Researchers develop new electrode structure for all-solid-state secondary battery

ETRI, DGIST develop new electrode structure for all-solid-state secondary battery
ETRI researchers are looking at a new type of electrode structure for all-solid-state secondary battery. Credit: Electronics and Telecommunications Research Institute(ETRI)

South Korean researchers have developed a new type of electrode structure for all-solid-state secondary batteries. If this technology is adopted, the energy density of the batteries could increase significantly when compared to existing technologies, contributing tremendously to the development of high-performance secondary batteries.

A joint research team from Electronics and Telecommunications Research Institute (ETRI) and Daegu Gyeongbuk Institute of Science and Technology (DGIST) has designed a new electrode structure for all-solid-state secondary batteries after identifying the mechanism of facile lithium-ion diffusion between active materials. They have published their results in ACS Energy Letters, an international online academic journal specializing in the energy sector which is run by the American Chemical Society (ACS).

Unlike primary cells, which can be only used once, secondary batteries can be recharged and used repeatedly. The importance of secondary battery technology to robots, electric cars, energy storage systems (ESS) and drones is growing year by year.

All-solid-state secondary batteries use a solid electrolyte to transport ions within battery electrodes. Solid electrolytes are safer than liquid electrolytes, which can cause a fire. Moreover, solid electrolytes can be implemented in a bipolar-type secondary cell to increase energy density by a simple battery configuration.

The electrode structure of a conventional all-solid-state secondary cell consists of a solid electrolyte responsible for ionic conduction, a conductive additive that provides the means for electron conduction; active material responsible for storing energy; and a binder that holds these constituent parts physically and chemically.

ETRI researchers discovered through systematic experiments, however, that ions are transported even between graphite active material particles. And they proposed a new type of electrode structure for an all-solid-state secondary cell consisting of only the active material and the binder. The researchers confirmed the possibility that even without a solid electrolyte additive within the electrodes, the performance of an all-solid-state secondary cell could be superior.

The theoretical feasibility of the novel structure proposed by ETRI was verified at DGIST through electrochemical testing of a virtual model running on a supercomputer. ETRI researchers succeeded in demonstrating this structure in an actual experiment. The result is a diffusion-dependent all-solid-state electrode.

If ETRI’s technology is adopted, solid conduction additive material will become unnecessary in the electrode; instead, the more active material can be squeezed into the same volume. In other words, the amount of active material in the electrode can increase by up to 98wt% and as a result, the energy density can be made 1.5 times greater than the conventional graphite composite electrode.

The technology offers advantages in manufacturing process aspects as well. Sulfide-type solid electrolytes, which have high ion conductivity and moderate plasticity, are regarded as an excellent candidate for the fabrication of all-solid-state batteries. But due to its high chemical reactivity, the sulfide-type solid electrolytes leave battery developers with very few options when it comes to solvents and binders. In contrast, with the new ETRI electrode, developers can

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