WHAT is the difference between diamond and Carbon in terms of light absorption.
Does same element reflect or absorb the light by some factors?
INSTEAD OF absorbed by cellulose-(a sheet of paper is made of cellulose)-the interaction of light with cellulose transformes the cellulose into Carbon.
There occur a black carbon area on the paper.
tHE SAME light without a lens is not able to burn the paper, because the light has the room to be reflected by cellulose. But lens condenses the light (ref: laser light creation).
....
BLACKHOLE does not reflect light as Kömür.
DIAMOND-CARBON:
fARK elmasta karbon atomlarının düzlemsel bir tabaka yerine üç boyutlu bir kristal oluşturacak şekilde dizilmeleri ve pozisyon almalarında. Daha açık ifade edersek, karanlıkta kömür ile elmas madeninin içerik olarak aslında hiçbir farkı yok. Fark, her ikisinin ışıkla ETKİLEŞMESİ ile ortaya çıkan durumda. Yani, elmasın, ışığı kömür gibi ABSORBE ETMEYİP, yansıtması.
Diamond-like carbon (DLC) exists in seven different forms[ of amorphous carbon materials that display some of the unique properties of diamond. All seven contain significant amounts of sp3 hybridized carbon atoms. The reason that there are different types is that even diamond can be found in two crystalline polytypes. The usual one has its carbon atoms arranged in a cubic lattice,
while the very rare one (lonsdaleite) has a hexagonal lattice. By mixing these polytypes in various ways at the nanoscale level of structure, DLC coatings can be made that at the same time are amorphous, flexible, and yet purely sp3 bonded "diamond". The hardest, strongest, and slickest is such a mixture, known as tetrahedral amorphous carbon, or ta-C.
Such ta-C can be considered to be the "pure" form of DLC, since it consists only of sp3 bonded carbon atoms. Fillers such as hydrogen, graphitic sp2 carbon are used in the other 6 forms to reduce production expenses.
DLC(elmas) production
There are several methods for producing DLC, but all depend upon the fact that in carbon the sp3 bond length is significantly less than the length of the sp2 bond. So the application of pressure, impact, catalysis, or some combination of these at the atomic scale can force sp2 bonded carbon atoms closer together into sp3 bonds. This must be done vigorously enough that the atoms cannot simply spring back apart into separations characteristic of sp2 bonds. Usually techniques either combine such a compression with a push of the new cluster of sp3 bonded carbon deeper into the coating so that there is no room for expansion back to separations needed for sp2 bonding; or the new cluster is buried by the arrival of new carbon destined for the next cycle of impacts. It is reasonable to envision the process as a "hail" of projectiles that produce localized, faster, nanoscale versions of the classic combinations of heat and pressure that produce natural and synthetic diamond. Because they occur independently at many places across the surface of a growing film or coating, they tend to produce an analog of a cobblestone street with the cobbles being nodules or clusters of sp3 bonded carbon. Depending upon the particular "recipe" being used, there are cycles of deposition of carbon and impact or continuous proportions of new carbon arriving and projectiles conveying the impacts needed to force the formation of the sp3 bonds.
CONCLUSION: rATHER THAN a start to a planet, blackholes are the end of planets. They are fired planets OF Space.
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EARTHQUAKES are a result of light absorption by earth.
The earth is a mixture of elements.
Each element absorbs different wavelenght of light.
For example Cerium element will not absorb the light as Kömür does.
The sun does not always emits the same wavelengt of light.
Or sometimes 'güneş tutulur' and the earth elements are exposed to different wavelength OR AMOUNT of light.
sOMETİMES Earthquake occur at the places where Cerium is rich when the light wavelenght coming from Sun corresponds to Cerium element.
My personal observation implied that; When a Cerium mine is collapsed, exploded in America OR IN ANOTHER PLACE, it is very likely that in China OR IN ANOTHER Cerium RICH place there occur an earthquake. It depends on the amount of Cerium found in certain areas.
In america only a mine collapses, whereas in china a town is destroyed by an earthquake. Because more light will be absorbed by larger amount of cerium PRESENT.
Each time the wavelenght of sunlight changes, the element on earth that absorbs the light changes also.
Thus one year it is Cerium that absorbs most light, another year it is a different element that absorbs most light.
(Cerium element is likely to ignite when scratched).
Some wavelenghts are able to penetrate to very deep ares of earth, some wavelengts will be not strong to reach to Elements located at deep areas.
This year, 2009-10, the wavelenght corresponds to an unknown element found in underwater volcanos. Thus depending on the amount of the underwater volcano's some unknown elements, the light is mostly absorbed by underwatervolcanos. Homogeneous distribution of elements on earth is preferable I believe.
Because, if the light at a special wavelength is too much to effect only one element, heterogeneous distribution of elements will be against to the odds of too much absorbtion of light by small areas.
The knowledge of element composition of earth will be helpfull to predict earthquakes in 3500. but not nowadays. we already know what elements absorb what wavelenght of light. For example light might further change electricity of Cerium ELEMENT and leads to easy gas explodes around Cerium.
Light spectrum Methods will be employed to analyse changes in electromagnetic light spectrum over years, its correlation with night and day. with temperature, with gas formation. Not a cheap project.
The interaction of special wavelenght light with certain elements will result in different chemical reactions.
Sometimes it will be accompanied with gas formation, or heat production, temperature changes. Volcano elements are very homogeneous for certain elements, metals and able to absorb or interact with large amount of light.
We do not know if the spectra of light differ prior to eartquakes. Does the proportion of visible wavelength light over Ultraviolet light changes prior to earthquakes nobody knows.
WHAT DOES IT MEANS, LIGHT OSCILLATES?
