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Astroecology concerns the interactions ofbiota withspace environments. It studies resources forlife onplanets,asteroids andcomets, around variousstars, ingalaxies, and in theuniverse. The results allow estimating the future prospects for life, fromplanetary togalactic andcosmological scales.^[1][2][3]

Availableenergy, andmicrogravity,radiation,pressure andtemperature are physical factors that affect astroecology. The ways by which life can reachspace environments, includingnatural panspermia anddirected panspermia are also considered.^{[4][5][6][7][8]} Further, for human expansion in space and directed panspermia, motivation by life-centeredbiotic ethics, panbiotic ethics and planetarybioethics are also relevant.^[7][8][9]

The term "astroecology" was first applied in the context of performing studies in actualmeteorites to evaluate their potential resources favorable to sustaining life.^[1] Early results showed that meteorite/asteroid materials can supportmicroorganisms,algae andplant cultures under Earth's atmosphere and supplemented with water.

Several observations suggest that diverse planetary materials, similar to meteorites collected on Earth, could be used as agricultural soils, as they provide nutrients to support microscopic life when supplemented with water and an atmosphere.^[1] Experimental astroecology has been proposed to rate planetary materials as targets for astrobiology exploration and as potential biological in-situ resources.^[1] The biological fertilities of planetary materials can be assessed by measuring water-extractableelectrolyte nutrients. The results suggest thatcarbonaceous asteroids and Martianbasalts can serve as potential future resources for substantial biological populations in theSolar System.^[1]

Analysis of the essentialnutrients (C,N,P,K) in meteorites yielded information for calculating the amount ofbiomass that can be constructed from asteroid resources.^[1] For example,carbonaceous asteroids are estimated to contain about 10²² kg potential resource materials,^{[10][11][12][13][14][15]} and laboratory results suggest that they could yield a biomass on the order of 6·10²⁰ kg, about 100,000 times more than biological matter presently onEarth.^[2]

To quantify the potential amounts of life in biospheres, theoretical astroecology attempts to estimate the amount of biomass over the duration of abiosphere. The resources, and the potential time-integrated biomass were estimated forplanetary systems, forhabitable zones aroundstars, and for thegalaxy and theuniverse.^[2][3] Such astroecology calculations suggest that the limiting elementsnitrogen andphosphorus in the estimated 10²² kg carbonaceous asteroids could support 6·10²⁰ kg biomass for the expected five billion future years of theSun, yielding a future time-integratedBIOTA (BIOTA,BiomassIntegratedOverTimesAvailable, measured in kilogram-years) of 3·10³⁰ kg-years in the Solar System,^[1][2][3] a hundred thousand times more than life on Earth to date. Considering biological requirements of 100 W kg⁻¹ biomass, radiated energy aboutred giant stars andwhite andred dwarf stars could support a time-integratedBIOTA up to 10⁴⁶ kg-years in the galaxy and 10⁵⁷ kg-years in the universe.^[2]

Such astroecology considerations quantify the immense potentials of future life in space, with commensuratebiodiversity and possibly,intelligence.^[2][3]Chemical analysis ofcarbonaceous chondrite meteorites show that they contain extractable bioavailablewater,organic carbon, and essentialphosphate,nitrate andpotassium nutrients.^[16][17][18] The results allow assessing the soil fertilities of the parent asteroids and planets, and the amounts of biomass that they can sustain.^[1][18]

Laboratory experiments showed that material from theMurchison meteorite, when ground into a fine powder and combined with Earth's water and air, can provide the nutrients to support a variety of organisms including bacteria (Nocardia asteroides), algae, and plant cultures such as potato and asparagus.^[18] The microorganisms used organics in the carbonaceous meteorites as the carbon source. Algae and plant cultures grew well also on Mars meteorites because of their high bio-available phosphate contents.^[1] The Martian materials achieved soil fertility ratings comparable to productive agricultural soils.^[1] This offers some data relating toterraforming of Mars.^[19]

Terrestrial analogues of planetary materials are also used in such experiments for comparison, and to test the effects of space conditions on microorganisms.^[20]

The biomass that can be constructed from resources can be calculated by comparing the concentration of elements in the resource materials and in biomass (Equation 1).^[1][2][3] A given mass of resource materials (m_resource) can supportm_{biomass, X} of biomass containing elementX (consideringX as the limiting nutrient), wherec_{resource, X} is the concentration (mass per unit mass) of elementX in the resource material andc_{biomass, X} is its concentration in the biomass.

${\displaystyle m_{biomass,X}=m_{resource,X}\frac{c_{resource,X}}{c_{biomass,X}}}$ (1)

Assuming that 100,000 kg biomass supports one human, the asteroids may then sustain about 6e15 (six million billion) people, equal to a million Earths (a million times the present population).^{[citation needed]} Similar materials in the comets could support biomass and populations about one hundred times larger.^{[citation needed]}Solar energy can sustain these populations for the predicted further five billion years of the Sun. These considerations yield a maximum time-integratedBIOTA of 3e30 kg-years in the Solar System. After the Sun becomes a white dwarf star,^[21] and other white dwarf stars, can provide energy for life much longer, for trillions of eons.^[22] (Table 2)

Astroecology also concerns wastage, such as the leakage of biological matter into space. This will cause an exponential decay of space-based biomass^[2][3] as given by Equation (2), where M (biomass 0) is the mass of the original biomass,k is its rate of decay (the fraction lost in a unit time) andbiomass t is the remaining biomass after timet.

Equation 2:${\displaystyle M_{biomass}(t)=M_{biomass}(0)e^{-kt}}$

Integration from time zero to infinity yields Equation (3) for the total time-integrated biomass (BIOTA) contributed by this biomass:

Equation 3:${\displaystyle BIOTA=\frac{M_{biomass}(0)}{k}}$

For example, if 0.01% of the biomass is lost per year, then the time-integratedBIOTA will be 10,000${\displaystyle M_{biomass}(0)}$. For the 6·10²⁰ kg biomass constructed from asteroid resources, this yields 6·10²⁴ kg-years ofBIOTA in the Solar System. Even with this small rate of loss, life in the Solar System would disappear in a few hundred thousand years, and the potential total time-integratedBIOTA of 3·10³⁰ kg-years under the main-sequence Sun would decrease by a factor of 5·10⁵, although a still substantial population of 1.2·10¹² biomass-supported humans could exist through the habitable lifespan of the Sun.^[2][3] The integrated biomass can be maximized by minimizing its rate of dissipation. If this rate can be reduced sufficiently, all the constructed biomass can last for the duration of the habitat and it pays to construct the biomass as fast as possible. However, if the rate of dissipation is significant, the construction rate of the biomass and its steady-state amounts may be reduced allowing a steady-state biomass and population that lasts throughout the lifetime of the habitat.

An issue that arises is whether we should build immense amounts of life that decays fast, or smaller, but still large, populations that last longer. Life-centered biotic ethics suggests that life should last as long as possible.^[9]

If life reaches galactic proportions,technology should be able to access all of the materials resources, and sustainable life will be defined by the available energy.^[2] The maximum amount of biomass about any star is then determined by the energy requirements of the biomass and by theluminosity of the star.^[2][3] For example, if 1 kg biomass needs 100 Watts, we can calculate the steady-state amounts of biomass that can be sustained by stars with various energy outputs. These amounts are multiplied by the life-time of the star to calculate the time-integratedBIOTA over the life-time of the star.^[2][3] Using similar projections, the potential amounts of future life can then be quantified.^[2]

For the Solar System from its origins to the present, the current 10¹⁵ kg biomass over the past four billion years gives a time-integrated biomass (BIOTA) of 4·10²⁴ kg-years. In comparison, carbon,nitrogen,phosphorus and water in the 10²² kg asteroids allows 6·10²⁰ kg biomass that can be sustained with energy for the 5 billion future years of the Sun, giving aBIOTA of 3·10³⁰ kg-years in the Solar System and 3·10³⁹ kg-years about 10¹¹ stars in the galaxy. Materials in comets could give biomass and time-integratedBIOTA a hundred times larger.

The Sun will then become awhite dwarf star, radiating 10¹⁵ Watts that sustains 1e13 kg biomass for an immense hundred million trillion (10²⁰) years, contributing a time-integratedBIOTA of 10³³ years. The 10¹² white dwarfs that may exist in the galaxy during this time can then contribute a time-integratedBIOTA of 10⁴⁵ kg-years. Red dwarf stars with luminosities of 10²³ Watts and life-times of 10¹³ years can contribute 10³⁴ kg-years each, and 10¹² red dwarfs can contribute 10⁴⁶ kg-years, whilebrown dwarfs can contribute 10³⁹ kg-years of time-integrated biomass (BIOTA) in the galaxy. In total, the energy output of stars during 10²⁰ years can sustain a time-integrated biomass of about 10⁴⁵ kg-years in the galaxy. This is one billion trillion (10²⁰) times more life than has existed on the Earth to date. In the universe, stars in 10¹¹ galaxies could then sustain 10⁵⁷ kg-years of life.

The astroecology results above suggest that humans can expand life in the galaxy throughspace travel ordirected panspermia.^[23][24] The amounts of possible life that can be established in the galaxy, as projected by astroecology, are immense. These projections are based on information about 15 billion past years since theBig Bang, but the habitable future is much longer, spanning trillions of eons. Therefore, physics, astroeclogy resources, and some cosmological scenarios may allow organized life to last, albeit at an ever slowing rate, indefinitely.^[25][26] These prospects may be addressed by the long-term extension of astroecology as cosmoecology.

• Biotic ethics
• Cosmology
• Meteorites

• Astro-Ecology / Science of expanding life in space
• AstroEthics / Ethics of expanding life in space
• Panspermia-Society / Science and ethics of expanding life in space

• Astrobiology
• Habitat
• Environmental terminology
• Ecology terminology

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