Chandrasekhar's white dwarf equation

In astrophysics, Chandrasekhar's white dwarf equation is an initial value ordinary differential equation introduced by the Indian American astrophysicist Subrahmanyan Chandrasekhar,^[1] in his study of the gravitational potential of completely degenerate white dwarf stars. The equation reads as^[2] $${\displaystyle \frac{1}{{\eta }^2}\frac{d}{d\eta }\left({\eta }^2\frac{d\phi }{d\eta }\right)+({\phi }^2-C{)}^{3/2}=0}$$ with initial conditions $${\displaystyle \phi (0)=1,{\phi }^{\prime }(0)=0}$$ where ${\displaystyle \phi }$ measures the density of white dwarf, ${\displaystyle \eta }$ is the non-dimensional radial distance from the center and ${\displaystyle C}$ is a constant which is related to the density of the white dwarf at the center. The boundary ${\displaystyle \eta ={\eta }_{\mathrm{\infty }}}$ of the equation is defined by the condition $${\displaystyle \phi ({\eta }_{\mathrm{\infty }})=\sqrt{C}.}$$ such that the range of ${\displaystyle \phi }$ becomes ${\displaystyle \sqrt{C}\le \phi \le 1}$. This condition is equivalent to saying that the density vanishes at ${\displaystyle \eta ={\eta }_{\mathrm{\infty }}}$.

Derivation

From the quantum statistics of a completely degenerate electron gas (all the lowest quantum states are occupied), the pressure and the density of a white dwarf are calculated in terms of the maximum electron momentum ${\displaystyle p_0}$standardized as ${\displaystyle x=p_0/mc}$, with pressure ${\displaystyle P=Af(x)}$ and density ${\displaystyle \rho =B{x}^3}$, where $${\displaystyle \begin{array}{rl}& A=\frac{\pi m_e^4{c}^5}{3h^3}=6.02\times 10^{21}\text{ Pa},\\ & B=\frac{8\pi }{3}{m}_p{\mu }_e{\left(\frac{m_{e}c}{h}\right)}^3=9.82\times 10^8{\mu }_e{\text{ kg/m}}^3,\\ & f(x)=x(2x^2-3)(x^2+1{)}^{1/2}+3{\sinh }^{-1}x,\end{array}}$$ ${\displaystyle {\mu }_e}$ is the mean molecular weight of the gas, and ${\displaystyle h}$ is the height of a small cube of gas with only two possible states. When this is substituted into the hydrostatic equilibrium equation $${\displaystyle \frac{1}{r^2}\frac{d}{dr}\left(\frac{r^2}{\rho }\frac{dP}{dr}\right)=-4\pi G\rho }$$ where ${\displaystyle G}$ is the gravitational constant and ${\displaystyle r}$ is the radial distance, we get $${\displaystyle \frac{1}{r^2}\frac{d}{dr}\left(r^2\frac{d\sqrt{x^2+1}}{dr}\right)=-\frac{\pi G{B}^2}{2A}{x}^3}$$ and letting ${\displaystyle y^2=x^2+1}$, we have $${\displaystyle \frac{1}{r^2}\frac{d}{dr}\left(r^2\frac{dy}{dr}\right)=-\frac{\pi G{B}^2}{2A}(y^2-1{)}^{3/2}}$$ If we denote the density at the origin as ${\displaystyle {\rho }_o=B{x}_o^3=B(y_o^2-1{)}^{3/2}}$, then a non-dimensional scale $${\displaystyle r={\left(\frac{2A}{\pi G{B}^2}\right)}^{1/2}\frac{\eta }{y_o},y=y_o\phi }$$ gives $${\displaystyle \frac{1}{{\eta }^2}\frac{d}{d\eta }\left({\eta }^2\frac{d\phi }{d\eta }\right)+({\phi }^2-C{)}^{3/2}=0}$$ where ${\displaystyle C=1/y_o^2}$. In other words, once the above equation is solved the density is given by $${\displaystyle \rho =B{y}_o^3{({\phi }^2-\frac{1}{y_o^2})}^{3/2}.}$$ The mass interior to a specified point can then be calculated $${\displaystyle M(\eta )=-\frac{4\pi }{B^2}{\left(\frac{2A}{\pi G}\right)}^{3/2}{\eta }^2\frac{d\phi }{d\eta }.}$$ The radius-mass relation of the white dwarf is usually plotted in the plane ${\displaystyle {\eta }_{\mathrm{\infty }}}$-${\displaystyle M({\eta }_{\mathrm{\infty }})}$.

Solution near the origin

In the neighborhood of the origin, ${\displaystyle \eta \ll 1}$, Chandrasekhar provided an asymptotic expansion as $${\displaystyle \begin{array}{rl}\phi =& 1-\frac{q^3}{6}{\eta }^2+\frac{q^4}{40}{\eta }^4-\frac{q^5(5q^2+14)}{7!}{\eta }^6\\ & +\frac{q^6(339q^2+280)}{3\times 9!}{\eta }^8-\frac{q^7(1425q^4+11346q^2+4256)}{5\times 11!}{\eta }^{10}+\cdots \end{array}}$$ where ${\displaystyle q^2=C-1}$. He also provided numerical solutions for the range ${\displaystyle C=0.01-0.8}$.

Equation for small central densities

When the central density ${\displaystyle {\rho }_o=B{x}_o^3=B(y_o^2-1{)}^{3/2}}$ is small, the equation can be reduced to a Lane–Emden equation by introducing $${\displaystyle \xi =\sqrt{2}\eta ,\theta ={\phi }^2-C={\phi }^2-1+x_o^2+O(x_o^4)}$$ to obtain at leading order, the following equation $${\displaystyle \frac{1}{{\xi }^2}\frac{d}{d\xi }\left({\xi }^2\frac{d\theta }{d\xi }\right)=-{\theta }^{3/2}}$$ subjected to the conditions ${\displaystyle \theta (0)=x_o^2}$ and ${\displaystyle {\theta }^{\prime }(0)=0}$. Note that although the equation reduces to the Lane–Emden equation with polytropic index ${\displaystyle 3/2}$, the initial condition is not that of the Lane–Emden equation.

Limiting mass for large central densities

When the central density becomes large, i.e., ${\displaystyle y_o\to \mathrm{\infty }}$ or equivalently ${\displaystyle C\to 0}$, the governing equation reduces to $${\displaystyle \frac{1}{{\eta }^2}\frac{d}{d\eta }\left({\eta }^2\frac{d\phi }{d\eta }\right)=-{\phi }^3}$$ subjected to the conditions ${\displaystyle \phi (0)=1}$ and ${\displaystyle {\phi }^{\prime }(0)=0}$. This is exactly the Lane–Emden equation with polytropic index ${\displaystyle 3}$. Note that in this limit of large densities, the radius $${\displaystyle r={\left(\frac{2A}{\pi G{B}^2}\right)}^{1/2}\frac{\eta }{y_o}}$$ tends to zero. The mass of the white dwarf however tends to a finite limit $${\displaystyle M\to -\frac{4\pi }{B^2}{\left(\frac{2A}{\pi G}\right)}^{3/2}{\left({\eta }^2\frac{d\phi }{d\eta }\right)}_{\eta ={\eta }_{\mathrm{\infty }}}=5.75{\mu }_e^{-2}{M}_{\odot }.}$$ The Chandrasekhar limit follows from this limit.

See also

• Emden–Chandrasekhar equation
• Tolman–Oppenheimer–Volkoff equation

References