reference:
www.itkp.uni-bonn.de/~metsch/STAR/star_pdf.pdf
www.ganil.fr/snns/tina/talks/talk_haensel.pdf
www.jlab.org/HYP2003/talks/Bombaci.pdf