planets.py

############################################################
# Planetary Database                                       #
# Modified by Paul Hayne from the "planets.py" library by  #
# Raymond T. Pierrehumbert                                 #
#                                                          #
# Last modified: June, 2017                                #
#                                                          #
# Sources:                                                 #
#     1. http://nssdc.gsfc.nasa.gov/planetary/factsheet/   #
#     2. Lang, K. (2012). Astrophysical data: planets and  #
#        stars. Springer Science & Business Media.         #
#                                                          #
############################################################

# All units M.K.S. unless otherwise stated

# Constants
AU = 149.60e9 # Astronomical Unit [m]
sigma = 5.67e-8 # Stefan-Boltzmann constant [W.m-2.K-4]
G = 6.67428e-11 # Gravitational constant

# Dependencies
import numpy as np

class Planet:
    '''
    A Planet object contains basic planetary data.
    If P is a Planet object, the data are:
           P.name = Name of the planet
           P.R = Mean radius of planet [m]
           P.g = Surface gravitational acceleration [m.s-2]
           P.S = Annual mean solar constant (current) [W.m-2]
           P.psurf = Average atmospheric pressure at the surface [Pa]
           P.albedo = Bond albedo [fraction]
           P.emissivity = IR emissivity [fraction]
           P.Qb = Crustal/basal heat flow (average) [W.m-2]
           P.gamma = Surface layer thermal inertia [J.m-2.K-1.s-1/2]
           
           P.rsm = Semi-major axis of orbit about Sun [m]
           P.rAU = Semi-major axis of orbit about Sun [AU]
           P.year = Sidereal length of year [s]
           P.eccentricity =  Orbital eccentricity [unitless]
           P.day = Mean length of solar day [s]
           P.obliquity = Obliquity to orbit [radian]
           P.Lequinox = Longitude of equinox [radian]
           P.Lp = Longitude of perihelion [radian]

           P.Tsavg = Mean surface temperature [K]
           P.Tsmax = Maximum surface temperature [K]

    For gas giants, "surface" quantities are given at the 1 bar level
    '''

    #__repr__ object prints out a help string when help is
    #invoked on the planet object or the planet name is typed
    def __repr__(self):
        line1 =\
        'This planet object contains information on %s\n'%self.name
        line2 = 'Type \"help(Planet)\" for more information\n'
        return line1+line2
    def __init__(self):
        self.name = None #Name of the planet
        self.R = None #Mean radius of planet
        self.g = None #Surface gravitational acceleration
        self.S = None #Annual mean solar constant (current)
        self.psurf = None # Surface pressure [Pa]
        self.albedo = None #Bond albedo
        self.albedoCoef = [0.0, 0.0] # Coefficients in variable albedo model
        self.emissivity = None #IR emissivity [fraction]
        self.Qb = None #Crustal heat flow (average) [W.m-2]
        self.Gamma = None #Thermal inertia [J.m-2.K-1.s-1/2]
        self.ks = None # Solid (phonon) conductivity at surface [W.m-1.K-1]
        self.kd = None # Solid (phonon) conductivity at depth z>>H [W.m.K-1]
        self.rhos = None # Density at surface [kg.m-3]
        self.rhod = None # Density at depth z>>H [kg.m-3]
        self.H = None # e-folding scale of conductivity and density [m]
        self.cp0 = None # heat capacity at average surface temp. [J.kg.K-1]
        self.cpCoeff = None# Heat capacity polynomial coefficients
        self.rsm = None #Semi-major axis
        self.rAU = None #Semi-major axis [AU]
        self.year = None #Sidereal length of year
        self.eccentricity = None # Eccentricity
        self.day = None #Mean length of solar day
        self.obliquity = None #Obliquity to orbit
        self.Lequinox = None #Longitude of equinox
        self.Lp = None #Longitude of perihelion

        self.Tsavg = None #Mean surface temperature
        self.Tsmax = None #Maximum surface temperature
    def Teq(self, latitude=0):
        F = self.S
        A = self.albedo
        e = self.emissivity
        return ( (1-A)*F*np.cos(latitude*np.pi/180)/(4*e*sigma) )**0.25

#----------------------------------------------------       
Mercury = Planet()        
Mercury.name = 'Mercury' #Name of the planet
Mercury.R = 2.4397e6 #Mean radius of planet
Mercury.g = 3.70 #Surface gravitational acceleration
Mercury.albedo = .119 #Bond albedo
Mercury.emissivity = 0.95 # Infrared emissivity
Mercury.S = 9126.6 #Annual mean solar constant (current)
Mercury.psurf = 1e-9 # Surface pressure [Pa]
#
Mercury.rsm = 57.91e9 #Semi-major axis
Mercury.rAU = Mercury.rsm/AU #Semi-major axis [AU]
Mercury.year = 87.969*24.*3600. #Sidereal length of year [s]
Mercury.eccentricity = .2056 # Eccentricity
Mercury.day = 4222.6*3600. #Mean length of solar day [s]
Mercury.obliquity = .01 #Obliquity to orbit [deg]
Mercury.Lequinox = None #Longitude of equinox [deg]
#
Mercury.Tsavg = 440. #Mean surface temperature
Mercury.Tsmax = 725. #Maximum surface temperature

#----------------------------------------------------        
Venus = Planet()
Venus.name = 'Venus' #Name of the planet
Venus.R = 6.0518e6 #Mean radius of planet
Venus.g = 8.87 #Surface gravitational acceleration
Venus.albedo = .750 #Bond albedo
Venus.emissivity = 0.95 # Infrared emissivity
Venus.S = 2613.9 #Annual mean solar constant (current)
Venus.psurf = 9.3e4 # Surface pressure [Pa]
#
Venus.rsm = 108.21e9 #Semi-major axis
Venus.rAU = Venus.rsm/AU #Semi-major axis [AU]
Venus.year = 224.701*24.*3600. #Sidereal length of year [s]
Venus.eccentricity = .0067 # Eccentricity
Venus.day = 2802.*3600. #Mean length of solar day [s]
Venus.obliquity = 177.36 #Obliquity to orbit [deg]
Venus.Lequinox = None #Longitude of equinox [deg]
#
Venus.Tsavg = 737. #Mean surface temperature [K]
Venus.Tsmax = 737. #Maximum surface temperature [K]

#----------------------------------------------------        
Earth = Planet()
Earth.name = 'Earth' #Name of the planet
Earth.R = 6.371e6 #Mean radius of planet
Earth.g = 9.798 #Surface gravitational acceleration
Earth.S = 1361 #Annual mean solar constant (current)
Earth.albedo = .306 #Bond albedo
Earth.emissivity = 0.95 # Infrared emissivity
Earth.psurf = 1.013e5 # Surface pressure [Pa]
#
Earth.rsm = 149.60e9 #Semi-major axis
Earth.rAU = Earth.rsm/AU #Semi-major axis [AU]
Earth.year = 365.256*24.*3600. #Sidereal length of year [s]
Earth.eccentricity = .0167 # Eccentricity
Earth.day = 24.000*3600. #Mean length of solar day [s]
Earth.obliquity = 23.45 #Obliquity to orbit [deg]
Earth.Lequinox = None #Longitude of equinox [deg]
#
Earth.Tsavg = 288. #Mean surface temperature [K]
Earth.Tsmax = 320. #Maximum surface temperature [K]

#----------------------------------------------------        
Mars = Planet()
Mars.name = 'Mars' #Name of the planet
Mars.R = 3.390e6 #Mean radius of planet
Mars.g = 3.71 #Surface gravitational acceleration
Mars.albedo = .250 #Bond albedo
Mars.emissivity = 0.95 # Infrared emissivity
Mars.S = 589.2 #Annual mean solar constant (current)
Mars.psurf = 632 # Average surface pressure [Pa]
#
Mars.rsm = 227.92e9 #Semi-major axis
Mars.rAU = Mars.rsm/AU #Semi-major axis [AU]
Mars.year = 686.98*24.*3600. #Sidereal length of year [s]
Mars.eccentricity = .0935 # Eccentricity
Mars.day = 24.6597*3600. #Mean length of solar day [s]
Mars.obliquity = 25.19 #Obliquity to orbit [deg]
Mars.Lequinox = None #Longitude of equinox [deg]
#
Mars.Tsavg = 210. #Mean surface temperature [K]
Mars.Tsmax = 295. #Maximum surface temperature [K]

#----------------------------------------------------        
Jupiter = Planet()
Jupiter.name = 'Jupiter' #Name of the planet
Jupiter.R = 69.911e6 #Mean radius of planet
Jupiter.g = 24.79 #Surface gravitational acceleration
Jupiter.albedo = .343 #Bond albedo
Jupiter.S = 50.5 #Annual mean solar constant (current)
#
Jupiter.rsm = 778.57e9 #Semi-major axis
Jupiter.rAU = Jupiter.rsm/AU #Semi-major axis [AU]
Jupiter.year = 4332.*24.*3600. #Sidereal length of year [s]
#Jupiter.eccentricity = .0489 # Eccentricity
Jupiter.eccentricity = 0. # Eccentricity
Jupiter.day = 9.9259*3600. #Mean length of solar day [s]
Jupiter.obliquity = 0.0546288 #Obliquity to orbit [radians]
Jupiter.Lequinox = None #Longitude of equinox [radians]
#
Jupiter.Tsavg = 165. #Mean surface temperature [K]
Jupiter.Tsmax = None #Maximum surface temperature [K]

#----------------------------------------------------        
Saturn = Planet()
Saturn.name = 'Saturn' #Name of the planet
Saturn.R = 58.232e6 #Mean radius of planet
Saturn.g = 10.44 #Surface gravitational acceleration
Saturn.albedo = .342 #Bond albedo
Saturn.S = 14.90 #Annual mean solar constant (current)
#
Saturn.rsm = 1433.e9 #Semi-major axis
Saturn.rAU = Saturn.rsm/AU #Semi-major axis [AU]
Saturn.year = 10759.*24.*3600. #Sidereal length of year [s]
Saturn.eccentricity = .0565 # Eccentricity
Saturn.day = 10.656*3600. #Mean length of solar day [s]
Saturn.obliquity = 26.73 #Obliquity to orbit [deg]
Saturn.Lequinox = None #Longitude of equinox [deg]
#
Saturn.Tsavg = 134. #Mean surface temperature [K]
Saturn.Tsmax = None #Maximum surface temperature [K]

#----------------------------------------------------        
Uranus = Planet()
Uranus.name = 'Uranus' #Name of the planet
Uranus.R = 25.362e6 #Mean radius of planet
Uranus.g = 8.87 #Surface gravitational acceleration
Uranus.albedo = .300 #Bond albedo
Uranus.S = 3.71 #Annual mean solar constant (current)
#
Uranus.rsm = 2872.46e9 #Semi-major axis
Uranus.rAU = Uranus.rsm/AU #Semi-major axis [AU]
Uranus.year = 30685.4*24.*3600. #Sidereal length of year [s]
Uranus.eccentricity = .0457 # Eccentricity
Uranus.day = 17.24*3600. #Mean length of solar day [s]
Uranus.obliquity = 97.77 #Obliquity to orbit [deg]
Uranus.Lequinox = None #Longitude of equinox [deg]
#
Uranus.Tsavg = 76. #Mean surface temperature [K]
Uranus.Tsmax = None #Maximum surface temperature [K]


#----------------------------------------------------        
Neptune = Planet()
Neptune.name = 'Neptune' #Name of the planet
Neptune.R = 26.624e6 #Mean radius of planet
Neptune.g = 11.15 #Surface gravitational acceleration
Neptune.albedo = .290 #Bond albedo
Neptune.S = 1.51 #Annual mean solar constant (current)
#
Neptune.rsm = 4495.06e9 #Semi-major axis
Neptune.rAU = Neptune.rsm/AU #Semi-major axis [AU]
Neptune.year = 60189.0*24.*3600. #Sidereal length of year [s]
Neptune.eccentricity = .0113 # Eccentricity
Neptune.day = 16.11*3600. #Mean length of solar day [s]
Neptune.obliquity = 28.32 #Obliquity to orbit [deg]
Neptune.Lequinox = None #Longitude of equinox [deg]
#
Neptune.Tsavg = 72. #Mean surface temperature [K]
Neptune.Tsmax = None #Maximum surface temperature [K]

#----------------------------------------------------        
Pluto = Planet()
Pluto.name = 'Pluto' #Name of the planet
Pluto.R = 1.195e6 #Mean radius of planet
Pluto.g = .58 #Surface gravitational acceleration
Pluto.albedo = .5 #Bond albedo
Pluto.emissivity = 0.95 # Infrared emissivity
Pluto.S = .89 #Annual mean solar constant (current)
Pluto.psurf = 1.0 # Average surface pressure [Pa]
#
Pluto.rsm = 5906.e9 #Semi-major axis
Pluto.rAU = Pluto.rsm/AU #Semi-major axis [AU]
Pluto.year = 90465.*24.*3600. #Sidereal length of year [s]
Pluto.eccentricity = .2488 # Eccentricity
Pluto.day = 153.2820*3600. #Mean length of solar day [s]
Pluto.obliquity = 122.53 #Obliquity to orbit [deg]
Pluto.Lequinox = None #Longitude of equinox [deg]
#
Pluto.Tsavg = 50. #Mean surface temperature [K]
Pluto.Tsmax = None #Maximum surface temperature [K]


#Selected moons

#----------------------------------------------------        
Moon = Planet()
Moon.name = 'Moon' #Name of the planet
Moon.R = 1.7374e6 #Mean radius of planet [m]
Moon.g = 1.62 #Surface gravitational acceleration [m.s-2]
Moon.S = 1361. #Annual mean solar constant [W.m-2]
Moon.psurf = 3.0e-10 # Surface pressure [Pa]

Moon.albedo = .12 #Bond albedo
Moon.albedoCoef = [0.06, 0.25] # Coefficients in variable albedo model
Moon.emissivity = .95 #IR emissivity
Moon.Qb = 0.018 #Heat flow [W.m-2]
# Thermophysical properties:
Moon.Gamma = 55. #Thermal inertia [J.m-2.K-1.s-1/2]
Moon.ks = 7.4e-4 # Solid (phonon) conductivity at surface [W.m-1.K-1]
Moon.kd = 3.4e-3 # Solid (phonon) conductivity at depth z>>H [W.m.K-1]
Moon.rhos = 1100. # Density at surface [kg.m-3]
Moon.rhod = 1800. # Density at depth z>>H [kg.m-3]
Moon.H = 0.07 # e-folding scale of conductivity and density [m]
Moon.cp0 = 600. # heat capacity at average surface temp. [J.kg.K-1]
Moon.cpCoeff = [8.9093e-9,-1.234e-5,\
                2.3616e-3,2.7431,-3.6125] # Heat capacity polynomial coefficients
#
Moon.rsm = Earth.rsm #Semi-major axis
Moon.rAU = Moon.rsm/AU #Semi-major axis [AU]
Moon.year = Earth.year #Sidereal length of year
Moon.eccentricity = Earth.eccentricity # Eccentricity
Moon.day = 29.53059*24.*3600. #Mean length of SYNODIC day [s]
Moon.obliquity = 0.026878 #Obliquity to orbit [radian]
Moon.Lequinox = None #Longitude of equinox [radian]
Moon.Lp = 0. # Longitude of perihelion [radian]
#
Moon.Tsavg = 250. #Mean surface temperature [K]
Moon.Tsmax = 400. #Maximum surface temperature [K]
Moon.Tsmin = 95. #Minimum surface temperature [K]

Titan = Planet()
Titan.name = 'Titan' #Name of the planet
Titan.R = 2.575e6 #Mean radius of planet
Titan.g = 1.35 #Surface gravitational acceleration
Titan.S = Saturn.S #Annual mean solar constant (current)
Titan.albedo = .22 #Bond albedo (Not yet updated from Cassini)
Titan.emissivity = 0.95 # Infrared emissivity
Titan.psurf = 1.5e5 # Average surface pressure [Pa]
#        
Titan.rsm = Saturn.rsm #Semi-major axis [m]
Titan.rAU = Titan.rsm/AU #Semi-major axis [AU]
Titan.year = Saturn.year #Sidereal length of year [s]
Titan.eccentricity = Saturn.eccentricity # Eccentricity ABOUT SUN
Titan.day = 15.9452*24.*3600. #Mean length of solar day [s]
Titan.obliquity = Saturn.obliquity #Obliquity to plane of Ecliptic
                                   #(Titan's rotation axis approx parallel
                                   # to Saturn's
Titan.Lequinox = Saturn.Lequinox #Longitude of equinox
#
Titan.Tsavg = 92. #Mean surface temperature [K]
Titan.Tsmax = 94. #Maximum surface temperature [K]

Europa = Planet()
Europa.name = 'Europa' #Name of the planet
Europa.R = 1.560e6 #Mean radius of planet
Europa.g = 1.31 #Surface gravitational acceleration
Europa.psurf = 1.0e-7 # Average surface pressure [Pa]

Europa.S = Jupiter.S #Annual mean solar constant (current)
Europa.albedo = 0.6 #Bond albedo

Europa.emissivity = 0.90 #IR emissivity
Europa.Qb = 0.030 #basal heat flow [W.m-2]
#Thermophysical properties:
Europa.ks = 2e-3 # Solid (phonon) conductivity at surface [W.m-1.K-1]
Europa.kd = 1e-2 # Solid (phonon) conductivity at depth z>>H [W.m.K-1]
Europa.rhos = 100. # Density at surface [kg.m-3]
Europa.rhod = 450. # Density at depth z>>H [kg.m-3]
Europa.H = 0.07 # e-folding scale of conductivity and density [m]
Europa.cp0 = 900 # heat capacity at average surface temp. [J.kg.K-1]
Europa.cpCoeff = [90.0,7.49] # Heat capacity polynomial coefficients
#        
Europa.rsm = Jupiter.rsm #Semi-major axis [m]
Europa.rAU = Europa.rsm/AU #Semi-major axis [AU]
Europa.year = Jupiter.year #Sidereal length of year [s]
Europa.eccentricity = Jupiter.eccentricity # Eccentricity
Europa.day = 3.06822e5 #Mean length of solar day [s]
Europa.obliquity = Jupiter.obliquity #Obliquity to plane of ecliptic
Europa.Lequinox = None #Longitude of equinox
Europa.Lp = 0. #Longitude of perihelion [radians]
#
Europa.Tsavg = 103. #Mean surface temperature [K]
Europa.Tsmax = 130. #Maximum surface temperature [K]

############
# Ganymede
############

Ganymede = Planet()
Ganymede.name = 'Ganymede' #Name of the planet
Ganymede.R = 2.631e6 #Mean radius of planet [m]
Ganymede.g = 1.43 #Surface gravitational acceleration
Ganymede.psurf = 1.0e-6 # Surface pressure [Pa]

Ganymede.S = Jupiter.S #Annual mean solar constant (current)
Ganymede.albedo = 0.4 #Bond albedo
Ganymede.emissivity = 0.90 #IR emissivity
Ganymede.Qb = 0.030 #basal heat flow [W.m-2]
#Thermophysical properties:
Ganymede.ks = 2e-3 # Solid (phonon) conductivity at surface [W.m-1.K-1]
Ganymede.kd = 1e-2 # Solid (phonon) conductivity at depth z>>H [W.m.K-1]
Ganymede.rhos = 100. # Density at surface [kg.m-3]
Ganymede.rhod = 450. # Density at depth z>>H [kg.m-3]
Ganymede.H = 0.07 # e-folding scale of conductivity and density [m]
Ganymede.cp0 = 900 # heat capacity at average surface temp. [J.kg.K-1]
Ganymede.cpCoeff = [90.0,7.49] # Heat capacity polynomial coefficients
#        
Ganymede.rsm = Jupiter.rsm #Semi-major axis [m]
Ganymede.rAU = Ganymede.rsm/AU #Semi-major axis [AU]
Ganymede.year = Jupiter.year #Sidereal length of year [s]
Ganymede.eccentricity = Jupiter.eccentricity # Eccentricity
Ganymede.day = 6.18192e5 #Mean length of solar day [s]
Ganymede.obliquity = Jupiter.obliquity #Obliquity to plane of ecliptic
Ganymede.Lequinox = None #Longitude of equinox
Ganymede.Lp = 0. #Longitude of perihelion [radians]
#
Ganymede.Tsavg = 110. #Mean surface temperature [K]
Ganymede.Tsmax = 140. #Maximum surface temperature [K]


Triton = Planet()
Triton.name = 'Triton' #Name of the planet
Triton.R = 2.7068e6/2. #Mean radius of planet
Triton.g = .78 #Surface gravitational acceleration
Triton.psurf = 2e-5 # Average surface pressure [Pa]

Triton.S = Neptune.S #Annual mean solar constant (current)
Triton.albedo = .76 #Bond albedo
Triton.emissivity = 0.95 # Infrared emissivity
#        
Triton.rsm = Neptune.rsm #Semi-major axis [m]
Triton.rAU = Triton.rsm/AU #Semi-major axis [AU]
Triton.year = Neptune.year #Sidereal length of year
Triton.eccentricity = Neptune.eccentricity # Eccentricity about Sun
Triton.day = 5.877*24.*3600. #Mean length of solar day [s]
                             #Triton's rotation is retrograde
Triton.obliquity = 156. #Obliquity to ecliptic **ToDo: Check this.
                        #Note: Seasons are influenced by the inclination
                        #of Triton's orbit? (About 20 degrees to
                        #Neptune's equator
Triton.Lequinox = None #Longitude of equinox
#
Triton.Tsavg = 34.5 #Mean surface temperature [K]
                    #This is probably a computed blackbody
                    #temperature, rather than an observation
Triton.Tsmax = None #Maximum surface temperature [K]

# Small bodies

#--------------------------------------------------------------------------

# Bennu
Bennu = Planet()
Bennu.name = 'Bennu' #Name of the planet
Bennu.R = 246. #Mean radius of planet [m]
Bennu.g = 1.0e-5 #Surface gravitational acceleration [m.s-2]
Bennu.S = 1072.7 #Annual mean solar constant [W.m-2]
Bennu.albedo = 0.045 #Bond albedo
Bennu.emissivity = 0.95 #IR emissivity
Bennu.Qb = 0.0 #basal heat flow [W.m-2]
#Thermophysical properties:
Bennu.ks = Moon.ks # Solid (phonon) conductivity at surface [W.m-1.K-1]
Bennu.kd = Moon.kd # Solid (phonon) conductivity at depth z>>H [W.m.K-1]
Bennu.rhos = Moon.rhos # Density at surface [kg.m-3]
Bennu.rhod = Moon.rhod # Density at depth z>>H [kg.m-3]
#Bennu.ks = 1.49
#Bennu.kd = 1.49
#Bennu.rhos = 2940.
#Bennu.rhod = 2940.
Bennu.H = Moon.H # e-folding scale of conductivity and density [m]
Bennu.cp0 = Moon.cp0 # heat capacity at average surface temp. [J.kg.K-1]
Bennu.cpCoeff = Moon.cpCoeff # Heat capacity polynomial coefficients
#        
Bennu.rsm = 1.685e11 #Semi-major axis [m]
Bennu.rAU = Bennu.rsm/AU #Semi-major axis [AU]
Bennu.year = Earth.year #Sidereal length of year [s]
Bennu.eccentricity = 0.204 # Eccentricity
Bennu.day = 15469.2 #Mean length of solar day [s]
Bennu.obliquity = 3.106686 #Obliquity to plane of ecliptic [radians]
Bennu.Lequinox = None #Longitude of equinox
Bennu.Lp = 0. #Longitude of perihelion [radians]
#
Bennu.Tsavg = 270. #Mean surface temperature [K]
Bennu.Tsmax = 400. #Maximum surface temperature [K]