Difference between revisions of "Titanium"
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− | == | + | {{Element | |
− | + | name=Titanium | | |
− | + | symbol=Ti | | |
− | + | available=abundant | | |
− | + | need= | | |
− | + | number=22 | | |
+ | mass=47.867 | | ||
+ | group=4 | | ||
+ | period=4 | | ||
+ | phase=Solid | | ||
+ | series=Transition Metals | | ||
+ | density=4.506 g/cm3 | | ||
+ | melts=1941K,<BR/>1668°C,<BR/>3034°F | | ||
+ | boils=3560K,<BR/>3287°C,<BR/>5949°F | | ||
+ | isotopes=46<BR/>50 | | ||
+ | prior=[[Scandium|<FONT color="#7F7FFF">Sc</FONT>]] | | ||
+ | next=[[Vanadium|<FONT color="#7F7FFF">V</FONT>]] | | ||
+ | above=<SMALL><FONT color="#7F7F7F">N/A</FONT></SMALL> | | ||
+ | aprior=<SMALL><FONT color="#7F7F7F">N/A</FONT></SMALL> | | ||
+ | anext=<SMALL><FONT color="#7F7F7F">N/A</FONT></SMALL> | | ||
+ | below=[[Zirconium|<FONT color="#7F7FFF">Zr</FONT>]] | | ||
+ | bprior=[[Yttrium|<FONT color="#7F7FFF">Y</FONT>]] | | ||
+ | bnext=[[Niobium|<FONT color="#7F7FFF">Nb</FONT>]] | | ||
+ | radius=140 | | ||
+ | bohr=176 | | ||
+ | covalent=136 | | ||
+ | vdwr= | | ||
+ | irad=(+4) 61 | | ||
+ | ipot=6.83 | | ||
+ | econfig=1s<sup>2</sup> <br/>2s<sup>2</sup> 2p<sup>6</sup> <br/>3s<sup>2</sup> 3p<sup>6</sup> 3d<sup>2</sup> <br/>4s<sup>2</sup> | | ||
+ | eshell=2, 8, 10, 2 | | ||
+ | enega=1.54 | | ||
+ | eaffin=0.08 | | ||
+ | oxstat=4 | | ||
+ | magn=Paramagnetic | | ||
+ | cryst=Hexagonal | | ||
+ | }} | ||
+ | '''Titanium''' is a Transition Metal in group 4. | ||
+ | It has a Hexagonal crystalline structure. | ||
+ | This element has two stable isotopes: 46 and 50. | ||
<BR/><BR/> | <BR/><BR/> | ||
− | "Titanium occurs primarily in the minerals anatase, brookite, [[ilmenite]], leucoxene, perovskite, [[rutile]], and sphene. Of these minerals, only ilmenite, leucoxene, and rutile have significant economic importance. As a metal, titanium is well known for corrosion resistance and for its high strength-to-weight ratio. Approximately 95% of titanium is consumed in the form of titanium dioxide ( | + | "Titanium occurs primarily in the minerals anatase, brookite, [[ilmenite]], leucoxene, perovskite, [[rutile]], and sphene. Of these minerals, only ilmenite, leucoxene, and rutile have significant economic importance. As a metal, titanium is well known for corrosion resistance and for its high strength-to-weight ratio. Approximately 95% of titanium is consumed in the form of [[titanium dioxide]] (TiO<SUB>2</SUB>), a white pigment in paints, paper, and plastics. TiO<SUB>2</SUB> pigment is characterized by its purity, refractive index, particle size, and surface properties. To develop optimum pigment properties, the particle size is controlled within the range of about 0.2 to 0.4 micrometer. The superiority of TiO<SUB>2</SUB> as a white pigment is due mainly to its high refractive index and resulting light-scattering ability, which impart excellent hiding power and brightness." - USGS Titanium Statistics and Information[http://minerals.usgs.gov/minerals/pubs/commodity/titanium/] |
+ | <BR/><BR/> | ||
+ | |||
+ | Titanium's low weight, high strength, excellent corrosion resistance, and good fatigue endurance make it an excellent material to work with in a lunar environment, whether for building spacecraft, lunar habitats, machinery, or industrial processing equipment. It is expected that titanium production will be a very important component of any lunar colonization effort. | ||
+ | |||
+ | |||
+ | == See Also == | ||
+ | [[Lunar Titanium Production]] | ||
+ | |||
+ | [[Category:Abundant Elements]] | ||
+ | [[Category:Paramagnetic Elements]] | ||
+ | [[Category:Solids]] | ||
+ | [[Category:Transition Metals ]] | ||
− | + | <!-- Generated by a gamma candidate version of Autostub2 (Test 9) --> |
Latest revision as of 07:35, 8 December 2011
Titanium | |
---|---|
Ti | |
In situ availability: | abundant |
Necessity: | |
Atomic number: | 22 |
Atomic mass: | 47.867 |
group: | 4 |
period: | 4 |
normal phase: | Solid |
series: | Transition Metals |
density: | 4.506 g/cm3 |
melting point: | 1941K, 1668°C, 3034°F |
boiling point: | 3560K, 3287°C, 5949°F |
N/A ← N/A → N/A | |
Sc ← Ti → V | |
Y ← Zr → Nb | |
Atomic radius (pm): | 140 |
Bohr radius (pm): | 176 |
Covalent radius (pm): | 136 |
Van der Waals radius (pm): | |
ionic radius (pm): | (+4) 61 |
1st ion potential (eV): | 6.83 |
Electron Configuration | |
1s2 2s2 2p6 3s2 3p6 3d2 4s2 | |
Electrons Per Shell | |
2, 8, 10, 2 | |
Electronegativity: | 1.54 |
Electron Affinity: | 0.08 |
Oxidation states: | 4 |
Magnetism: | Paramagnetic |
Crystal structure: | Hexagonal |
Titanium is a Transition Metal in group 4.
It has a Hexagonal crystalline structure.
This element has two stable isotopes: 46 and 50.
"Titanium occurs primarily in the minerals anatase, brookite, ilmenite, leucoxene, perovskite, rutile, and sphene. Of these minerals, only ilmenite, leucoxene, and rutile have significant economic importance. As a metal, titanium is well known for corrosion resistance and for its high strength-to-weight ratio. Approximately 95% of titanium is consumed in the form of titanium dioxide (TiO2), a white pigment in paints, paper, and plastics. TiO2 pigment is characterized by its purity, refractive index, particle size, and surface properties. To develop optimum pigment properties, the particle size is controlled within the range of about 0.2 to 0.4 micrometer. The superiority of TiO2 as a white pigment is due mainly to its high refractive index and resulting light-scattering ability, which impart excellent hiding power and brightness." - USGS Titanium Statistics and Information[1]
Titanium's low weight, high strength, excellent corrosion resistance, and good fatigue endurance make it an excellent material to work with in a lunar environment, whether for building spacecraft, lunar habitats, machinery, or industrial processing equipment. It is expected that titanium production will be a very important component of any lunar colonization effort.
See Also