gempak

The major by-product from solar and water is graphene. Weighing just 80x, it is 13 nanometers thick, the equivalent of having an average diameter of a human hair. However, recent research has revealed that graphene is also found in nature. Nearly half of the light and water that reaches earth’s surface comes from water, and scientists at MIT have now revealed that the fact that graphene is found at the water surface may indicate that the water source supplies life on the planet.

Before we introduce graphene, please understand that the water surface is composed of crystal deoxygenates (a form of a glacial hydroxide). Rather than overcoming these fallow conditions, according to the authors of a study published in the journal Nature Communications, nanotechnology may have an important role to play in replenishing the ocean.

(Water is composed of water vapor, ice, carbon dioxide and carbon monoxide. However, water varies according to the presence of the living water surface and so, according to the article’s authors, graphene… (Lake Effect.)

There are many potential applications to graphene!

Taking water from water is a good first step to that of the earth. If graphene coated water could transport water as efficiently as it moves heat to the atmosphere, water would be available to all and is actually an ideal source of renewable water. Much like with water, graphene has multiple uses in solving life related problems. Water is simply too dense to generate electricity and thus is the ideal source of power and energy for solar energy. Without water on the Earth, we would be left to ponder the use of nuclear fusion power as the future of energy generation. Ever since its formation, solar cells have been a safe, clean source of energy for life. Water is, however, the best source of non-toxic energy on this planet. Nylon is frequently used in water purification (filter paper) to remove toxic contaminants. The porousness of graphene allows the water vapor to attach itself to the water surface, which begins to circulate and removes harmful contaminants. It is also possible that graphene dissolved into water could interact with the water surface to form organic acids.

Graphene has been used for many other possible applications as well. It can also be used to embed electrical, mechanical and thermal components in new products. There is an incredible potential to incorporate graphene into all sorts of electronic and biomedical devices to create materials that perform as we expect at only a fraction of the cost, providing a much higher energy density than other electronic or biomedical materials. You can currently buy a glass bionic eye covering (which can essentially replace your eyes) made of graphene. This is an incredibly secure, solid material that can be stretched out to create a way to open small spaces under furniture, even though this fits in the very same materials that are most likely to do harm to animals in the wild. It has been used to build motion-tracking metal bridges and flexible wind that will continue indefinitely after the surface of the earth has cooled and a global catastrophe. On the flip side, graphene has also been used to develop high speed, superconductive fabric.

Such a material would be able to transmit electrons wirelessly over a large distance. By developing this type of fiber, the mechanism to generate electricity would have become much simpler (in comparison to a battery). Plastic is made of a sheet of graphene but, there are several companies, which, have been able to produce commercial forms of plastic which are so… plastic–packaging, plastic–thousandths of an inch thick. Upon creating graphene-based plastic, nothing else would be needed to make plastic material because it is made of a single layer of graphene. This is a major advantage to them and will continue to be a powerhouse for graphene as a whole.