Nanotechnology changes behavior of materials

January 23, 2015 by Beth Miller, Washington University in St. Louis
Nanotechnology changes behavior of materials, new research finds

One of the reasons solar cells are not used more widely is cost—the materials used to make them most efficient are expensive. Engineers are exploring ways to print solar cells from inks, but the devices don't work as well.

Elijah Thimsen, PhD, assistant professor of energy, environmental & chemical engineering in the School of Engineering & Applied Science at Washington University in St. Louis, and a team of engineers at the University of Minnesota have developed a technique to increase the performance and of thin films that make up these materials using nanotechnology. Their work was published in the Dec. 19, 2014, issue of Nature Communications.

Transparent conductors are thin films, which are are simply ultrathin layers of materials deposited on a surface that allow light to pass through and conduct electricity, a process in which electrons flow through a system. Thimsen and his team found by changing the structure of a thin film made of nanoparticles, electrons no longer flowed through the system in a conventional way, but hopped from place to place by a process called tunneling.

The team measured the electronic properties of a thin film made of zinc oxide nanoparticles before and after coating its surface with aluminum oxide. Both the zinc oxide nanoparticles and are electronic insulators, so only a tiny amount of electricity flows through them. However, when these insulators were combined, the researchers got a surprising result.

"The new composite became highly conductive," Thimsen said. "The composite exhibits fundamentally different behavior than the parent compounds. We found that by controlling the structure of the material, you can control the mechanism by which electrons are transported."

Because the reason behind this is not well understood, Thimsen and the team plan to continue to work to understand the relationship between the structure of the nanoparticle film and the electron transport mechanism, he said.

"If electrons are tunneling, they're not really moving with a classical velocity and moving from one point to the next," Thimsen said. "If are tunneling from one point to the next, one hypothesis is that they won't interact with strong magnetic fields. One of our long-term visions is to create a material that has high electrical conductivity but does not interact with magnetic fields."

In addition, the new composite's behavior also improved its performance, which could ultimately help to lower the cost of materials used in and other electronic devices.

"The performance is quite good, but not at the level it needs to be to be commercially viable, but it's close," Thimsen said.

Explore further: Shining a little light changes metal into semiconductor

More information: "High electron mobility in thin films formed via supersonic impact deposition of nanocrystals synthesized in nonthermal plasmas." Nature Communications, Dec. 19, 2014. DOI: 10.1038/ncomms6822

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not rated yet Jan 23, 2015
Of course the idea and reality that "Nanotechnology changes behavior of materials", then turns to applying the complex math, applying the gaseous and RF characteristics tied to the full expression of Maxwell's equations--taking that as the pure particle to particle connections in things like Rossi's LENR devices.

One is dealing not with Newtonian simpleton mathematics and considerations, but aspects of transmutation, aspects of quantum interactions, on a mass scale. Heart of the sun stuff.

Rossi's device works on the quantum to quantum individual level, not mass aggregate level of what most people consider to be the math and the science. Rossi's E-Cat device has passed every single testing hurdle, from all corners. The protestations are coming the illiterate, and the agenda driven.

Recently, Bill gates of Microsoft, Flew into Italy, in order to receive a full breakdown of the technology, by the university of Bologna.

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