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[[Nanofactory|Nanofactories]] will allow us to make very cheap clothing anytime anywhere (even just [[living from air and sun|from air-molecules and sunlight]]) | [[Nanofactory|Nanofactories]] will allow us to make very cheap clothing anytime anywhere (even just [[living from air and sun|from air-molecules and sunlight]]) | ||
− | + | This type of clothing will be able to give us more comfort at any place on earth than any entire house can give us today (2014..2015). | |
Death from freezing will largely be a thing of the past. | Death from freezing will largely be a thing of the past. |
Revision as of 08:08, 24 April 2015
Nanofactories will allow us to make very cheap clothing anytime anywhere (even just from air-molecules and sunlight) This type of clothing will be able to give us more comfort at any place on earth than any entire house can give us today (2014..2015).
Death from freezing will largely be a thing of the past.
Contents
comfortable everyday tracksuits
With advanced atomically precise technology clothing can become much more comfortable. First and foremost thermal regulation becomes a thing one just don't have to care about anymore. One can keep the same clothes independent of the whether. This can be archived through advanced thermal regulation as described further below.
With more advanced metamaterials which can emulate elasticity and actively change surface area clothing can be made sloppy or skin tight or both on different body parts. A simple lightweight hood with transparent visor that behaves like textile when unused and self stiffens to a helmet like state when employed can be used to protect the face.
An inflatable mattress for comfortably cushioning sitting or lying that is very tiny in its folded up state can be included. You only need to take care about water and food for the most extreme trips through the land.
Means for washing ones body could be integrated too. This would especially make sense in life supporting protection suits for deadly environments.
Temperature regulation
A skin covering material that is normally thin with thermal conductivity near the one of diamond can blow up a tiny bit in volume and rise it's thermal isolation to levels that suffice for every possible climate one can encounter on earth including -90°C and extreme winds on the polar caps. Its basically a metamaterial that combines the thermal isolation of aerogels (wikipedia) with springiness that prevents it from being crushed permanently and some actuating microcomponents for adjustment.
Additionally one can use a heat harvesting trick similar to the one penguins use. Turning the sun facing area black (in the visible spectrum that lies way above thermal equilibrium) and the area in the shadow white this maximizes optical absorption while minimizing thermal emission. (See: Kirchhoff's law of thermal radiation, Stefan–Boltzmann law, emissivity and absorptivity )
In hot climate the solar energy can directly be used for cooling with e.g. diamondoid solar cells and diamondoid heat pump systems. Physical movement can be tapped as a power source too but depending on the ambient temperature it might heat you up more than it cools you down.
There are limits for temperature regulation. In rather unnatural very hot and dark situations like in a deep mine life supporting protection suits that use energy from storage cells to actively cool the body become necessary.
A thin second skin
Proposed in Josh Halls Book Nanofuture. If thermal isolation is not too much of an issue suits can be made extremely thin without risk of rupture and thus maybe barely noticeable. This would protect against well against mosquitoes cuts with kitchen knives and aggressive chemicals like acids. This works because diamondoid metamaterials can have very high tensile strengths and diamond and quartz are resilient against most aggressive chemicals.
life supporting protection suits
Suits for extreme environments like space and deep-sea where no or too little oxygen is present need life support systems which add significant volume and mass. This won't make them exorbitant more expensive than simple AP tracksuits. Only patents and proprietary secrecy may do so when those suits first emerge.
space suits
Space suits can use the same fabric as advanced basic atomically precise manufactured tracksuits just fortified to counter (one full nice atmosphere of) internal air pressure and external bombardment with micrometeorites. Perfect shielding against radiation is and will always be physically impossible with a moderately thick suit made from light elements. [todo: check how effective would be the massive inclusion use of lead atoms in a space radiation environment]
indoor space suits
Cool would be something like a weightless airspace movement gear.
Suppose you are somewhere in outer space in a big sports hall located far away from the walls and not moving relative to them at all. You're helplessly stuck there. Its known that air-swimming doesn't work effectively and sucking air in from the front and blowing it back with your lung probably won't be very effective either. You can change our orientation (the direction in which you look) easily by using the cat body rotation trick but that's about all. If you're spinning fast you can't get rid of that rotation.
For mobility in such a situation small round air accelerator plates stiffly mounted to key locations of your body (e.g. at the shoulders hips and feet) would probably work well especially to stop spin. They would only pop up when needed. A wrist mounted winch with a gripper that can be shot towards railings would be more effective for movement towards a wall. The winch cable should be a smart material that breaks in a controlled way when side-ward forces are detected - no decapitation accidents !!
deep sea suits
With diamond as building material deep sea suits will become less bulky. Maybe each finger can be encapsulated separately. They will still be fairly massive because of the immense pressures. Cable bound telepresence is and will be a good way to work down there.
Telepresence
If the suit is sufficiently equipped with motion sensors all the movements of the wearer can be detected. This allows one to use the suit as input device for the remote control of a humanoid avatar. This avatar can (given sufficient bandwidth) be located on the other side of the planet. Out in space (e.g. earth-moon, interplanetary, asteroid belt, ...) the time lag due to the limited speed of light is prohibitive.
In the other direction the avatar can send back diverse kinds of tactile impressions (like pressure friction temperature and others) back to the wearer via the suite. Additional actors in the suit (normally used for adjusting whether the clothes should behave sloppy or skintight) can apply that pressure to the skin at fast changing rates with high spacial resolution. The suite now essentially became not only a remote controller but an immersive remote reality system. In short this is remote sensing for telepresence. It might be a good idea to physically limit the force that the suite can apply to the wearer instead of limiting it by software to prevent gruesome accidents.
It shouldn't come as a surprise that the humanoid avatar is somewhat similar to the suite. The main difference is that the inside is not occupied by a human but instead is inflated with air or uncrushable aerogel. Additional weight might be needed. It can be added either by adding some common low density stuff like water or specialized weight delivering microcomponents which carry e.g. some insoluble diamondoid lead mineral.
Note that the "Fabric" only needs to change its area and not its general shape - that would be utility fog which would be more general purpose than needed - see:Self limitation for safety.
Scaling telepresence ...
Related
- AP clothing e.g. shoes