Princeton Chemistry demonstrates powerful sodium ion cathode to new battery technology
For decades, scientists have sought ways to combat our dependence on lithium-ion batteries. These traditional, rechargeable batteries feed the most omnipresent consumer electronics of today – from laptops to mobile phones to electric cars. But rough lithium is expensive and often comes from fragile geopolitical networks.
This month, the Dinca Group from Princeton University announces an exciting alternative that depends on an organic, energy -rich cathodial material to make sodium batteries, which means that this technology will find commercialization with safe, cheaper, cheaper, more sustainable components.
Although scientists have made some progress with sodium ion batteries, obstacles largely arise because of their low energy density: they have shorter battery run times relative to their size. High power density, which relates to output, also factors in their performance. Achieving high energy density and high power density at the same time has been a continuous challenge for alternative batteries.
But the cathode material presented by the Dinca group, a layered organic solid called bis-tetaminobenzoquinon (TAQ), surpasses traditional lithium-ion cathodes in both energy and power densities in a technology that is really scalable.
Their research has a potential for large -scale energy storage applications such as data centers, electricity networks and renewable energy systems on a commercial scale, in addition to electric vehicles.
“Everyone understands the challenges associated with limited resources for something as important as batteries, and Lithium certainly qualifies itself in a number of ways such as ‘Limited’,” said Mircea Dinca, the Alexander Stewart 1886 professor of chemistry. “It is always better to have a diversified portfolio for these materials. Sodium is literally everywhere. For us, behind batteries that are made with really abundant agents such as organic matter and seawater are among our largest research dreams.
“Energy density is something in the spirit of many people because you can compare it to how much juice you get in a battery. The more energy density you have, the further your car goes before you have to charge it. We have answered quite emphatically that the new material we have developed has the greatest energy density, certainly on a perpery kilogram, and with the best materials is even on a volumetic.
“In the front line of developing a truly sustainable and cost -effective sodium ion cathode or battery is really exciting.”
With financing of Automobili Lamborghini Spa, the research of the lab, very energy, powerful sodium batteries from a layered organic cathode, this month in the Journal of the American Chemical Society (Jacs).
Theoretical maximum capacity is approaching
The lab underlined the benefits of TAQ a year ago when they first reported on the usefulness of its usefulness for making lithium ion batteries in ACS Central Science. Researchers just kept investigating the potential, especially when they found TAQ completely insoluble and very conductive, two important technical benefits for an organic cathod material. A cathode is an essential part of all polarized devices.
So they tried to build an organic, sodium ion battery with the same material, Taq. The process lasted about a year, because researchers had to adjust different design principles that could not be transferred from lithium-ion technology.
In the end, the results exceeded their expectations. The performance of their cathode is almost close to a benchmark known as the theoretical maximum capacity.
“The binder we chose, carbon nanobuis, facilitates the mixing of TAQ crystallites and carbon -black particles, leading to a homogeneous electrode,” said Dinca Group Ph.D. And first author on paper, Tianyang Chen. “The carbon nano tubes wrap closet closely around TAQ crystallites and connect them. Both factors promote electron transport within the Elektrodebulk, which makes almost 100% active use of materials possible, leading to almost theoretical maximum capacity.
“The use of carbon nibes significantly improves the speed performance of the battery, which means that the battery can store the same amount of energy within a much shorter loading time, or store much more energy in the same loading time.”
Chen said that the benefit of TAQ as a cathode material also includes stability against air and moisture, long service life, the ability to withstand high temperatures and environmentally durability.
Research report:High-Energy, powerful sodium batteries of a layered organic cathode