Summary of Scalings[edit]

On an accompanying Wiki page we have explained how to interpret the set of dimensionless units that Dominic Marcello is using in his rad-hydrocode. The following tables summarize some of the mathematical relationships that have been derived in that accompanying discussion.

General Relation

Case A:

$\frac{m_{c g s}}{m_{c o d e}}$	$=$	$0.40375 μ_{e}^{2} M_{C h} (\frac{{\tilde{g}}^{3} \tilde{a}}{{\tilde{r}}^{4} {\bar{μ}}^{4}})^{1 / 2}$	$= 2.8094 \times 1 0^{33} g$
$\frac{ℓ_{c g s}}{ℓ_{c o d e}}$	$=$	$4.4379 \times 1 0^{- 4} μ_{e} ℓ_{C h} (\frac{{\tilde{c}}^{4} \tilde{g} \tilde{a}}{{\bar{μ}}^{4} {\tilde{r}}^{4}})^{1 / 2}$	$= 8.179 \times 1 0^{9} c m$
$\frac{t_{c g s}}{t_{c o d e}}$	$=$	$2.9216 \times 1 0^{- 6} μ_{e}^{1 / 2} t_{C h} (\frac{{\tilde{c}}^{6} \tilde{g} \tilde{a}}{{\bar{μ}}^{4} {\tilde{r}}^{4}})^{1 / 2}$	$= 54.02 s$
$\frac{T_{c g s}}{T_{c o d e}}$	$=$	$1.08095 \times 1 0^{13} (\frac{\tilde{r} \bar{μ}}{{\tilde{c}}^{2}})$	$= 1.618 \times 1 0^{8} K$

where:

$μ_{e}^{2} M_{C h} = 1.14169 \times 1 0^{34} g$ ; $μ_{e} ℓ_{C h} = 7.71311 \times 1 0^{8} c m$ ; $μ_{e}^{1 / 2} t_{C h} = 3.90812 s$

Case A $\Rightarrow \tilde{g} = 1$ ; $\tilde{c} = 198$ ; $\tilde{r} = 0.44$ ; $\tilde{a} = 0.044$ ; $\bar{μ} = 4 / 3$ ; $ρ_{m a x} = 1$ ; $(Δ R) = \frac{π}{128}$

Now let's convert all of the system parameters listed on the accompanying page that details the properties of various polytropic binary systems.

Properties of ( $n = 3 / 2$ ) Polytropic Binary Systems

Q07¹

Binary System

Accretor

Donor

$q$

$M_{t o t}$

$a$

$P = \frac{2 π}{Ω}$

$J_{t o t}$

$M_{a}$

$ρ_{a}^{m a x}$

$K_{3 / 2}^{a}$

$R_{a}$

$M_{d}$

$ρ_{d}^{m a x}$

$K_{3 / 2}^{d}$

$R_{d}$

$f_{R L}$

SCF units

0.70000

0.02371

0.83938

31.19

$8.938 \times 1 0^{- 4}$

0.013945

1.0000

0.02732

0.2728

0.009761

0.6077

0.02512

0.2888

0.998

conversion²

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{3}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{5}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{3}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{2}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{3}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})^{2}$

$(\frac{ℓ_{c o d e}}{ℓ_{S C F}})$

Rad-Hydro units

0.70000

0.6847

2.5752

31.19

0.24293

0.4027

1.0000

0.2571

0.8369

0.28187

0.6077

0.2364

0.88603

0.998

cgs units

0.70000

$1.924 \times 1 0^{33}$

$2.106 \times 1 0^{10}$

$1.687 \times 1 0^{3}$

$1.924 \times 1 0^{33}$

$1.132 \times 1 0^{33}$

$5.136 \times 1 0^{3}$

$6.845 \times 1 0^{9}$

$7.921 \times 1 0^{32}$

$3.121 \times 1 0^{3}$

$7.247 \times 1 0^{9}$

0.996

Other units

$0.967 M_{⊙}$

$0.303 R_{⊙}$

$28.1 m i n$

$0.569 M_{⊙}$

$0.0984 R_{⊙}$

$0.398 M_{⊙}$

$0.1042 R_{⊙}$

¹Model Q07 ( $q = 0.700$ ): Drawn from the first page of the accompanying PDF document. NOTE: In this PDF document, Roche-lobe volumes appear to be too large by factor of 2.
²For this model, $(ℓ_{c o d e} / ℓ_{S C F}) = π (128 - 3) / 128 = 3.068$ ; see more detailed, accompanying discussion.

Here are some additional useful relations:

General Relation

Case A:

$f_{E d d} \equiv \frac{L_{a c c}}{L_{E d d}}$	$=$	$1.25 \times 1 0^{21} (\frac{{\tilde{g}}^{1 / 2} {\tilde{r}}^{2} {\bar{μ}}^{2}}{{\tilde{c}}^{5} {\tilde{a}}^{1 / 2}}) [\frac{\dot{M}}{R_{a}}]_{c o d e}$	$= 6.74 \times 1 0^{9} [\frac{\dot{M}}{R_{a}}]_{c o d e}$
$\frac{ρ_{t h r e s h o l d}}{ρ_{m a x}} \equiv \frac{1}{ρ_{m a x} κ_{T} (Δ R)}$	$=$	$5.164 \times 1 0^{- 21} (\frac{{\tilde{c}}^{4} {\tilde{a}}^{1 / 2}}{{\bar{μ}}^{2} {\tilde{r}}^{2} {\tilde{g}}^{1 / 2}}) [\frac{1}{ρ_{m a x} (Δ R)}]_{c o d e}$	$= 4.83 \times 1 0^{- 12}$
$Γ \equiv \frac{P_{g a s}}{P_{r a d}}$	$=$	$(\frac{3 \tilde{r}}{\tilde{a}}) [\frac{ρ}{T^{3}}]_{c o d e}$	$= 30 [\frac{ρ}{T^{3}}]_{c o d e}$
$\frac{v_{c i r c}}{c} \equiv \frac{2 π a_{s e p a r a t i o n}}{c P_{o r b i t}}$	$=$	$\frac{2 π}{\tilde{c}} [\frac{a_{s e p}}{P_{o r b}}]_{c o d e}$	$= 0.032 [\frac{a_{s e p}}{P_{o r b}}]_{c o d e}$

Case A $\Rightarrow \tilde{g} = 1$ ; $\tilde{c} = 198$ ; $\tilde{r} = 0.44$ ; $\tilde{a} = 0.044$ ; $\bar{μ} = 4 / 3$ ; $ρ_{m a x} = 1$ ; $(Δ R) = \frac{π}{128}$

Combining the above Case A relations with the RadHydro-code properties of the Q0.7 polytropic binary that serves as an initial condition for Dominic's simulations, we conclude the following:

(1) The system will experience "super-Eddington" accretion (i.e., $f_{E d d} > 1$ ) when

$[\dot{M}]_{c o d e} > 1.3 \times 1 0^{- 10} .$

(2) The mean-free-path, $ℓ_{m f p}$ , of a photon will be less than one grid cell $(Δ R)_{c o d e}$ when

$[ρ]_{c o d e} > ρ_{t h r e s h o l d} = 5 \times 1 0^{- 12} .$

(3) The system is weakly relativistic because,

$\frac{v_{c i r c}}{c} = 0.0026 .$

Appendix/Ramblings/Radiation/SummaryScalings

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Summary of Scalings[edit]

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