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author | Aaron LI <aaronly.me@outlook.com> | 2017-05-27 18:11:00 +0800 |
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committer | Aaron LI <aly@aaronly.me> | 2017-06-01 16:33:40 +0800 |
commit | c630afcff2a8529232dee68a3964e52cf8f080b4 (patch) | |
tree | af5163d51c89a03084df6decbf33d7e5847d0a24 /fg21sim/extragalactic/clusters/cosmology.py | |
parent | c7e866bb8474c0b391ebb29826361c75240e5cd3 (diff) | |
download | fg21sim-c630afcff2a8529232dee68a3964e52cf8f080b4.tar.bz2 |
clusters: Move units.py and cosmology.py to utils
Diffstat (limited to 'fg21sim/extragalactic/clusters/cosmology.py')
-rw-r--r-- | fg21sim/extragalactic/clusters/cosmology.py | 215 |
1 files changed, 0 insertions, 215 deletions
diff --git a/fg21sim/extragalactic/clusters/cosmology.py b/fg21sim/extragalactic/clusters/cosmology.py deleted file mode 100644 index 12e581a..0000000 --- a/fg21sim/extragalactic/clusters/cosmology.py +++ /dev/null @@ -1,215 +0,0 @@ -# Copyright (c) 2016-2017 Weitian LI <liweitianux@live.com> -# MIT license - -""" -Flat ΛCDM cosmological model. -""" - -import numpy as np -from scipy import integrate -from astropy.cosmology import FlatLambdaCDM - -from .units import (UnitConversions as AUC, Constants as AC) - - -class Cosmology: - """ - Flat ΛCDM cosmological model. - - Attributes - ---------- - H0 : float - Hubble parameter at present day (z=0) - Om0 : float - Density parameter of (dark and baryon) matter at present day - Ob0 : float - Density parameter of baryon at present day - Ode0 : float - Density parameter of dark energy at present day - sigma8 : float - Present-day rms density fluctuation on a scale of 8 h^-1 Mpc. - - References - ---------- - [1] https://astro.uni-bonn.de/~pavel/WIKIPEDIA/Lambda-CDM_model.html - [2] https://en.wikipedia.org/wiki/Lambda-CDM_model - [3] Randall, Sarazin & Ricker 2002, ApJ, 577, 579 - http://adsabs.harvard.edu/abs/2002ApJ...577..579R - Sec.(2) - """ - def __init__(self, H0=71.0, Om0=0.27, Ob0=0.046, sigma8=0.834): - self.H0 = H0 # [km/s/Mpc] - self.Om0 = Om0 - self.Ob0 = Ob0 - self.Ode0 = 1.0 - Om0 - self.sigma8 = sigma8 - self._cosmo = FlatLambdaCDM(H0=H0, Om0=Om0, Ob0=Ob0) - - @property - def h(self): - """ - Dimensionless/reduced Hubble parameter - """ - return self.H0 / 100.0 - - @property - def M8(self): - """ - Mass contained in a sphere of radius of 8 h^-1 Mpc. - Unit: [Msun] - """ - r = 8 * AUC.Mpc2cm / self.h # [cm] - M8 = (4*np.pi/3) * r**3 * self.rho_crit(0) # [g] - M8 *= AUC.g2Msun # [Msun] - return M8 - - def E(self, z): - """ - Redshift evolution factor. - """ - return np.sqrt(self.Om0 * (1+z)**3 + self.Ode0) - - def H(self, z): - """ - Hubble parameter at redshift z. - """ - return self.H0 * self.E(z) - - @property - def hubble_time(self): - """ - Hubble time. - Unit: [Gyr] - """ - uconv = AUC.Mpc2km * AUC.s2Gyr - t_H = (1.0/self.H0) * uconv # [Gyr] - return t_H - - def age(self, z): - """ - Cosmic time (age) at redshift z. - - Parameters - ---------- - z : float - Redshift - - Returns - ------- - age : float - Age of the universe (cosmic time) at the given redshift. - Unit: [Gyr] - - References - ---------- - [1] Thomas & Kantowski 2000, Physical Review D, 62, 103507 - http://adsabs.harvard.edu/abs/2000PhRvD..62j3507T - Eq.(18) - """ - t_H = self.hubble_time - t = (t_H * (2/3/np.sqrt(1-self.Om0)) * - np.arcsinh(np.sqrt((1/self.Om0 - 1) / (1+z)**3))) - return t - - @property - def age0(self): - """ - Present age of the universe. - """ - return self.age(0) - - def redshift(self, age): - """ - Invert the above ``self.age(z)`` formula analytically, to calculate - the redshift corresponding to the given cosmic time (age). - - Parameters - ---------- - age : float - Age of the universe (cosmic time), unit [Gyr] - - Returns - ------- - z : float - Redshift corresponding to the specified age. - """ - t_H = self.hubble_time - term1 = (1/self.Om0) - 1 - term2 = np.sinh(3*age*np.sqrt(1-self.Om0) / (2*t_H)) ** 2 - z = (term1 / term2) ** (1/3) - 1 - return z - - def rho_crit(self, z): - """ - Critical density at redshift z. - Unit: [g/cm^3] - """ - rho = 3 * self.H(z)**2 / (8*np.pi * AC.G) - rho *= AUC.km2Mpc**2 - return rho - - def Om(self, z): - """ - Density parameter of matter at redshift z. - """ - return self.Om0 * (1+z)**3 / self.E(z)**2 - - def overdensity_virial(self, z): - """ - Calculate the virial overdensity, which generally used to - determine the virial radius of a cluster. - - References - ---------- - [1] Cassano & Brunetti 2005, MNRAS, 357, 1313 - http://adsabs.harvard.edu/abs/2005MNRAS.357.1313C - Eqs.(10,A4) - """ - omega_z = (1 / self.Om(z)) - 1 - Delta_c = 18*np.pi**2 * (1 + 0.4093 * omega_z**0.9052) - return Delta_c - - def overdensity_crit(self, z): - """ - Critical (linear) overdensity for a region to collapse - at a redshift z. - - References - ---------- - [1] Randall, Sarazin & Ricker 2002, ApJ, 577, 579 - http://adsabs.harvard.edu/abs/2002ApJ...577..579R - Appendix.A, Eq.(A1) - """ - coef = 3 * (12*np.pi) ** (2/3) / 20 - D0 = self.growth_factor0 - D_z = self.growth_factor(z) - Om_z = self.Om(z) - delta_c = coef * (D0 / D_z) * (1 + 0.0123*np.log10(Om_z)) - return delta_c - - def growth_factor(self, z): - """ - Growth factor at redshift z. - - References - ---------- - [1] Randall, Sarazin & Ricker 2002, ApJ, 577, 579 - http://adsabs.harvard.edu/abs/2002ApJ...577..579R - Appendix.A, Eq.(A7) - """ - x0 = (2 * self.Ode0 / self.Om0) ** (1/3) - x = x0 / (1 + z) - coef = np.sqrt(x**3 + 2) / (x**1.5) - integral = integrate.quad(lambda y: y**1.5 * (y**3+2)**(-1.5), - a=0, b=x, epsabs=1e-5, epsrel=1e-5)[0] - D = coef * integral - return D - - @property - def growth_factor0(self): - """ - Present-day (z=0) growth factor. - """ - if not hasattr(self, "_growth_factor0"): - self._growth_factor0 = self.growth_factor(0) - return self._growth_factor0 |