aboutsummaryrefslogtreecommitdiffstats
path: root/fg21sim/extragalactic/clusters/emission.py
diff options
context:
space:
mode:
authorAaron LI <aaronly.me@outlook.com>2017-01-16 21:10:30 +0800
committerAaron LI <aly@aaronly.me>2017-06-01 16:33:40 +0800
commit93dc96a0a6a336419b2e80b221257a8a7532019a (patch)
tree767c4bfbeb88e9fb44ac463963f2bd735f6d45c8 /fg21sim/extragalactic/clusters/emission.py
parent912e2c8b5a37606828241e259e719bbced50989c (diff)
downloadfg21sim-93dc96a0a6a336419b2e80b221257a8a7532019a.tar.bz2
Add clusters/emission.py: Calculate synchrotron emissivity
Calculate the synchrotron emissivity from the given electron spectrum at specified frequency. Add the electron charge to units.Constants
Diffstat (limited to 'fg21sim/extragalactic/clusters/emission.py')
-rw-r--r--fg21sim/extragalactic/clusters/emission.py117
1 files changed, 117 insertions, 0 deletions
diff --git a/fg21sim/extragalactic/clusters/emission.py b/fg21sim/extragalactic/clusters/emission.py
new file mode 100644
index 0000000..e71632b
--- /dev/null
+++ b/fg21sim/extragalactic/clusters/emission.py
@@ -0,0 +1,117 @@
+# Copyright (c) 2017 Weitian LI <liweitianux@live.com>
+# MIT license
+
+"""
+Calculate the synchrotron emission for simulated radio halos.
+"""
+
+import logging
+
+import numpy as np
+import scipy.integrate
+import scipy.special
+
+from .units import (Units as AU, Constants as AC)
+
+
+logger = logging.getLogger(__name__)
+
+
+class SynchrotronEmission:
+ """
+ Calculate the synchrotron emission from a given population
+ of electrons.
+
+ References
+ ----------
+ [1] Cassano & Brunetti 2005, MNRAS, 357, 1313
+ http://adsabs.harvard.edu/abs/2005MNRAS.357.1313C
+ Appendix.C
+ """
+ def __init__(self, B):
+ # Uniform magnetic field strength
+ self.B = B # [uG]
+
+ @property
+ def frequency_larmor(self):
+ """
+ Electron Larmor frequency:
+ ν_L = e * B / (2*π * m0 * c) = e * B / (2*π * mec)
+
+ Unit: MHz
+ """
+ coef = AC.e / (2*np.pi * AU.mec) # [Hz/G]
+ coef *= 1e-12 # [MHz/uG]
+ nu = coef * self.B # [MHz]
+ return nu
+
+ def frequency_crit(self, p, theta=np.pi/2):
+ """
+ Synchrotron critical frequency.
+
+ Critical frequency:
+ ν_c = (3/2) * γ^2 * sin(θ) * ν_L
+
+ Parameters
+ ----------
+ p : float
+ Electron momentum (unit: mec), i.e., Lorentz factor γ
+ theta : float, optional
+ The angle between the electron velocity and the magnetic field.
+ (unit: radian)
+
+ Returns
+ -------
+ nu : float
+ Critical frequency, unit: MHz
+ """
+ nu_L = self.frequency_larmor
+ nu = (3/2) * p**2 * np.sin(theta) * nu_L
+ return nu
+
+ def F(self, x):
+ """
+ Synchrotron kernel function.
+ """
+ val = x * scipy.integrate.quad(lambda t: scipy.special.kv(5/3, t),
+ a=x, b=np.inf)[0]
+ return val
+
+ def emissivity(self, nu, p, n_e):
+ """
+ Calculate the synchrotron emissivity (power emitted per volume
+ and per frequency) at the specified frequency from the given
+ electron number & energy distribution
+
+ Parameters
+ ----------
+ nu : float
+ Frequency (unit: MHz) where to calculate the emissivity.
+ p : `~numpy.ndarray`
+ The momentum grid adopted when solving the Fokker-Planck equation.
+ Unit: [mec]
+ n_e : `~numpy.ndarray`
+ Electron spectrum by solving the Fokker-Planck equation.
+ Unit: [cm^-3 mec^-1]
+
+ Returns
+ -------
+ j_nu : float
+ Synchrotron emissivity at frequency ``nu``.
+ Unit: [erg/s/cm^3/Hz]
+ """
+ def func(theta, _p, _n_e):
+ nu_c = self.frequency_crit(_p, theta)
+ x = nu / nu_c
+ return (np.sin(theta)**2 * _n_e * self.F(x))
+
+ coef = np.sqrt(3) * AC.e**3 * self.B / AC.c # multiplied a [mec]
+ func_p = np.zeros(p.shape)
+ for i in range(len(p)):
+ # Integrate over ``theta``
+ func_p[i] = scipy.integrate.quad(
+ lambda t: func(t, p[i], n_e[i]),
+ a=0, b=np.pi/2)[0]
+ # Integrate over ``p``
+ j_nu = coef * scipy.integrate.trapz(func_p, p)
+ return j_nu