Difference between revisions of "Carbon dioxide"

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'''Carbon dioxide''' (''chemical formula:'' CO<sub>2</sub>) is a chemical substance that occupies about 96 % of [[Mars]]'s [[atmosphere]].
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[[File:Carbon dioxide Structural Formula V1.svg|thumb|200x200px|Carbon dioxyde molecule]]
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'''Carbon dioxide'''<ref>https://en.wikipedia.org/wiki/Carbon_dioxide</ref> (''chemical formula:'' CO<sub>2</sub>) is a [[Elements on Mars|chemical substance]] that occupies about 96 % of the [[Mars|Martian]] [[atmosphere]].
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__NOTOC__
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Molar Mass of 12(C)+32(O<sub>2</sub>)=44
  
 
==Biological significance==
 
==Biological significance==
The metabolism of [[human|human beings]], [[:category:animals|animals]] and various [[microbes]] depends on the oxidation of [[carbohydrate]]s, resulting in carbon dioxide exhalation.  
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The metabolism of [[human|human beings]], [[:category:animals|animals]] and various [[microbes]] depends on the oxidation of [[carbohydrate]]s, resulting in carbon dioxide and water exhalation.  [[:Category:Plants|Plants]] use the [[carbon]] from carbon dioxide  to produce [[carbohydrates]]  and release the [[oxygen]] back to the [[atmosphere]], completing the cycle.  
  
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:The reaction is: CO<sub>2</sub>(carbon dioxide) + 2H<sub>2</sub>O (water) + photons (light energy) → C<sub>(n)</sub>H<sub>2</sub>O<sub>(m)</sub> (carbohydrate) + O<sub>2</sub>(oxygen)+ H<sub>2</sub>O (water)<ref>[[w:Photosynthesis|Photosynthesis- https://en.wikipedia.org/wiki/Photosynthesis]]</ref>
  
[[:Category:Plants|Plants]] use the [[carbon]] from CO<sub>2</sub>, and release the [[oxygen]] back to the [[atmosphere]].
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Humans require that carbon dioxide levels be low in the air, so that CO2 in the blood can diffuse outwards into the air in the lungs.  There can be plenty of oxygen in the air, but if CO2 goes much over 0.5% of the air pressure, then flow of CO2 out of the body is slowed.  OSHA (Occupational Safety & Health Administration) has established a permissible Exposure Limit of 5,000 parts per million (ppm) or 0.5% of CO2 in the air, averaged over an 8 hour work day.  At 10,000 ppm (1.0%) CO2 may cause drowsiness.  At 4% to 5% it is immediately dangerous to life or health (gasping for breath, dizziness, confusion, headaches, shortness of breath).  At 80,000 ppm (8% of the air pressure) it will cause unconsciousness and then death.  These responses vary by individual (depending on how healthy they are), and on the length of the exposure.  The treatment for too high CO2 concentration is to immediately move the subject to an area with low CO2, to allow the dangerous CO2 level in the blood to drop.
  
The one single cenocrn that is threatening the very existence of lives in this planet is global warming. Global warming can be minimized to a great extent, if we eliminate the causes which are mostly human made… Introduction To the ThreatenThe one single cenocrn that is threatening the very existence of lives in this planet is global warming. The drastic changes in the climatic conditions pose serious threat to our future generation. Owing to the results of global warming glaciers is retreating, sea levels are increasing, polar bears and other rare cold climate species are slowly becoming extinct. Navigators maintain that the Icebergs that once dominated the Atlantic and Pacific oceans have now vanished. Scientists and environmentalists conducted various studies and concluded that the past 30 years has been the warmest period in the global history. The main causes attributed towards global warming are human activities. The burning of fossil fuel is one of the major factors that contribute to global warming. Reasons for Global Warming Global warming can be minimized to a great extent, if we eliminate the causes which are mostly human made. The responsibility of preventing global warming rests both on individual as well as the state. In individual level we can change our practices such as minimize the usage of fossil based fuel, reduce the electricity consumption by using energy efficient appliances. Vehicular pollution can be minimized by using the public transport system. The nucleus goal is to beget the global warming under control by restricting the carbon dioxide release and other heat ensnaring greenhouse gases into the environment. On an average nearly 10000 pounds of carbon dioxide is released per year in significant countries like Canada and US. This can be immediately curtailed by becoming energy efficient. Reducing the usage of oil, coal and gasoline are one of the effective ways of preventing global warming. Home Appliances Contribution to Global Warming Regrettably, it is noticed that an average home contributes to global warming more than a car. The increase of contribution is at home because the energy utilized in our homes is received from power plants that burn fossil fuel to provide power for our electric products. We can save energy by substituting compact fluorescent bulbs in the place of incandescent light bulbs. This will save your money as well as your energy bill will be minimal. The CFL bulbs last longer and the energy consumed is also less. LED bulbs are efficient and energy savers. Home appliances also contribute a lot in elevating the energy bill. The higher is the energy efficient appliance, the lesser is the cost of running the appliance. So purchasing energy efficient appliances will help in reducing the utility bill and also in protecting the environment. Similarly, purchase major appliances such as dishwasher, air conditioner or refrigerator with maximum energy efficiency. This reduces the carbon dioxide pollution. As per the U.S. energy report, heating as well as cooling systems emit maximum carbon dioxide in the atmosphere. The energy used for our homes for heating goes in vain though the prevention is inexpensive and simple. This energy that goes vain can be saved by reducing the need for air conditioners. This can help improve the environment from pollution. The largest source is transportation that adds to greenhouse gases. Vehicles are responsible and poor maintenance of vehicle contributes to pollution and global warming. Maintaining Vehicle Efficiency This can be protected by increasing the overall fuel efficiency of your vehicle and paying attention to your driving style and maintenance. Buying fuel efficient hybrid cars and using bio-fuel that allows using gas electric engines and thereby cutting global warming pollution to a great extent. Driving less and making use of public transports, walking or riding a bike will save the environment from pollution. Besides this, consolidating trips and encouraging car- pooling is one of the effective ways of preventing global warming. Recycling maximum products, eating local foods and vegetarian meals, painting home in light color, purchasing energy certificates as well as carbon offsets are few of the ways of preventing our wonderful planet, the earth from the disastrous global warming. Though, there are many ways to prevent initiating and following it with determination will yield the desired results. This is a unison effort and so all the hands have to join together with force to push the effects of global warming back beyond sight.
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==Settlement atmosphere==
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[[File:Colony CO2 treatment.png|thumb|600x600px]]
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Carbon dioxide is required in the [[Air|settlement atmosphere]] for plant metabolism.  Standard concentration on Earth is increasing, so the value is a moving target. However, a concentration between 300 ppm (0,03%) and 1,000 ppm (0,1%) is considered acceptable<ref>Carbon dioxyde concentrations<nowiki/>https://www.nap.edu/read/11170/chapter/5</ref>. Nuclear submarines have varying carbon dioxide levels that can reach 9000 ppm in normal operations, but average between 3-4000ppm<ref>High CO2 exposures: https://www.nap.edu/read/11170/chapter/5#47</ref>. A CO<sub>2</sub> enriched environment may be beneficial for the growth of plants in [[greenhouse|greenhouses]] or [[photobioreactor|photobioreactors]].
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The Sabatier process can be used in place of photosynthesis to complete the atmospheric part of the carbon cycle. [[Bioreactor#Methanotrophs|Methanotrophic]] synthesis of carbohydrates from [[methane]] would be required to complete the carbon metabolic cycle without the use of plants.  Or food can be supplied from Earth or Mars for a partial cycle, where [[Methane]] from the Sabatier process can be stored for use as a propellant.
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==How Submarines remove carbon dioxide <ref>Destin Sandlin (2021). How Do Nuclear Submarines Make Oxygen?- Smarter Every Day 251 [Video]. https://www.youtube.com/watch?v=g3Ud6mHdhlQ; SmarterEveryDay.</ref>==
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Submarines are a fairly good analog for a Mars habitat, a sealed system that has to manufacture oxygen and remove carbon dioxide.
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Submarines have two processes for removing CO<sub>2</sub>, primary extractor is powered and has no consumables, the secondary is low tech but has consumables (typically used when the primary is undergoing maintenance or repair).
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Primary uses Monoethanolamine or MEA. MEA is sprayed on the air to increase the MEA surface area with the air. MEA absorbs CO<sub>2</sub> from the air. CO<sub>2</sub> rich MEA gets pumped into a heater. The MEA is boiled at a high pressure which causes the CO<sub>2</sub> to distill out first. CO<sub>2</sub> is compressed and pushed out of the boat into the sea. Submariner spouses complain about the MEA smell from the uniforms when they return home. The MEA smell permeates everything.
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Secondary CO<sub>2</sub> scrubber uses Lithium Hydroxide LiOH. Lithium Hydroxide absorbs CO2 but in a submarine it’s a one use process. The canisters need to remain sealed until they are going to be used. LiOH powder can be sprinkled around on surfaces to absorb CO<sub>2</sub>. This is the same technology used for CO<sub>2</sub> removal in spacesuits.<br>
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2LiOH<sub>(s)</sub> + CO<sub>2(g)</sub> -> Li<sub>2</sub>CO<sub>3(s)</sub> + H<sub>2</sub>O<sub>(g)</sub> <ref>Carbon Dioxide Removal – Thermodynamics. Nasa.gov. Retrieved 16 November 2021, from https://www.nasa.gov/pdf/519347main_AP_ST_CO2Removal_Therm.pdf.</ref><br>
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Although the reaction can be reversed, neither the ISS nor submarines do so.
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==[[In-situ resource utilization|In situ Production]]==
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CO2 will be extracted [[In-situ resource utilization|in-situ]] by [[atmospheric processing]], or from carbonate rocks to provide larger industrial quantities to feed industry<ref>https://www.nature.com/articles/ngeo971</ref> Carbonate rocks are common on Earth, but seem to be rarer on Mars.  It is possible that Mars has more carbonate rock formations which are buried.
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It is very likely that large amounts of CO2 will be found in local clays which will out-gas if the clay is warmed. (Some clays can hold 9% of their mass in CO2 when cold.)
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==Notes on Atmosphere==
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CO2 forms clouds in the Martian atmosphere, which is rare.  (Most planetary atmospheres do not form clouds of its primary constituent.)  Mars is so cold that CO2 freezes out in the winter, causing the planet's air pressure to fall by as much as 30%. See [[Atmosphere]] for more details.
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CO2 is a [[Greenhouse gas]] and if more carbon dioxide could be outgassed from the crust somehow, the planet would warm. See [[Terraforming]] for more details.
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==Concentration==
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Concentration of CO2 on Earth is was 275 parts per million (ppm) in pre-industrial times.  Currently it has risen above 400 ppm.  Increasing concentration improves plant production rates, however the effect is non linear and reaches a peak of 20% improvement in yields at about 1,200 ppm.<ref>University of California, Agriculture and Natural ressources https://ucanr.edu/blogs/NurseryFlower/</ref>  This may also be affected by pressure, if low pressure greenhouse are developed for Mars.
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[[File:CO2 concentration.jpg|thumb|Effect of CO2 concentration on plant production]]
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==Uses==
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*[[Food preservation|Food Preservation]]
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*[[Photosynthesis]] by plants in [[greenhouse]]s to create [[carbohydrates]] for plant metabolism.
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*[[Synthetic materials]], [[Hydrocarbons|hydrocarbon]]<nowiki/>s using the [[Fischer-Tropsch reaction|Fischer Tropsch]] reaction process.
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*[[Propellant]] production. Methane (CH<sub>4</sub>) and Oxygen (O<sub>2</sub>), through [[In-situ resource utilization|ISRU]] using the [[Sabatier process]]. The hydrogen comes from Electrolysis of water or is brought from Earth.
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*[[Carbon]] using the [[Bosch reaction]] process. The Bosch reaction consumes hydrogen to produce carbon and water. The [[hydrogen]] can come from [[electrolysis]] of water.
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==References==
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[[Category: Biospherics]]
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<references />

Revision as of 14:44, 16 November 2021

Carbon dioxyde molecule

Carbon dioxide[1] (chemical formula: CO2) is a chemical substance that occupies about 96 % of the Martian atmosphere.

Molar Mass of 12(C)+32(O2)=44

Biological significance

The metabolism of human beings, animals and various microbes depends on the oxidation of carbohydrates, resulting in carbon dioxide and water exhalation. Plants use the carbon from carbon dioxide to produce carbohydrates and release the oxygen back to the atmosphere, completing the cycle.

The reaction is: CO2(carbon dioxide) + 2H2O (water) + photons (light energy) → C(n)H2O(m) (carbohydrate) + O2(oxygen)+ H2O (water)[2]

Humans require that carbon dioxide levels be low in the air, so that CO2 in the blood can diffuse outwards into the air in the lungs. There can be plenty of oxygen in the air, but if CO2 goes much over 0.5% of the air pressure, then flow of CO2 out of the body is slowed. OSHA (Occupational Safety & Health Administration) has established a permissible Exposure Limit of 5,000 parts per million (ppm) or 0.5% of CO2 in the air, averaged over an 8 hour work day. At 10,000 ppm (1.0%) CO2 may cause drowsiness. At 4% to 5% it is immediately dangerous to life or health (gasping for breath, dizziness, confusion, headaches, shortness of breath). At 80,000 ppm (8% of the air pressure) it will cause unconsciousness and then death. These responses vary by individual (depending on how healthy they are), and on the length of the exposure. The treatment for too high CO2 concentration is to immediately move the subject to an area with low CO2, to allow the dangerous CO2 level in the blood to drop.

Settlement atmosphere

Colony CO2 treatment.png

Carbon dioxide is required in the settlement atmosphere for plant metabolism. Standard concentration on Earth is increasing, so the value is a moving target. However, a concentration between 300 ppm (0,03%) and 1,000 ppm (0,1%) is considered acceptable[3]. Nuclear submarines have varying carbon dioxide levels that can reach 9000 ppm in normal operations, but average between 3-4000ppm[4]. A CO2 enriched environment may be beneficial for the growth of plants in greenhouses or photobioreactors.

The Sabatier process can be used in place of photosynthesis to complete the atmospheric part of the carbon cycle. Methanotrophic synthesis of carbohydrates from methane would be required to complete the carbon metabolic cycle without the use of plants. Or food can be supplied from Earth or Mars for a partial cycle, where Methane from the Sabatier process can be stored for use as a propellant.

How Submarines remove carbon dioxide [5]

Submarines are a fairly good analog for a Mars habitat, a sealed system that has to manufacture oxygen and remove carbon dioxide.

Submarines have two processes for removing CO2, primary extractor is powered and has no consumables, the secondary is low tech but has consumables (typically used when the primary is undergoing maintenance or repair).

Primary uses Monoethanolamine or MEA. MEA is sprayed on the air to increase the MEA surface area with the air. MEA absorbs CO2 from the air. CO2 rich MEA gets pumped into a heater. The MEA is boiled at a high pressure which causes the CO2 to distill out first. CO2 is compressed and pushed out of the boat into the sea. Submariner spouses complain about the MEA smell from the uniforms when they return home. The MEA smell permeates everything.

Secondary CO2 scrubber uses Lithium Hydroxide LiOH. Lithium Hydroxide absorbs CO2 but in a submarine it’s a one use process. The canisters need to remain sealed until they are going to be used. LiOH powder can be sprinkled around on surfaces to absorb CO2. This is the same technology used for CO2 removal in spacesuits.
2LiOH(s) + CO2(g) -> Li2CO3(s) + H2O(g) [6]
Although the reaction can be reversed, neither the ISS nor submarines do so.

In situ Production

CO2 will be extracted in-situ by atmospheric processing, or from carbonate rocks to provide larger industrial quantities to feed industry[7] Carbonate rocks are common on Earth, but seem to be rarer on Mars. It is possible that Mars has more carbonate rock formations which are buried.

It is very likely that large amounts of CO2 will be found in local clays which will out-gas if the clay is warmed. (Some clays can hold 9% of their mass in CO2 when cold.)

Notes on Atmosphere

CO2 forms clouds in the Martian atmosphere, which is rare. (Most planetary atmospheres do not form clouds of its primary constituent.) Mars is so cold that CO2 freezes out in the winter, causing the planet's air pressure to fall by as much as 30%. See Atmosphere for more details.

CO2 is a Greenhouse gas and if more carbon dioxide could be outgassed from the crust somehow, the planet would warm. See Terraforming for more details.

Concentration

Concentration of CO2 on Earth is was 275 parts per million (ppm) in pre-industrial times. Currently it has risen above 400 ppm. Increasing concentration improves plant production rates, however the effect is non linear and reaches a peak of 20% improvement in yields at about 1,200 ppm.[8] This may also be affected by pressure, if low pressure greenhouse are developed for Mars.

Effect of CO2 concentration on plant production

Uses

References

  1. https://en.wikipedia.org/wiki/Carbon_dioxide
  2. Photosynthesis- https://en.wikipedia.org/wiki/Photosynthesis
  3. Carbon dioxyde concentrationshttps://www.nap.edu/read/11170/chapter/5
  4. High CO2 exposures: https://www.nap.edu/read/11170/chapter/5#47
  5. Destin Sandlin (2021). How Do Nuclear Submarines Make Oxygen?- Smarter Every Day 251 [Video]. https://www.youtube.com/watch?v=g3Ud6mHdhlQ; SmarterEveryDay.
  6. Carbon Dioxide Removal – Thermodynamics. Nasa.gov. Retrieved 16 November 2021, from https://www.nasa.gov/pdf/519347main_AP_ST_CO2Removal_Therm.pdf.
  7. https://www.nature.com/articles/ngeo971
  8. University of California, Agriculture and Natural ressources https://ucanr.edu/blogs/NurseryFlower/