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− | [[File:energy-management-complete.png|512px|thumb|right|'''todo''' upload scalable svg version]]
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| + | '''Advanced [[mechanosynthesis]] can provide today's missing link of efficient chemomechanical conversion'''. This makes long term storage of huge amounts of energy possible. Additionally chemical energy is easier to transport than electrical energy - even today (oil tankers). |
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− | == State of the art == | + | == Limits == |
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− | Today (2015) humankind still mainly uses fossile fuel for energy.
| + | Unlike other performance specs like transmittable power density. |
− | In europe regenerative energy sources are on the rise and already provide some noticeable fraction of the energy.
| + | The energy density of chemical energy storage is (with gasoline and explosives as good examples) pretty much at it's limits with our current (2016) crude technology. |
− | Regenerative energy faces several problems though.
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− | The main one is that current non atomically precise technology isn't capable of storing massive amounts of energy efficiently and durably at any location.
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− | Beside that for wind turbine generators currently big amounts of rare earth elements from mines in china are needed.
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− | Single- and poly-crystalline solar cells made from the abundant element silicon are still energy intensive in production and need aggressive chemical agents.
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− | Organic cells are in development which promise to reduce mass and production cost but they use the super scarce element indium in one of their electrodes and will extend the environmental plastic pollution problem if extensively deployed.
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− | == Energy management of nature and human (today and tomorrow) ==
| + | Advanced atomically precise technology allows now forms of chemical energy storage that at the cost of slightly lower energy density are far safer and allow energy conversion efficiencies very near 100%. |
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− | Lets look at how energy is managed by nature how humanity does it today and what would be a desirable state we want to move our energy management to.
| + | For energy densities higher than chemical only nuclear is possible. |
| + | How and in how far advanced atomically precise technology may enable us using some nuclear physics as a bidirectional battery is very unclear at this moment (2016). See [[APM and nuclear technology]] for related highly speculative thoughts. |
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− | == Nature == | + | == Related == |
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− | All energy originally stems from nuclear sources either the sun or radioactive decay in the earths core.
| + | * For more details see: [[Global scale energy management]] |
− | The suns first converts nuclear to thermal energy (a thermonuclear conversion) and then the termal energy to photonic energy (a photothermal conversion - via Stefan Boltzmanns radiation law). On earth this photonic energy gets either captured by photosynthesis (a photochemical energy conversion - with a little hidden electrical intermediate step) or it gets converted back to heat again (again photothermal). This lower level heat may drive winds via pressure gradients (a thermomechanical conversion) and vaporize water (partially a thermoentropic conversion). Wind convections may then lift up water vapor and water droplets in clouds (a mechanogravitative conversion). When the water finally rains down and flows down rivers it is converted back to thermal energy that is so much devalutaed that it becomes practically unusable. At the end it is becomes irradiated as infrared light at night into the three kelvin cold space.
| + | * [[Energy storage cell]] |
− | | + | * [[Chemomechanical converters]] |
− | A tiny bit of the chemical energy originally captured from plants (mentioned before) get converted to mechanical energy my the muscles of animals.
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− | == Human (today) ==
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− | Most of the energy we currently use is drawn from ancient hydrocarbon deposits of coal oil or gas that are located not very deep below the ground (if viewed relative to the total thickness of the earths crust). It is commonly assumed that this stuff was accumulated in the carbonifeous period of earths history.
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− | It is thought that the evolutionary invention of lignin as structural support for land plants led to major pollution of the environment with massive amounts of at that time undecomposable lignin. This only went on until the later evolutionary invention of lignin eating fungi.
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− | There wheren't any more hydrocarbons produced ever since and there won't be produced any time in the future. ['''todo''': add link]
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− | Starting from this source we create thermal energy by burning it (a '''very stupid''' chemothermal conversion where valuable free energy is devaluated into the irrecoverable fraction of thermal energy - bound energy) we then convert this thermal energy to mechanical energy via heat engines (a '''reversible''' thermomechanical conversion) where we are limited to carnough efficiency because of the stupid burning step we did before.
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− | We need to convert mechanical energy back and forth to electrical energy to transport it. While this electomechanical conversion works pretty well electrical energy isn't nearly as efficient transportable as chemical energy and needs large amounts of metals like rare copper and currently abundant but not cleanly producible aluminum. Furthermore and most problematically purely electrical storage devices like capacitors and inductors can't store large amounts of energy (except superconductor coils maybe - that are dirty to produce and use scarce elements and too expensive). There is the newly growing option of massive electochemical storage devices (that is rechargeable batteries) but they have limited efficiency. More importantly they use lithium that is mostly coming from a single salt sea in america. We might want to save that lithium for future fusion instead of diluting it in landfills and pollution of the environment with this uncommon alkali metal.
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− | Impounding reservoirs (using electromechanic and mechaogravitative energy conversion) where a good solution up till now but with the growing amount of regenerative energy they are starting to hit their limits and become uneconomic to use. New ones can't be made because of the massive destruction of land.
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− | === Sidenote on hydrocarbons ===
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− | ...
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− | == Human (tomorrow) ==
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− | ...
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Unlike other performance specs like transmittable power density.
The energy density of chemical energy storage is (with gasoline and explosives as good examples) pretty much at it's limits with our current (2016) crude technology.
Advanced atomically precise technology allows now forms of chemical energy storage that at the cost of slightly lower energy density are far safer and allow energy conversion efficiencies very near 100%.
For energy densities higher than chemical only nuclear is possible.
How and in how far advanced atomically precise technology may enable us using some nuclear physics as a bidirectional battery is very unclear at this moment (2016). See APM and nuclear technology for related highly speculative thoughts.