Borrowed from all-solid-states batteries, these capacitors show high temperature use, high current densities, and high-capacity charging or discharging are possible
From: Osaka Metropolitan University
August 19, 2022 -- A
research group has successfully developed a high-capacity capacitor, an energy
storage device -- using a solid electrolyte with high deformability -- that can
operate at high temperatures. With this discovery, high-capacity capacitors can
now be made which do not require cooling, this increases their efficiency and
allows for new suitable applications.
Capacitors are energy
storage devices, consisting of two electrodes and an electrolyte, that are
capable of rapid charging and discharging because of charge adsorption and
desorption properties at the electrode-electrolyte interface. Because
capacitors' energy storage does not involve chemical reactions, their storage
capacity is lower than that of lithium-ion batteries, but they are useful for
power leveling for renewable energy that requires repeated charging at high
currents, regenerative braking energy for trains and electric or hybrid cars,
as well as instantaneous voltage drop compensation devices that prevent
equipment failure due to lightning strikes. They are also expected to be used
to store energy for wearable devices in the near future.
Most capacitors use a
liquid electrolyte with a low boiling point, which can only be used at
temperatures below 80℃. Ceramic capacitors that use solid inorganic materials
as a dielectric can be used at temperatures above 80℃, but their storage
capacity is much lower than liquid electrolyte capacitors, which limits their
use to electronic circuits. To increase the energy storage of capacitors, it is
necessary to have a large contact area at the interface between the electrode
and the electrolyte. Making a large contact area is difficult using solid
electrolytes; so, the creation of a capacitor with high storage capacity that
can also operate at high temperatures has been desired for a long time.
A research group led by
Professor Akitoshi Hayashi at the Graduate School of Engineering, Osaka
Metropolitan University, has developed a solid electrolyte that is highly
deformable, allowing it to have a large contact area with an electrode, which
was developed to be used for an oxide-based all-solid-state battery. In this
study, they fabricated a composite using the same highly deformable solid
electrolyte and carbon, then used it to construct both electrodes for a
bulk-type all-solid-state capacitor. This capacitor is capable of high current
densities and high-capacity charging and discharging at temperatures of
200-300°C, creating the world's first bulk-type all-solid-state capacitors. The
researchers expect that their capacitor will be used to improve technology for
high-temperature environments, which could not be developed previously due to
these technical limitations.
"The key to
realizing this capacitor was to take the solid oxide electrolytes that we have
been developing for all-solid-state lithium batteries -- which combine
excellent deformability and lithium-ion conductivity -- and apply them to
capacitors," explained Professor Hayashi.
In the future, the
researchers hope to construct all-solid-state hybrid capacitors with even
higher energy densities, by controlling the chemical reaction between a solid
electrolyte and carbon, then combining them with positive electrode materials
used in lithium-ion batteries.
https://www.sciencedaily.com/releases/2022/08/220819094543.htm
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