Can quantum dots stop heat loss in solar cells?
U. MINNESOTA (US)—Researchers have cleared a major hurdle in the drive to build solar cells with potential efficiencies up to twice as high as current levels, which rarely exceed 30 percent.
By showing how energy that is now being lost from semiconductors in solar cells can be captured and transferred to electric circuits, the discovery opens new avenues for solar cell researchers seeking to build cheaper, more efficient solar energy devices.
The work is published in the June 18 issue of Science.
A system built on the research could also slash the cost of manufacturing solar cells by removing the need to process them at very high temperatures.
In most solar cells now in use, rays from the sun strike the uppermost layer of the cells, which is made of a crystalline semiconductor substance—usually silicon. The problem is that many electrons in the silicon absorb excess amounts of solar energy and radiate that energy away as heat before it can be harnessed.
An early step in harnessing that energy is to transfer these “hot” electrons out of the semiconductor and into a wire, or electric circuit, before they can cool off. But efforts to extract hot electrons from traditional silicon semiconductors have not succeeded.
However, when semiconductors are constructed in small pieces only a few nanometers wide—”quantum dots”—their properties change.
“Theory says that quantum dots should slow the loss of energy as heat,” says William Tisdale, a graduate student at University of Minnesota. “And a 2008 paper from the University of Chicago showed this to be true.
“The big question for us was whether we could also speed up the extraction and transfer of hot electrons enough to grab them before they cooled.”
In the current work, Tisdale demonstrated that quantum dots—made not of silicon but of another semiconductor called lead selenide—could indeed be made to surrender their “hot” electrons before they cooled. The electrons were pulled away by titanium dioxide, another common inexpensive and abundant semiconductor material that behaves like a wire.
“This is a very promising result,” Tisdale says. “We’ve shown that you can pull hot electrons out very quickly—before they lose their energy. This is exciting fundamental science.”
The work shows that the potential for building solar cells with efficiencies approaching 66 percent exists, says chemical engineering and materials science professors Eray Aydil.
“This work is a necessary but not sufficient step for building very high-efficiency solar cells,” he says. “It provides a motivation for researchers to work on quantum dots and solar cells based on quantum dots.”
The next step is to construct solar cells with quantum dots and study them. But one big problem still remains: “Hot” electrons also lose their energy in titanium dioxide. New solar cell designs will be needed to eliminate this loss.
“I’m comfortable saying that electricity from solar cells is going to be a large fraction of our energy supply in the future,” Aydil notes.
Researchers from the University of Texas at Austin contributed to the research, funded primarily by the U.S. Department of Energy and partially by the National Science Foundation.
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