Difference between revisions of "Abundant element"
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* production of microchips - metal and poison free | * production of microchips - metal and poison free | ||
* no scarce alloy metals (e.g. Mo,Cr) for steel in cars are needed | * no scarce alloy metals (e.g. Mo,Cr) for steel in cars are needed | ||
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| + | A huge part of the current (2014) focus of material science is on metals | ||
| + | (maybe because of their relatively high count in the periodic table and their interesting properties). | ||
| + | Will this knowledge find only limited applicatbility in advanced systems of AP technology? | ||
| + | In any case having knowledge is always a good thing. | ||
Revision as of 16:49, 4 June 2014
Contents
Ground
The most common elements on the earths surface are the ones found in rock forming minerals: Most contain silicon as the main ingredient.
Wikipedia: the abundance of elements in earths crust
Atmosphere
The elements easiest to attain are not equal to the most abundant ones. E.g. Nitrogen is easier to get than Silicon or Titan since it can be drawn from the atmosphere. Given a bit of patience carbon can be drawn directly from the atmosphere too. Carbon already an infrastructure for delivery too: gas pipes. Read the "air as a resource" page for further information.
Ocean
Salts in the sea (alkali metals and halogenides) are a huge reservoir of potential building material but unfortunately with view exceptions like
- Periclase MgO
- Fluorite CaF2,
- Sellait MgF2)
- Magnesium Diboride MgB2 (superconductor, health hazard)
- Calcium Hexaboride CaB6 (barely dissolvable but irritating)
Simple compounds of those elements make no good building materials. They tend to strongly dissolve in water (that was the reason why they where in there to begin with) and are brittle. More complex compounds are often more water stable but also rather weak.
Scarce elements
With AP Technology many if not all scarce elements can be replaced by a few abundant ones
- (augmented) carbon nanotubes can replace copper cables and soldering tin
- artificial motor-muscles can replace electrical motors that use rare earth elements
- interferometric displays or AP quantum dots can replace indium in screens
- chemomechanical converters can replace metal using rechargable batteries
- production of microchips - metal and poison free
- no scarce alloy metals (e.g. Mo,Cr) for steel in cars are needed
A huge part of the current (2014) focus of material science is on metals (maybe because of their relatively high count in the periodic table and their interesting properties). Will this knowledge find only limited applicatbility in advanced systems of AP technology? In any case having knowledge is always a good thing.
