A new kind of solar cell could store
electrical energy without any help from traditional batteries, according to a
new study.
Researchers at Ohio State University, in
Columbus, have developed what they're calling the world's first solar battery —
a hybrid device that combines the energy-capturing abilities of a solar cell with
the energy-storing capabilities of a battery.
The
new cell could lower the cost of harvesting renewable energy from the sun by as much as 25 percent, according to
the researchers.
- The key to the device's success is a mesh solar panel that allows both sunlight and air to enter the cell. This porous material represents a departure from the solid semiconductor materials typically used to make solar cells. Allowing both light and oxygen into the cell enables the chemical reactions that typically occur inside a battery to occur within the solar cell itself.
A loss of electricity naturally occurs
within any solar cell when the electrons released by the cell's semiconductor
materials travel outside the cell and into a battery. Only about 80 percent of
the electrons produced by solar cells successfully complete this journey. But
the new solar cell is designed to ensure that 100 percent of the electrons
captured find their way into a battery, the researchers said.
This high efficiency is possible
because the conversion of sunlight to electric current isn't
happening inside the solar cell before being transferred to the battery. Since
the battery is located inside the cell, electrons are not able to escape, the
researchers said.
The hybrid solar cell-battery is made
up of three electrodes, or materials that conduct electricity. The first electrode is the
mesh solar panel (which is really a collection of solar cells), the second
electrode is made of a thin sheet of porous carbon and the third electrode is a
sheet of lithium metal. Between these three electrodes is an electrolyte that
can shuttle charges back and forth.
When the battery is in use — a phase
known as "discharge" — the lithium metal and porous carbon electrodes
are connected to an external circuit. Lithium ions can then travel to the
carbon electrode and form lithium peroxide. This chemical process drives an
external electrical current.
To recharge the solar battery, light hits
the mesh panel and generates electron-hole pairs, which can carry an electrical
charge. One of the most important features of the device is that it uses added
molecules, known as redox shuttle additives, to transfer these charges from the
mesh solar panel to the lithium electrode, where they cause the lithium
peroxide to decompose into oxygen and lithium ions.
The oxygen is released out of the cell,
but the lithium ions, as well as electrical charges, are stored inside the
battery in the lithium electrode.
“Basically, it's a breathing battery,”.
“It breathes in air when it discharges, and breathes out when it charges.”
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