Difference between revisions of "Venus"
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+ | More general: [[Colonisation of the solar system]] | ||
+ | ---- | ||
+ | If one does not insist to go down to the solid surface (0m 500°C 90bar) <br> Venus is actually a nice place for humans to colonize (52.5km 37°C 660mbar). <br> | ||
+ | And it might be rather easy with nanofactories since Venus' atmosphere is is essentially an ocean of building material bathed in intense sunlight. | ||
− | + | Venus is pretty devoid of Hydrogen (20ppm Water that amounts to about 20kg per cubic kilometer at 1bar level) which is essential for APM technology. Luckily there's this nice sulfuric acid rain which concentrates the hydrogen for us. We get a bonus of a high deuterium concentration - whatever it may be used for. Also diamond [[crystolecule]]s have much less hydrogen passivated surface than the hydrocarbon chains in current day plastics. Much much less than one hydrogen atom per carbon atom. | |
− | + | ||
− | Breathable air and nitrogen are effective lifting gasses in the dense carbon dioxide atmosphere. | + | Breathable air and nitrogen are effective lifting gasses in the dense carbon dioxide atmosphere and can be directly drawn from the atmosphere. |
Comparison of molecular weights: nitrogen 28, oxygen 32, carbon dioxide 44 | Comparison of molecular weights: nitrogen 28, oxygen 32, carbon dioxide 44 | ||
− | == | + | == Why is Venus' surface so difficult to explore? == |
+ | |||
+ | * High temperature (~500°C)? No. One can isolate against that. | ||
+ | * High pressure (~90atm)? No. One can build pressure resistant capsules. The increased weight is not nice for spaceflight though. | ||
+ | ---- | ||
+ | * Lack of an energy source at ground level? Yes,yes,yes! <br>That's the one single most difficult problem hardest to crack. <br> A power source would allows for active cooling and long duration mission. | ||
+ | * High gravity? Yes in case of a sample return mission. It's as bad as with Earth. That means it's really bad. | ||
+ | |||
+ | This is generally misunderstood as Venus' surface conditions (~500°C,~90atm) seems so daunting and attention grabbing. <br> | ||
+ | But they actually are not the core problem. The problem is the lack of a long duration power source for active cooling. | ||
+ | High temperature electronics are not a good alternative unless one is fine with going back to Venera like single pixel scanning camera crudeness (amazing for the time back then). | ||
+ | |||
+ | = Atmosphere = | ||
The atmosphere is not your foe its your friend. She .. | The atmosphere is not your foe its your friend. She .. | ||
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* .. provides an environment with nearly constant temperature | * .. provides an environment with nearly constant temperature | ||
* .. to a degree protects from volcanism on the ground | * .. to a degree protects from volcanism on the ground | ||
− | * .. reduces the day night cycle to a reasonable length. ( | + | * .. reduces the day night cycle to a reasonable length. (super-rotation) |
− | + | The chemically neutral to reducing character of the atmosphere may allow to make use of materials that in an atmosphere containing oxygen quickly oxidize extending the range of usable base materials for higher level [[metamaterial]]s. This way passivation with locally scarce hydrogen may be avoidable altogether. | |
+ | See: [[Colonisation of the solar system#Flavors of diamondoid gem gum technology|Flavors of diamondoid gem gum technology]] | ||
− | + | == Interesting facts == | |
− | == | + | === Results from balloon missions === |
− | The | + | The Vega probes placed each a balloon in the atmosphere of Venus. They drifted in a height of around 53km 46 and 60 hours long. In this time they covered a distance of about a third of the circumference of Venus an measured wind speed, temperature, pressure and cloud density. Thereby more storm and air current activity was observed than anticipated. Also a sudden change in flight height of about one to three kilometer was detected. (Source: [http://de.wikipedia.org/wiki/Venus_(Planet) de.wikipedia]) |
− | === Basic housing | + | {{todo|Check the actual data - what means a sudden change in flight height here. What means sudden sudden here?}} <br> |
+ | High up in the atmosphere strong wind-speed gradients like the ones on the surface of earth are probably not to expect. | ||
+ | How much is known about the scales of the turbulences in the venusian atmosphere? | ||
+ | |||
+ | === Why Venus is the way she is === | ||
+ | |||
+ | The following is from gathered crumbs of info. It totally needs references. <br> | ||
+ | Take it with a grain of salt for now. | ||
+ | |||
+ | There are a number of (partially circular) interrelationships that made Venus what it is today and keep it that way. <br> | ||
+ | In the following list: Read the backward arrows "'''<='''" as "is/was caused by". <br> | ||
+ | Please take these simplifications with a grain of salt! | ||
+ | |||
+ | * massive CO<sub>2</sub> atmosphere '''<=''' CO<sub>2</sub> not bound in the ground as CaCO<sub>3</sub> '''<=''' no water (H<sub>2</sub>O) on the planet (to wash it out and bind it) '''<=''' no hydrogen on/in the planet | ||
+ | * no significant mountains on Venus '''<=''' no plate tectonics '''<=''' no "lubricating" water (H<sub>2</sub>O) in the planets crust AND a very thick and cool planetary crust | ||
+ | * a thick and cool crust '''<=''' fast cooling of the planets interior '''<=''' no tectonics AND no "lubricating" water in the crust | ||
+ | * no "lubricating" water in the crust '''<=''' no hydrogen in/on Venus '''<=''' solar wind blowing away the hydrogen '''<=''' no magnetic field '''<=''' cool core '''<=''' fast cooling | ||
+ | * long day '''<=''' near to sun and no moon (?) and no plate tectonics (??) | ||
+ | * ... '''<=''' red hot glowing surface '''<=''' ... | ||
+ | |||
+ | {{todo|Improve this list (less overlaps) and make an image with arrows for the interrelationships.}} | ||
+ | |||
+ | = Colonisation - (conceptual) = | ||
+ | |||
+ | The objective is to create a nice place for humans to live. | ||
+ | |||
+ | == Basic housing == | ||
First a nanofactory (e.g. of the size of a sugar cube) is sent to Venus. | First a nanofactory (e.g. of the size of a sugar cube) is sent to Venus. | ||
− | There a durable balloon is created with a | + | There a durable balloon is created with a semi-transparent semi-reflective [[diamondoid solar cells|diamond solar foil]] on top that leaves through enough light for plants to grow. |
− | The balloon further needs an | + | The balloon further needs an ''[[atmospheric converter unit]]'' ([[air using micro ships]]) that has a number of functions. It creates among other thing breathable air. The balloon must be inflated while being built to be kept afloat at all times. |
− | + | == Creation of soil for plants == | |
Creating earth like soil with humic substances such that plants can grow in a natural way takes a lot longer then the employment of such a balloon. | Creating earth like soil with humic substances such that plants can grow in a natural way takes a lot longer then the employment of such a balloon. | ||
One could start with hydroponic cultures and compose the dead plants. At that time humans may be present or may not. A small piece of earth soil may be usable to introduce a rich set of microorganisms. | One could start with hydroponic cultures and compose the dead plants. At that time humans may be present or may not. A small piece of earth soil may be usable to introduce a rich set of microorganisms. | ||
+ | (Each balloon can be an experimental perfectly isolated ecosystem) | ||
It should be rather easy to design small balloons but to create an earth like landscape a bigger free area and some soil depth is probably desired. | It should be rather easy to design small balloons but to create an earth like landscape a bigger free area and some soil depth is probably desired. | ||
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At this size one needs to consider the wind speed gradient in the atmosphere which is around 10m/s per 1km. One doesn't want the balloon to start rolling like a barrel. This may be a difficult problem. | At this size one needs to consider the wind speed gradient in the atmosphere which is around 10m/s per 1km. One doesn't want the balloon to start rolling like a barrel. This may be a difficult problem. | ||
− | === Atmospheric converter unit | + | == Air conditioning == |
+ | |||
+ | Although 37°C with 660mbar air pressure is endurable for most humans it's not pleasant. | ||
+ | Can a leightweight balloon hull provide enough [[thermal isolation]] to make a more pleasurable environment of e.g. 22°C at higher pressure? | ||
+ | |||
+ | There are several options for how to handle the three parameters pressure height and temperature when the outside weather changes abruptly. | ||
+ | |||
+ | == Atmospheric converter unit for Venus == | ||
* filters nitrogen from the atmosphere | * filters nitrogen from the atmosphere | ||
* captures sulfuric acid rain which concentrates the rare hydrogen [Todo: at which heights is sulfuric acid rain present] | * captures sulfuric acid rain which concentrates the rare hydrogen [Todo: at which heights is sulfuric acid rain present] | ||
* sulfuric acid → hydrogen + sulfur dioxide | * sulfuric acid → hydrogen + sulfur dioxide | ||
− | * carbon dioxide + hydrogen | + | * carbon dioxide + hydrogen → ethyne + oxygen |
− | Because of the [[reproduction hexagon]] it may make sense to keep it separate from the nanofactory. | + | Because of the [[reproduction hexagon]] it may make sense to keep it separate from the nanofactory. Related: [[Mobile carbon dioxide collector balloon]]. |
− | + | = Possible threats = | |
− | + | == Lightning == | |
− | Some kind of lightning arrester system needs to be devised. | + | Some kind of lightning arrester system needs to be devised. <br> |
+ | Active aversion of especially bad weather may or may not a viable strategy depending <br> | ||
+ | on wind speeds and mobility of the aerial vehicle of choice. | ||
− | + | Airplanes on Earth manage to deal pretty good with occasionally being hit by lightning strikes. <br> | |
+ | Granted they always try to avoid bad weather. <br> | ||
+ | There should be quite some info on that for investigating further. | ||
− | + | == Strong downwards facing winds == | |
− | + | ||
− | + | How much down sucking winds are there on Venus excactly? <br> | |
+ | If there are too strong downwinds that cannot reliably be avoided <br> | ||
+ | that reach all the way down to extreme heat and pressure levels then aerial colonization might not be viable. | ||
− | Building a thin walled carbon balloon filled with oxygen is basically asking for fire. | + | === Likely no anti-cyclones === |
− | To mend this problem one can compartmentalize bigger balloons. Only the bottom few meters get filled with breathable air. A transparent ceiling foil material separates off the majority of the balloons volume. This part gets filled with nitrogen and is uninhabited "empty" space. | + | |
+ | Given the global super-rotation of the atmosphere there are like no hidden big scale anticyclones. <br> | ||
+ | Even if there were anticyclones, these are typically larger and much less vigorous than cyclones since | ||
+ | they have a negative feedback cycle in energy release rather than a positive one. <br> | ||
+ | <small>The big red spot on [[Jupiter]] is an anticyclone where there are no clouds in the upper layers of the atmosphere and one can see deep inside Jupiters guts.</small> | ||
+ | |||
+ | '''Adiabatic compression in big air down-swirls (aka anticyclones):''' <br> | ||
+ | air heats up => clouds and mist evaporate which takes up a lot of energy (negative feedback) => Clear skies slow wind-speeds over wide areas. | ||
+ | |||
+ | '''Adiabatic expansion in big air up-swirls (aka cyclones):''' <br> | ||
+ | air cools down => and humid air condensates into clouds which releases a lot of energy (positive feedback) intensified by percipitation => intense thunderstorms - more local | ||
+ | |||
+ | === Measured sudden down-drafts (to worry about?) === | ||
+ | |||
+ | The balloon missions on Venus registered significant and sudden drops in altitude. Which sounds a bit worrying. <br> | ||
+ | {{wikitodo|investigate sudden ballon altitude drops in venera mission(s) further}} | ||
+ | |||
+ | === Different effect on different means for staying aloft === | ||
+ | |||
+ | Strong down-winds would be especially a problem for Balloons or Blip/Zeppelin like airships with big wind-attack-area to mass ratios that have thus | ||
+ | rather limited maximal speeds relative to the air. <br> | ||
+ | |||
+ | Strong down-winds would be less of a problem for [[permanently flying airplanes]]. <br> | ||
+ | But truly permanently flying airplanes require very advanced technology that is capable of active in flight self repair. <br> | ||
+ | Ideally with resources directly tapped from the atmosphere. | ||
+ | |||
+ | == Wing gusts (danger of toppling over) == | ||
+ | |||
+ | Since there are no obstacles high up in the atmosphere on a small scale differences in relative airspeed should be negligible. <br> | ||
+ | On a bigger scale this might become an issue ['''data needed''']. <br> | ||
+ | Like a very big balloon might strongly want to start to roll over upside down. | ||
+ | |||
+ | == Fires == | ||
+ | |||
+ | Building a thin walled carbon balloon filled with oxygen is basically asking for fire. (On an other note when a hole is burnt into the hull penetrating carbon dioxide will probably quickly extinquish any fire) | ||
+ | To mend this problem one can compartmentalize bigger balloons. Only the bottom few meters get filled with breathable air. A transparent ceiling foil material separates off the majority of the balloons volume. This part gets filled with nitrogen and is uninhabited "empty" space. A nice side effect is slightly more buoyancy lift. | ||
An other approach is to use silicon carbide as a building material which may self protect against fire by building glass. | An other approach is to use silicon carbide as a building material which may self protect against fire by building glass. | ||
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A closed material "cycle" can be conceived that protects against fire even if atmosphere gets really crowded. | A closed material "cycle" can be conceived that protects against fire even if atmosphere gets really crowded. | ||
− | * carbon dioxide + silicate stone → silicon carbide + oxygen | + | * carbon dioxide + silicate stone → '''silicon carbide''' + oxygen |
* oxygen + iron → iron oxides | * oxygen + iron → iron oxides | ||
* sulfur dioxide + iron → pyrite + iron oxides | * sulfur dioxide + iron → pyrite + iron oxides | ||
− | * sulfuric acid + oxygen → hydrogen + sulfur dioxide | + | * sulfuric acid + oxygen → '''hydrogen''' + sulfur dioxide |
+ | |||
+ | (Energy gets stored in gravity - since heavy things can't fall through (non-molten) light things there's a perfectly safe activation energy barrier) | ||
+ | |||
+ | = Outlook on a very long term - {{SciFi warning}} = | ||
+ | |||
+ | [[File:Possible_use_of_Venusian_Resources.svg|400px|thumb|right|How Venusian resources could be used in the very long term.{{todo|add fluorine and chlorine to the diagram}}]] | ||
+ | |||
+ | Since with advanced nanofactories exponential growth is easy it comes naturally to think about Terraforming. | ||
+ | We'll discuss later whether a terraforming attempt is desirable and whether it makes sense. | ||
+ | |||
+ | The main reason why the venusian atmosphere is so hot at it's bottom is not because Venus is so near to the Sun or because there is a runaway green house effect. It is so hot because it is so massive. Adiabatic compression of a gas heats it up. When a volume of gass high up in the atmosphere falls back to the ground it gets adiabatically compressed and heated. | ||
+ | |||
+ | === Binding excessive elements of the atmosphere === | ||
+ | |||
+ | To reduce the mass of Venus' atmosphere the most part of the carbon dioxide all the sulfur trioxide and a good part of the nitrogen would need to be bound with some kind of [[Carbon dioxide collector]]s placed in the upper layers of the Venusian atmosphere where the conditions are benign. The carbon dioxide needs to be bound in a chemically very stable form (dropped down or kept floating ?) such that in a later state of the atmosphere with free oxygen powerful ignition sources (like e.g. frequent and powerful strokes of lightning and bigger things like meteor impacts) cannot cause an epic global firestorm putting all the carbon back into the atmosphere. Like the energy rich but sufficiently metastable bisophere on earth. | ||
+ | |||
+ | To get rid of all the carbon bound in the carbon dioxide it could be combined with silicon taken from the silicon dioxide (quartz) of the planets crust. | ||
+ | This would create the useful building material silicon carbide (moissanite) which is (in big chunks) self protecting against fire. When ignited at all (which is very hard to do) it forms a molten glass layer preventing further oxygen from reacting with more carbon and silicon inside. | ||
+ | |||
+ | Doing that beside the oxygen from the carbon dioxide one also gets oxygen from silicon dioxide. | ||
+ | Each source on its own is far too much for earth like oxygen levels. | ||
+ | Obviously it wouldn't be smart to create a super-dense (too dense for humans and incredible dangerous) oxygen atmosphere. | ||
+ | To get rid of all that excess oxygen a giant amount of some reducing element is needed. | ||
+ | Ideally the oxygen would be bound to hydrogen but there is barely any hydrogen on Venus. | ||
+ | Most of it was blown away by the solar wind. | ||
+ | So hydrogen would need to be delivered from space. Which sounds difficult. | ||
+ | Probably gentle methods should be used not a destructive methods like bombardment with ice meteors which seem to have no benefits. | ||
+ | A reducing element that is certainly present in sufficient amounts on Venus is iron. | ||
+ | The oxygen can be bound in the useful iron mineral building materials hematite and magnetite. | ||
+ | Big amounts of metallic non-reduced iron can be found in the planets mantle and outer core. | ||
+ | Advanced atomically precise technology ([[gem-gum technology]]) may make mining in such extreme pressure and temperature environments possible. | ||
+ | But this goes near the very limits of the physical possible! | ||
+ | |||
+ | The iron can also be used to bind sulfur from sulfur trioxide (which is another gas that needs to be bound into a solid state) into the mineral pyrite. | ||
+ | For the excess nitrogen there are plenty of options to bind it safely. | ||
+ | |||
+ | While setting up the process (exponential production of carbon dioxide collectors) is straightforward for Venus' atmosphere | ||
+ | for the then following terraforming process an incredible amount of energy is needed. | ||
+ | As it turns out even when the complete solar energy that hits Venus is converted to chemical energy this endeavor would take a very very long time - {{todo|show the math}}. Also for removal of just the sulfuric acid and SO<sub>3</sub> there necessary timescales would be so big that it is questionable whether when the process is finished humans will still "use" biological bodies that depend on earth like conditions. | ||
+ | But "we" might just want to make a "garden" for other earth life. | ||
+ | |||
+ | === Cooling by shading? === | ||
+ | |||
+ | Another thing easy to set up is thin light and highly reflective floating mirrors covering the whole surface (or at least dayside) of the planet. | ||
+ | Relative to the mass of the whole atmosphere the mass of a mirror layer is vanishing. It could be produced and employed rather quickly. | ||
+ | The following cooling of the atmosphere might take some time {{todo|do the math}}. | ||
+ | By waiting long enough all but the nitrogen part of the atmosphere could be frozen to dry ice (assuming no chemical atmosphere conversion runs in parallel). (Maybe not so useful) | ||
+ | |||
+ | It may be possible to speed up cooling by setting up a planetary scale [[Diamondoid heat pump system|heat pump system]] creating hot spots with temperatures >>500°C (cheap silicon carbide can handle those temperatures) that can more effectively radiate away the heat. [[Thermal metamaterial]]s can help. | ||
+ | |||
+ | See: Josh Storrs Hall's concept of ultra-lightweight [[stratospheric mirror airships]] <br> | ||
+ | {{todo|find and link video where he presents that idea (for application on earth)}} | ||
+ | |||
+ | === Peculiarities of hypothetical terraforming result === | ||
+ | |||
+ | What would a Venus with its over 100 earth day long day (that probably can't be changed) and higher solar constant look like if all the carbon where bound and most of the oxygen where trapped into the soil or water? Would there be lots of poisonous heavy metals around? | ||
+ | Considering Venus is so flat (it lacks mountains because it has no plate tectonics.) Would there be any dry land left? | ||
+ | How high would the waves get with the extreme winds at the day night borders? What about water vapor clouds, lack of magnetosphere ...? | ||
+ | |||
+ | Further SciFi ideas that could be investigated just for fun: | ||
+ | * packing a terraformed Venus in a ring of infinitesimal bearings for a 24h day night cycle | ||
+ | * packing Venus in a giant superconducting ring to create an artificial magnetosphere (to keep the scarce hydrogen from getting away) | ||
+ | * hypothetical terra-changing experiment. | ||
+ | |||
+ | == Increasing the activation energy barrier for global disaster == | ||
+ | |||
+ | [[File:Pallasite_slice-of-Esquel-meteorite.jpg|450px|thumb|right|Shown here is how the material at the matle core boundary of Venus (and other rocky planets like earth) probably looks like. Pictured is a piece of a meteorite from what would have been the core of one or more ancient protoplanets between mars and jupiter that got smashed up again later in the evolution of the solar system. The biggest protoplanet reaining to this day is the dwarf planet ([[Ceres]]). Most of the material between Mars and Jupiter is spread out in shatters because of Jupiters strong gravitational disturbances. It forms our solar systems main asteroid belt instead of a single compact planet.]] | ||
+ | |||
+ | Given very advanced mining technology iron from the mantle core boundary of Venus could be used to safely bind excessive oxygen and convert chemical to safer gravitational energy. | ||
+ | |||
+ | By binding the excess oxygen from the CO<sub>2</sub> splitting process to unoxidized iron form Venus' core one can turn the moderate chemical activation energy that prevents a global diamond oxygen firestorm into a much higher gravitative barrier where first the crust of the planet needs to be broken such that the heavy iron sinks (giant but very slow energy release due to very high viscosity) and re-releases the oxygen before the oxygen could burn with the carbon. | ||
+ | {{todo|section is redundant - merge with corresponding parts of the article}} | ||
+ | |||
+ | == Comparison to the situation on earth == | ||
+ | |||
+ | There is an enormous amount of energy stored in the earth atmosphere biosphere system (oxidizing agent oxygen and reducing agents hydrocarbons. (How much exactly?) | ||
+ | This shows that even situations far from equilibrium can be quite stable and safe for geological time-scales. | ||
+ | (Beside activation energy other factors play important roles - Extinguishing systems?) | ||
+ | Could there be sufficient energy input (e.g. catastrophic asteroid impact) that would lead to a mostly complete reaction to carbon dioxide and water and leave the earth in a Venus like state? | ||
+ | |||
+ | = Further notes = | ||
+ | |||
+ | * The high gravity of Venus (almost identical to earths) is a big challenge. | ||
+ | * Methods for hydrogen free high thrust propulsion is are of interest. | ||
+ | |||
+ | = "Soaking" up all of the scarce hydrogen = | ||
+ | |||
+ | Once building activities on Venus grow beyond a certain really big scale <br> | ||
+ | The scarcity of hydrogen on Venus may become a limiting factor. | ||
+ | |||
+ | The typically [[low hydrogen content]] of [[gemstone metamaterial products]] helps in delaying <br> | ||
+ | the point where one runs out of hydrogen as a resource by a lot.<br> | ||
+ | If the products being made would mainly be hyrocarbon plastics (which are very hydrogen rich) then <br> | ||
+ | one would run out of hydrogen much much sooner. | ||
+ | |||
+ | Maybe soaking up all the scarce hydrogen in the atmosphere from high up acid rain or acid mist (aka Venus' clouds) could <br> | ||
+ | eventually clear up the "eternal" cloud layer of Venus in a much shorter timescale than <br> | ||
+ | any significant changes in the atmospheres total pressure could be made (which is many millennia even at "full tilt"). <br> | ||
+ | {{todo|Estimate how long it would take to filter out a good part of all of the hydrogen that is present in Venus' atmosphere. Given only non-space solar power.}} | ||
+ | |||
+ | If the plan is to deliberately "soak" up all the hydrogen then it's scarcity <br> | ||
+ | helps in that the amount of mass is low and not helps in that concentrations are falling. <br> | ||
+ | Especially if a threshold is reached where the acid rain that naturally concentrates the hydrogen stops falling. | ||
+ | |||
+ | Artificially dried up Venus skies might clear up such that the ground becomes occasionally vislible from space (like on Earth). <br> | ||
+ | There might be more infrared radiative cooling at the night side (guessing) but <br> | ||
+ | the sun hitting the already very hot ground directly on the day side might not change it's temperature all that much perceptually. <br> | ||
+ | High ground temperatures are caused a good deal due to adiabatic compression (and winds equilibrating day and night side). <br> | ||
+ | Maybe there could be slight increase in ground wind-speeds (wild guessing). | ||
+ | |||
+ | A cleared up cloud layer would mainly help in optical inspection of the ground from the sky or space. <br> | ||
+ | And be aesthetically pleasing for the human eye. | ||
+ | |||
+ | Clouds are probably mostly made mostly from hydrogen containing compounds. <br> | ||
+ | Hydrogen bonds are what's giving these compounds a low condensation point. <br> | ||
+ | Beside that there may be some dry dust in the atmosphere. <br> | ||
+ | But judging from earth this does not obstruct an optical view to the ground. | ||
+ | |||
+ | = Related = | ||
+ | |||
+ | * [[Gas giant atmospheres]] | ||
+ | * Handling of molten iron and very high temperatures - [[refractory material]]s | ||
+ | * [[Mars]] | ||
+ | * [[Mercury (planet)]] | ||
+ | |||
+ | = External Links = | ||
+ | |||
+ | * [https://web.archive.org/web/20220513022542/http://www.shadetreephysics.com/vel/1918vpt.htm temperature-height & pressure-height graphs of the Venusian atmosphere (archive)] | ||
+ | * [http://www.shadetreephysics.com/vel/1918vpt.htm temperature-height & pressure-height graphs of the Venusian atmosphere] | ||
+ | * Wikipedia: [http://en.wikipedia.org/wiki/Sulfur_trioxide Sulfur trioxide (liquid)] | ||
+ | * Wikipedia: [https://en.wikipedia.org/wiki/Lapse_rate Atmospheric lapse rate] |
Latest revision as of 10:17, 18 March 2024
More general: Colonisation of the solar system
If one does not insist to go down to the solid surface (0m 500°C 90bar)
Venus is actually a nice place for humans to colonize (52.5km 37°C 660mbar).
And it might be rather easy with nanofactories since Venus' atmosphere is is essentially an ocean of building material bathed in intense sunlight.
Venus is pretty devoid of Hydrogen (20ppm Water that amounts to about 20kg per cubic kilometer at 1bar level) which is essential for APM technology. Luckily there's this nice sulfuric acid rain which concentrates the hydrogen for us. We get a bonus of a high deuterium concentration - whatever it may be used for. Also diamond crystolecules have much less hydrogen passivated surface than the hydrocarbon chains in current day plastics. Much much less than one hydrogen atom per carbon atom.
Breathable air and nitrogen are effective lifting gasses in the dense carbon dioxide atmosphere and can be directly drawn from the atmosphere. Comparison of molecular weights: nitrogen 28, oxygen 32, carbon dioxide 44
Contents
Why is Venus' surface so difficult to explore?
- High temperature (~500°C)? No. One can isolate against that.
- High pressure (~90atm)? No. One can build pressure resistant capsules. The increased weight is not nice for spaceflight though.
- Lack of an energy source at ground level? Yes,yes,yes!
That's the one single most difficult problem hardest to crack.
A power source would allows for active cooling and long duration mission. - High gravity? Yes in case of a sample return mission. It's as bad as with Earth. That means it's really bad.
This is generally misunderstood as Venus' surface conditions (~500°C,~90atm) seems so daunting and attention grabbing.
But they actually are not the core problem. The problem is the lack of a long duration power source for active cooling.
High temperature electronics are not a good alternative unless one is fine with going back to Venera like single pixel scanning camera crudeness (amazing for the time back then).
Atmosphere
The atmosphere is not your foe its your friend. She ..
- .. provides building material in optimal standardized form
- .. makes the scarce hydrogen better available (sulfuric acid rain is a natural hydrogen concentrator process)
- .. provides radiation protection (except UV)
- .. provides protection against micrometeorites
- .. makes street infrastructure unnecessary
- .. provides an environment with nearly constant temperature
- .. to a degree protects from volcanism on the ground
- .. reduces the day night cycle to a reasonable length. (super-rotation)
The chemically neutral to reducing character of the atmosphere may allow to make use of materials that in an atmosphere containing oxygen quickly oxidize extending the range of usable base materials for higher level metamaterials. This way passivation with locally scarce hydrogen may be avoidable altogether. See: Flavors of diamondoid gem gum technology
Interesting facts
Results from balloon missions
The Vega probes placed each a balloon in the atmosphere of Venus. They drifted in a height of around 53km 46 and 60 hours long. In this time they covered a distance of about a third of the circumference of Venus an measured wind speed, temperature, pressure and cloud density. Thereby more storm and air current activity was observed than anticipated. Also a sudden change in flight height of about one to three kilometer was detected. (Source: de.wikipedia)
(TODO: Check the actual data - what means a sudden change in flight height here. What means sudden sudden here?)
High up in the atmosphere strong wind-speed gradients like the ones on the surface of earth are probably not to expect.
How much is known about the scales of the turbulences in the venusian atmosphere?
Why Venus is the way she is
The following is from gathered crumbs of info. It totally needs references.
Take it with a grain of salt for now.
There are a number of (partially circular) interrelationships that made Venus what it is today and keep it that way.
In the following list: Read the backward arrows "<=" as "is/was caused by".
Please take these simplifications with a grain of salt!
- massive CO2 atmosphere <= CO2 not bound in the ground as CaCO3 <= no water (H2O) on the planet (to wash it out and bind it) <= no hydrogen on/in the planet
- no significant mountains on Venus <= no plate tectonics <= no "lubricating" water (H2O) in the planets crust AND a very thick and cool planetary crust
- a thick and cool crust <= fast cooling of the planets interior <= no tectonics AND no "lubricating" water in the crust
- no "lubricating" water in the crust <= no hydrogen in/on Venus <= solar wind blowing away the hydrogen <= no magnetic field <= cool core <= fast cooling
- long day <= near to sun and no moon (?) and no plate tectonics (??)
- ... <= red hot glowing surface <= ...
(TODO: Improve this list (less overlaps) and make an image with arrows for the interrelationships.)
Colonisation - (conceptual)
The objective is to create a nice place for humans to live.
Basic housing
First a nanofactory (e.g. of the size of a sugar cube) is sent to Venus. There a durable balloon is created with a semi-transparent semi-reflective diamond solar foil on top that leaves through enough light for plants to grow. The balloon further needs an atmospheric converter unit (air using micro ships) that has a number of functions. It creates among other thing breathable air. The balloon must be inflated while being built to be kept afloat at all times.
Creation of soil for plants
Creating earth like soil with humic substances such that plants can grow in a natural way takes a lot longer then the employment of such a balloon. One could start with hydroponic cultures and compose the dead plants. At that time humans may be present or may not. A small piece of earth soil may be usable to introduce a rich set of microorganisms. (Each balloon can be an experimental perfectly isolated ecosystem)
It should be rather easy to design small balloons but to create an earth like landscape a bigger free area and some soil depth is probably desired. For an average soil depth of half a meter a balloon with around one kilometer height is needed to compensate for the weight. (Put that in relation to the floating height of ~ 53km for visualization)
At this size one needs to consider the wind speed gradient in the atmosphere which is around 10m/s per 1km. One doesn't want the balloon to start rolling like a barrel. This may be a difficult problem.
Air conditioning
Although 37°C with 660mbar air pressure is endurable for most humans it's not pleasant. Can a leightweight balloon hull provide enough thermal isolation to make a more pleasurable environment of e.g. 22°C at higher pressure?
There are several options for how to handle the three parameters pressure height and temperature when the outside weather changes abruptly.
Atmospheric converter unit for Venus
- filters nitrogen from the atmosphere
- captures sulfuric acid rain which concentrates the rare hydrogen [Todo: at which heights is sulfuric acid rain present]
- sulfuric acid → hydrogen + sulfur dioxide
- carbon dioxide + hydrogen → ethyne + oxygen
Because of the reproduction hexagon it may make sense to keep it separate from the nanofactory. Related: Mobile carbon dioxide collector balloon.
Possible threats
Lightning
Some kind of lightning arrester system needs to be devised.
Active aversion of especially bad weather may or may not a viable strategy depending
on wind speeds and mobility of the aerial vehicle of choice.
Airplanes on Earth manage to deal pretty good with occasionally being hit by lightning strikes.
Granted they always try to avoid bad weather.
There should be quite some info on that for investigating further.
Strong downwards facing winds
How much down sucking winds are there on Venus excactly?
If there are too strong downwinds that cannot reliably be avoided
that reach all the way down to extreme heat and pressure levels then aerial colonization might not be viable.
Likely no anti-cyclones
Given the global super-rotation of the atmosphere there are like no hidden big scale anticyclones.
Even if there were anticyclones, these are typically larger and much less vigorous than cyclones since
they have a negative feedback cycle in energy release rather than a positive one.
The big red spot on Jupiter is an anticyclone where there are no clouds in the upper layers of the atmosphere and one can see deep inside Jupiters guts.
Adiabatic compression in big air down-swirls (aka anticyclones):
air heats up => clouds and mist evaporate which takes up a lot of energy (negative feedback) => Clear skies slow wind-speeds over wide areas.
Adiabatic expansion in big air up-swirls (aka cyclones):
air cools down => and humid air condensates into clouds which releases a lot of energy (positive feedback) intensified by percipitation => intense thunderstorms - more local
Measured sudden down-drafts (to worry about?)
The balloon missions on Venus registered significant and sudden drops in altitude. Which sounds a bit worrying.
(wiki-TODO: investigate sudden ballon altitude drops in venera mission(s) further)
Different effect on different means for staying aloft
Strong down-winds would be especially a problem for Balloons or Blip/Zeppelin like airships with big wind-attack-area to mass ratios that have thus
rather limited maximal speeds relative to the air.
Strong down-winds would be less of a problem for permanently flying airplanes.
But truly permanently flying airplanes require very advanced technology that is capable of active in flight self repair.
Ideally with resources directly tapped from the atmosphere.
Wing gusts (danger of toppling over)
Since there are no obstacles high up in the atmosphere on a small scale differences in relative airspeed should be negligible.
On a bigger scale this might become an issue [data needed].
Like a very big balloon might strongly want to start to roll over upside down.
Fires
Building a thin walled carbon balloon filled with oxygen is basically asking for fire. (On an other note when a hole is burnt into the hull penetrating carbon dioxide will probably quickly extinquish any fire) To mend this problem one can compartmentalize bigger balloons. Only the bottom few meters get filled with breathable air. A transparent ceiling foil material separates off the majority of the balloons volume. This part gets filled with nitrogen and is uninhabited "empty" space. A nice side effect is slightly more buoyancy lift.
An other approach is to use silicon carbide as a building material which may self protect against fire by building glass. For silicon one would need to mine the surface though. Releasing excess oxygen to the atmosphere might get dangerous after a very long period colonization activity (more than centuries). A global firestorm could start making Venus rivaling/exceeding? the sun in brightness for a brief moment (this is some phantastic dystopic SciFi just for entertainment). To get rid of the excess oxygen from the silicates one can use iron as reducing agent. The place where one can get unoxidized iron for sure is the planets core. (See: deep drilling)
A closed material "cycle" can be conceived that protects against fire even if atmosphere gets really crowded.
- carbon dioxide + silicate stone → silicon carbide + oxygen
- oxygen + iron → iron oxides
- sulfur dioxide + iron → pyrite + iron oxides
- sulfuric acid + oxygen → hydrogen + sulfur dioxide
(Energy gets stored in gravity - since heavy things can't fall through (non-molten) light things there's a perfectly safe activation energy barrier)
Outlook on a very long term - Template:SciFi warning
Since with advanced nanofactories exponential growth is easy it comes naturally to think about Terraforming. We'll discuss later whether a terraforming attempt is desirable and whether it makes sense.
The main reason why the venusian atmosphere is so hot at it's bottom is not because Venus is so near to the Sun or because there is a runaway green house effect. It is so hot because it is so massive. Adiabatic compression of a gas heats it up. When a volume of gass high up in the atmosphere falls back to the ground it gets adiabatically compressed and heated.
Binding excessive elements of the atmosphere
To reduce the mass of Venus' atmosphere the most part of the carbon dioxide all the sulfur trioxide and a good part of the nitrogen would need to be bound with some kind of Carbon dioxide collectors placed in the upper layers of the Venusian atmosphere where the conditions are benign. The carbon dioxide needs to be bound in a chemically very stable form (dropped down or kept floating ?) such that in a later state of the atmosphere with free oxygen powerful ignition sources (like e.g. frequent and powerful strokes of lightning and bigger things like meteor impacts) cannot cause an epic global firestorm putting all the carbon back into the atmosphere. Like the energy rich but sufficiently metastable bisophere on earth.
To get rid of all the carbon bound in the carbon dioxide it could be combined with silicon taken from the silicon dioxide (quartz) of the planets crust. This would create the useful building material silicon carbide (moissanite) which is (in big chunks) self protecting against fire. When ignited at all (which is very hard to do) it forms a molten glass layer preventing further oxygen from reacting with more carbon and silicon inside.
Doing that beside the oxygen from the carbon dioxide one also gets oxygen from silicon dioxide. Each source on its own is far too much for earth like oxygen levels. Obviously it wouldn't be smart to create a super-dense (too dense for humans and incredible dangerous) oxygen atmosphere. To get rid of all that excess oxygen a giant amount of some reducing element is needed. Ideally the oxygen would be bound to hydrogen but there is barely any hydrogen on Venus. Most of it was blown away by the solar wind. So hydrogen would need to be delivered from space. Which sounds difficult. Probably gentle methods should be used not a destructive methods like bombardment with ice meteors which seem to have no benefits. A reducing element that is certainly present in sufficient amounts on Venus is iron. The oxygen can be bound in the useful iron mineral building materials hematite and magnetite. Big amounts of metallic non-reduced iron can be found in the planets mantle and outer core. Advanced atomically precise technology (gem-gum technology) may make mining in such extreme pressure and temperature environments possible. But this goes near the very limits of the physical possible!
The iron can also be used to bind sulfur from sulfur trioxide (which is another gas that needs to be bound into a solid state) into the mineral pyrite. For the excess nitrogen there are plenty of options to bind it safely.
While setting up the process (exponential production of carbon dioxide collectors) is straightforward for Venus' atmosphere for the then following terraforming process an incredible amount of energy is needed. As it turns out even when the complete solar energy that hits Venus is converted to chemical energy this endeavor would take a very very long time - (TODO: show the math). Also for removal of just the sulfuric acid and SO3 there necessary timescales would be so big that it is questionable whether when the process is finished humans will still "use" biological bodies that depend on earth like conditions. But "we" might just want to make a "garden" for other earth life.
Cooling by shading?
Another thing easy to set up is thin light and highly reflective floating mirrors covering the whole surface (or at least dayside) of the planet. Relative to the mass of the whole atmosphere the mass of a mirror layer is vanishing. It could be produced and employed rather quickly. The following cooling of the atmosphere might take some time (TODO: do the math). By waiting long enough all but the nitrogen part of the atmosphere could be frozen to dry ice (assuming no chemical atmosphere conversion runs in parallel). (Maybe not so useful)
It may be possible to speed up cooling by setting up a planetary scale heat pump system creating hot spots with temperatures >>500°C (cheap silicon carbide can handle those temperatures) that can more effectively radiate away the heat. Thermal metamaterials can help.
See: Josh Storrs Hall's concept of ultra-lightweight stratospheric mirror airships
(TODO: find and link video where he presents that idea (for application on earth))
Peculiarities of hypothetical terraforming result
What would a Venus with its over 100 earth day long day (that probably can't be changed) and higher solar constant look like if all the carbon where bound and most of the oxygen where trapped into the soil or water? Would there be lots of poisonous heavy metals around? Considering Venus is so flat (it lacks mountains because it has no plate tectonics.) Would there be any dry land left? How high would the waves get with the extreme winds at the day night borders? What about water vapor clouds, lack of magnetosphere ...?
Further SciFi ideas that could be investigated just for fun:
- packing a terraformed Venus in a ring of infinitesimal bearings for a 24h day night cycle
- packing Venus in a giant superconducting ring to create an artificial magnetosphere (to keep the scarce hydrogen from getting away)
- hypothetical terra-changing experiment.
Increasing the activation energy barrier for global disaster
Given very advanced mining technology iron from the mantle core boundary of Venus could be used to safely bind excessive oxygen and convert chemical to safer gravitational energy.
By binding the excess oxygen from the CO2 splitting process to unoxidized iron form Venus' core one can turn the moderate chemical activation energy that prevents a global diamond oxygen firestorm into a much higher gravitative barrier where first the crust of the planet needs to be broken such that the heavy iron sinks (giant but very slow energy release due to very high viscosity) and re-releases the oxygen before the oxygen could burn with the carbon. (TODO: section is redundant - merge with corresponding parts of the article)
Comparison to the situation on earth
There is an enormous amount of energy stored in the earth atmosphere biosphere system (oxidizing agent oxygen and reducing agents hydrocarbons. (How much exactly?) This shows that even situations far from equilibrium can be quite stable and safe for geological time-scales. (Beside activation energy other factors play important roles - Extinguishing systems?) Could there be sufficient energy input (e.g. catastrophic asteroid impact) that would lead to a mostly complete reaction to carbon dioxide and water and leave the earth in a Venus like state?
Further notes
- The high gravity of Venus (almost identical to earths) is a big challenge.
- Methods for hydrogen free high thrust propulsion is are of interest.
"Soaking" up all of the scarce hydrogen
Once building activities on Venus grow beyond a certain really big scale
The scarcity of hydrogen on Venus may become a limiting factor.
The typically low hydrogen content of gemstone metamaterial products helps in delaying
the point where one runs out of hydrogen as a resource by a lot.
If the products being made would mainly be hyrocarbon plastics (which are very hydrogen rich) then
one would run out of hydrogen much much sooner.
Maybe soaking up all the scarce hydrogen in the atmosphere from high up acid rain or acid mist (aka Venus' clouds) could
eventually clear up the "eternal" cloud layer of Venus in a much shorter timescale than
any significant changes in the atmospheres total pressure could be made (which is many millennia even at "full tilt").
(TODO: Estimate how long it would take to filter out a good part of all of the hydrogen that is present in Venus' atmosphere. Given only non-space solar power.)
If the plan is to deliberately "soak" up all the hydrogen then it's scarcity
helps in that the amount of mass is low and not helps in that concentrations are falling.
Especially if a threshold is reached where the acid rain that naturally concentrates the hydrogen stops falling.
Artificially dried up Venus skies might clear up such that the ground becomes occasionally vislible from space (like on Earth).
There might be more infrared radiative cooling at the night side (guessing) but
the sun hitting the already very hot ground directly on the day side might not change it's temperature all that much perceptually.
High ground temperatures are caused a good deal due to adiabatic compression (and winds equilibrating day and night side).
Maybe there could be slight increase in ground wind-speeds (wild guessing).
A cleared up cloud layer would mainly help in optical inspection of the ground from the sky or space.
And be aesthetically pleasing for the human eye.
Clouds are probably mostly made mostly from hydrogen containing compounds.
Hydrogen bonds are what's giving these compounds a low condensation point.
Beside that there may be some dry dust in the atmosphere.
But judging from earth this does not obstruct an optical view to the ground.
Related
- Gas giant atmospheres
- Handling of molten iron and very high temperatures - refractory materials
- Mars
- Mercury (planet)