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There are a few ways to make an electronic component transparent. One is to make it so thin that it doesn’t register with the human eye. Or you can make the component take the form of a pattern whose features are so small they are invisible. Some battery components are easy to render transparent by shrinking them, but electrodes are particularly difficult to make thin. A super-thin electrode isn’t energy dense, and therefore it doesn’t store up enough power to be useful in any realistic way.

So Cui opted for the second approach. He and his team figured that if you can pattern the electrode into a superfine mesh, you can still build an energy dense battery. With enough electrode material distributed across the mesh, a battery can still hold a significant charge.

So using a relatively straightforward lithography method, they built a framework for the mesh in a soft, clear, spongy material called PDMS. To make a complete battery, they simply need two of these layers filled with electrode material--in this case, they used the makings of a standard lithium-ion battery--with a gel electrolyte (also clear, of course) sandwiched in between. Encase the whole thing in plastic, and you’ve got a see-through battery.

In the lab, the batteries have been used to power a small LED light (which can be viewed straight through the battery itself). Cui thinks the batteries should be roughly half as energy dense as a equally-sized regular battery. So right now the prototype is about as powerful as a NiCad battery, but Cui says he and his team should be able to improve that by an order of magnitude by reducing inefficiencies in the prototype design and layering batteries one atop the other. Depending on how it scales, the Stanford team thinks such transparent batteries could be commercialized in just two to four years.

See a video of the technology in practice via the Tech Review link below.

[Technology Review]

Material is called "the most condensed form of energy storage outside of nuclear"

Calling the material "the most condensed form of energy storage outside of nuclear energy," the researchers created the super-battery inside a diamond anvil cell, a small chamber that can create extremely high pressures within a confined space. The team filled the chamber with xenon difluoride, a white solid usually used to etch silicon conductors.

The science is in the squeezing; under normal atmospheric conditions, the molecules of xenon difluoride keep a respectable distance from one another. But under the intense pressures produced by the diamond anvils the molecules are forced together into metallic 3-D structures. At one million atmospheres -- roughly equivalent to the pressure found halfway to the center of the Earth -- the xenon difluoride is pressed neatly into these structures where the mechanical energy of all that pressure is stored in the chemical bonds between the molecules.

And just like that, the material becomes a chemical battery containing the mechanical energy from all that pressure. That raises the possibility of practical applications such as high-energy fuels, high-powered and compact batteries, or semiconductors that can function at very high temperatures.

[Science Daily]