“The environmental requirements for life to exist depend quite strongly on the life form in question. The conditions for primitive life to exist, for example, are not nearly so demanding as they are for advanced life. Also, it makes a big difference how active the life form is and how long it remains in its environment. On this basis there are six distinct zones or regions in which life can exist.”
- Hugh Ross (Composer of the list - for some reason, he uses it as an evangilical tool.)
Complicating factors, however, are that unicellular, low metabolism life (extremophiles) typically is more easily subject to radiation damage and it has a low molecular repair rate. The origin of life problem is far more difficult for low metabolism life (H. James Cleaves II and John H. Chambers, “Extremophiles May Be Irrelevant to the Origin of Life,” Astrobiology, 4 (2004), pp. 1-9).
The following parameters of a planet, its planetary companions, its moon, its star, and its galaxy must have values falling within narrowly defined ranges for physical life of any kind to exist.
galaxy cluster type
galaxy size
galaxy type
galaxy mass distribution
galaxy location
decay rate of cold dark matter particles
hypernovae eruptions
supernovae eruptions
white dwarf binaries
proximity of solar nebula to a supernova eruption
timing of solar nebula formation relative to supernova eruption
number of stars in parent star birth aggregate
star formation history in parent star vicinity
birth date of the star-planetary system
parent star distance from center of galaxy
parent star distance from closest spiral arm
z-axis heights of star's orbit
quantity of galactic dust
number of stars in the planetary system
parent star age
parent star mass
parent star metallicity
parent star color
galactic tides
H3+ production
flux of cosmic ray protons
solar wind
parent star luminosity relative to speciation
surface gravity (escape velocity)
distance from parent star
inclination of orbit
orbital eccentricity
axial tilt
rate of change of axial tilt
rotation period * if longer: diurnal temperature differences would be too great
rate of change in rotation period
planet age
magnetic field
thickness of crust
albedo (ratio of reflected light to total amount falling on surface)
asteroidal and cometary collision rate
mass of body colliding with primordial Earth
timing of body colliding with primordial Earth
collision location of body colliding with primordial Earth
oxygen to nitrogen ratio in atmosphere
carbon dioxide level in atmosphere
water vapor level in atmosphere
atmospheric electric discharge rate
ozone level in atmosphere
oxygen quantity in atmosphere
nitrogen quantity in atmosphere
ratio of 40K, 235,238U, 232Th to iron for the planet
rate of interior heat loss
seismic activity
volcanic activity
rate of decline in tectonic activity
rate of decline in volcanic activity
timing of birth of continent formation
oceans-to-continents ratio
rate of change in oceans-to-continents ratio
global distribution of continents (for Earth)
frequency and extent of ice ages
soil mineralization
gravitational interaction with a moon
Jupiter distance
Jupiter mass
drift in major planet distances
major planet eccentricities
major planet orbital instabilities * if greater: orbit of life supportable planet would be pulled out of life support zone
mass of Neptune
Kuiper Belt of asteroids (beyond Neptune)
separation distances among inner terrestrial planets
atmospheric pressure
atmospheric transparency
magnitude and duration of sunspot cycle
continental relief
chlorine quantity in atmosphere
iron quantity in oceans and soils
tropospheric ozone quantity
stratospheric ozone quantity
mesospheric ozone quantity
quantity and extent of forest and grass fires
quantity of soil sulfer
biomass to comet infall ratio
density of quasars
density of giant galaxies in the early universe
giant star density in galaxy
rate of sedimentary loading at crustal subduction zones
poleward heat transport in planet's atmosphere
polycyclic aromatic hydrocarbon abundance in solar nebula
phosphorus and iron absorption by banded iron formations
silicate dust annealing by nebular shocks
size of galactic central bulge
total mass of Kuiper Belt asteroids
solar magnetic activity level
number of hypernovae
timing of hypernovae production
masses of stars that become hypernovae
quantity of geobacteraceae
density of brown dwarfs
quantity of aerobic photoheterotrophic bacteria
average rainfall preciptiation
species of ocean life that are vital for the existence of all life
variation and timing of average rainfall precipitation
average slope or relief of the continental land masses
distance from nearest black hole
absorption rate of planets and planetismals by parent star
water absorption capacity of planet's lower mantle
gas dispersal rate by companion stars, shock waves, and molecular cloud expansion in the Sun's birthing star cluster
decay rate of cold dark matter particles
ratio of inner dark halo mass to stellar mass for galaxy
star rotation rate
rate of nearby gamma ray bursts
aerosol particle density emitted from forests
density of interstellar and interplanetary dust particles in vicinity of life-support planet
thickness of mid-mantle boundary
galaxy cluster density
star formation rate in solar neighborhood during past 4 billion years
variation in star formation rate in solar neighborhood during past 4 billion years
gamma-ray burst events
cosmic ray luminosity of Milky Way Galaxy
air turbulence in troposphere
primordial cosmic superwinds
smoking quasars
quantity of phytoplankton
quantity of iodocarbon-emitting marine organisms
mantle plume production
quantity of magnetars (proto-neutron stars with very strong magnetic fields)
frequency of gamma ray bursts in galaxy
parent star magnetic field
amount of outward migration of Neptune
Q-value (rigidity) of Earth during its early history
parent star distance from galaxy's corotation circle
average quantity of gas infused into the universe's first star clusters
frequency of late impacts by large asteroids and comets
level of supersonic turbulence in the infant universe
number density of the first metal-free stars to form in the universe
size of the carbon sink in the deep mantle of the planet
rate of growth of central spheroid for the galaxy
amount of gas infalling into the central core of the galaxy
level of cooling of gas infalling into the central core of the galaxy
ratio of dual water molecules, (H2O)2, to single water molecules, H2O, in the troposphere
heavy element abundance in the intracluster medium for the early universe
quantity of volatiles on and in Earth-sized planet in the habitable zone
pressure of the intra-galaxy-cluster medium
level of spiral substructure in spiral galaxy
mass of outer gas giant planet relative to inner gas giant planet
triggering of El Nino events by explosive volcanic eruptions
time window between the peak of kerogen production and the appearance of intelligent life
time window between the production of cisterns in the planet's crust that can effectively collect and store petroleum and natural gas and the appearance of intelligent life
efficiency of flows of silicate melt, hypersaline hydrothermal fluids, and hydrothermal vapors in the upper crust
quantity of dust formed in the ejecta of Population III supernovae
quantity and proximity of gamma-ray burst events relative to emerging solar nebula
heat flow through the planet's mantle from radiometric decay in planet's core
water absorption by planet's mantle
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– Jack Anderson - 13 Nov 2006