RIP
The Man Behind The Success Of Modern Lithium Ion Batteries
By Robert Rapier - Jul 01, 2023
- Engineer John Goodenough, the founding father of modern day lithium ion batteries passed away at 100.
- But Goodenough’s groundbreaking work began in the 1970s and led to the development of the first practical rechargeable lithium-ion battery.
- Goodenough’s advancements in lithium-ion battery technology have had a profound impact on various industries.
I am sure many of us have entertained fantasies of making some remarkable discovery that changes the world for the better. For one reason or another, only a small percentage of people make an enormous impact that affects the entire world.
But John B. Goodenough was such a person. Dr. Goodenough passed away on June 25, 2023 at the age of 100. He was an American materials scientist and engineer who is renowned for his significant contributions toward the development of rechargeable lithium-ion batteries.
He was born on July 25, 1922, in Jena, Germany to American parents. Goodenough’s family moved to the United States in 1923. He earned a bachelor’s degree in mathematics from Yale University in 1944. He served in World War II and then earned a Ph.D. in physics at the University of Chicago.
But Goodenough’s groundbreaking work began in the 1970s and led to the development of the first practical rechargeable lithium-ion battery, revolutionizing portable electronic devices in the process. His research involved the use of lithium cobalt oxide as a cathode material, greatly enhancing battery performance and energy storage capacity.
He made several important contributions to battery technology. His team discovered that lithium ions could shuttle between the cathode and anode of a battery, enabling efficient and reversible energy storage. He also explored different materials, including lithium iron phosphate and lithium manganese oxide, which further improved battery performance.
Goodenough’s advancements in lithium-ion battery technology have had a profound impact on various industries, including consumer electronics, electric vehicles, and renewable energy storage. His work paved the way for the development of lightweight, high-energy-density batteries that power modern devices and contribute to the transition to cleaner energy sources.
His accomplishments have been widely recognized. In 2019, he was awarded the Nobel Prize in Chemistry, along with Stanley Whittingham and Akira Yoshino, for their contributions to the development of lithium-ion batteries.
Goodenough has received numerous other prestigious awards, including the National Medal of Science, the Japan Prize, and the Enrico Fermi Award. John B. Goodenough’s research and innovations in battery technology have had a transformative impact on society, enabling the proliferation of portable electronics and advancing the shift toward more sustainable energy solutions.
His work exemplifies the power of scientific inquiry and its potential to shape our modern world. Regarding his lasting impact on the world, perhaps nobody ever had a more fitting name than “Goodenough.”
By Robert Rapier
New Advances In Lithium Air Batteries Promise Greener Future
By Brian Westenhaus - Jul 02, 2023- The researchers created CoSn(OH)6 (CSO), a catalyst for oxygen evolution reactions necessary for lithium air batteries, in a single step within 20 minutes, significantly speeding up previous methods.
- The synthesized CSO demonstrated excellent catalytic properties for oxygen evolution reactions, making it a promising material for high energy density batteries, such as those required for electric vehicles.
- This breakthrough opens a new path towards the realization of next-generation electric batteries, potentially aiding in the transition to a new energy system independent of fossil fuels.
Shibaura Institute of Technology scientists have developed a faster more efficient way to synthesize CoSn(OH)6, a powerful catalyst required for high-energy lithium air batteries.
The research paper has been published in the journal Sustainable Energy & Fuels. CoSn(OH)6 (CSO) is an effective oxygen evolution reaction (OER) catalyst, necessary for developing next-generation lithium-air batteries. However, current methods of synthesizing CSO are complicated and slow. Recently, an international research team synthesized CSO in a single step within 20 minutes using solution plasma to generate CSO nanocrystals with excellent OER catalytic properties. Their findings could boost the manufacturing of high energy density batteries.
There is pressure to reduce fossil fuel dependency and switch to alternative green energy sources. The development of electric vehicles is a move towards this direction.
However, electric vehicles require high energy density batteries for their functioning, and conventional lithium-ion batteries are not up to the task. Theoretically, lithium-air batteries provide a higher energy density than lithium-ion batteries. But before they can be put to practical use, these batteries need to be made energy efficient, their cycle characteristics need to be enhanced, and the overpotential needed to charge/discharge the oxygen redox reaction needs to be reduced.
To address these issues, a suitable catalyst is needed to accelerate the oxygen evolution reaction (OER) inside the battery. The OER is an extremely important chemical reaction involved in water splitting for improving the performance of storage batteries.
Rare and expensive noble metal oxides such as ruthenium(IV) oxide (RuO2) and iridium(IV) oxide (IrO2) have typically been used as catalysts to expedite the OER of metal-air batteries. More affordable catalytic materials include transition metals, such as perovskite-type oxides and hydroxides, which are known to be highly active for the OER.
CoSn(OH)6 (CSO) is one such perovskite-type hydroxide that is known to be a promising OER catalyst. However, current methods of synthesizing CSO are slow (require over 12 hours) and require multiple steps.
To address these issues, a suitable catalyst is needed to accelerate the oxygen evolution reaction (OER) inside the battery. The OER is an extremely important chemical reaction involved in water splitting for improving the performance of storage batteries. Rare and expensive noble metal oxides such as ruthenium(IV) oxide (RuO2) and iridium(IV) oxide (IrO2) have typically been used as catalysts to expedite the OER of metal-air batteries.
More affordable catalytic materials include transition metals, such as perovskite-type oxides and hydroxides, which are known to be highly active for the OER. CoSn(OH)6 (CSO) is one such perovskite-type hydroxide that is known to be a promising OER catalyst. However, current methods of synthesizing CSO are slow (require over 12 hours) and require multiple steps.
In a recent breakthrough, a research team from Shibaura Institute of Technology in Japan, led by Prof. Takahiro Ishizaki along with Mr. Masaki Narahara and Dr. Sangwoo Chae, managed to synthesize CSO in just 20 minutes using only a single step! To achieve this remarkable feat, the team used a solution plasma process, a cutting-edge method for material synthesis in a nonthermal reaction field. Their research was published in the journal Sustainable Energy & Fuels.
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The team used X-ray diffractometry to show that highly crystalline CSO could be synthesized from a precursor solution by adjusting the pH to values greater than 10 to 12. Using a transmission electron microscope, they further noticed that the CSO crystals were cube-shaped, with sizes of about 100-300 nm. The team also used X-ray photoelectron spectroscopy to investigate the composition and binding sites of CSO crystals and found Cobalt (Co) in a divalent and Tin (Sn) in a tetravalent state within the compound.
Finally, the team used an electrochemical method to look at the properties of CSO as a catalyst for OER. They observed that synthesized CSO had an overpotential of 350 mV at a current density of 10 mA cm−2.
“CSO synthesized at pH12 had the best catalytic property among all samples synthesized. In fact, this sample had slightly better catalytic properties than that of even commercial-grade RuO2,” highlighted Prof. Ishizaki. This was confirmed when the pH 12 sample was shown to have the lowest potential, specifically 104 mV lower than that of commercially available RuO2 vs. reversible hydrogen electrode at 10 mA cm−2.
Overall, this study describes, for the first time, an easy and efficient process for synthesizing CSO. This process makes CSO practically effective for use in lithium-air batteries and opens a new avenue towards the realization of next-generation electric batteries.
Prof. Ishizaki concluded, “The synthesized CSO showed superior electrocatalytic properties for OER. We hope that the perovskite-type CSO materials will be applied to energy devices and will contribute to the high functionalization of electric vehicles. This, in turn, will bring us one step closer towards achieving carbon neutrality by enabling a new energy system independent of fossil fuels.”
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Lithium-air battery chemistry seems to offer quite a step up from the lithium-ion field. The theoretical number look really encouraging. One does hope that the technology will serve to extend the lithium supply.
But the small fly in the future is the long term performance. Lithium-ion came to market all set, same as perfect and remains to this day much less than the ideal originally proposed.
As this technology gets so close now to marketable it might be time to get on with some real long term testing to see just what the technology offers beyond more capacity.
By Brian Westenhaus via New Energy and Fuel