(News) IIT Alumnus Technique May Help Harness Body's Heat To Recharge Cell-Phones
IIT
Alumnus Technique May Help Harness Body's Heat To Recharge Cell-Phones
An Indian
Institute of Technology, Bombay (IIT-B) alumnus has developed a technology
that may make it possible to create personal power-jackets which may harness
heat from the human body to recharge cell-phones and other electronic devices
Professor
Arun Majumdar, who is currently jointly
associated with the University of California at Berkeley and the US Department
of Energys Lawrence Berkeley National Laboratory (Berkeley Lab), says his
technique is based on the synthesis of silicon nanowires.
He
claims that his synthesized silicon nanowires can help harness the energy that
is usually lost as heat during the production of electricity.
The
researcher says that during experiments, rough silicon nanowires synthesized by
his team demonstrated high performance thermoelectric properties even at room
temperature when connected between two suspended heating pads. While one pad
served as the heat source, the other as the sensor, he adds.
This is the first demonstration of high performance thermoelectric capability in
silicon, an abundant semiconductor for which there already exists a
multibillion dollar infrastructure for low-cost and high-yield processing
and packaging, Nature magazine quoted him as saying.
Weve
shown that its possible to achieve a large enhancement of thermoelectric energy
efficiency at room temperature in rough silicon nanowires that have been
processed by wafer-scale electrochemical synthesis, said chemist Peidong Yang,
the other principal investigator behind this research, who also holds a joint
Berkeley Lab and UC Berkeley appointment.
The
researchers call their unique method of synthesizing arrays of silicon nanowires
electro less etching. Here, the nanowires are synthesized in an aqueous solution
on the surfaces of wafers that can measure dozens of square inches in area.
The
technique involves the galvanic displacement of silicon through the reduction of
silver ions on a wafers surface, they add.
While
other synthesis techniques yield smooth-surfaced nanowires, the electro less
etching method produces arrays of vertically aligned silicon nanowires with
exceptionally rough surfaces, which are believed to be critical to the
surprisingly high thermoelectric efficiency of the silicon nanowires.
The
rough surfaces are definitely playing a role in reducing the
thermal conductivity of the silicon nanowires by a hundredfold, but at
this time we don't fully understand the physics. While we cannot say exactly why
it works, we can say that the technique does work, said Majumdar.
Majumdar
pointed out that the worlds electrical power is generated by heat engines,
giant gas or steam-powered turbines that convert
heat to mechanical energy, which is then converted to electricity. However, much
of this heat releases into the environment, approximately 15 trillion Watts, he
added.
According
to him, even if a small fraction of the lost heat could be converted into
electricity, its might have a huge impact on the energy situation.
Thermoelectric
materials, which have the ability to convert heat into electricity, potentially
could be used to capture much of the low-grade waste heat now being lost and
convert it into electricity, said Majumdar.
This
would result in massive savings on fuel and carbon dioxide emissions. The same
devices can also be used as refrigerators and air conditioners, and because
these devices can be miniaturized, it could make heating and cooling much more
localized and efficient, he added.
The
Berkeley Lab researchers are now seeking industrial partners to further develop
and commercialize their technology. (ANI)
Courtesy:thaindian.com
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