Concerns about the scarcity of lithium and other materials necessary in the now ubiquitous lithium-ion batteries have recently driven many researchers to look for alternatives, such as sodium and potassium. Professor Shinichi Komaba from Tokyo University of Science, Japan, and his team have worked for over a decade on this topic. In his latest review article, he extensively discusses his findings on the recent advances, promises, and limitations of potassium-ion batteries.
Our modern lifestyle would be immensely different without rechargeable batteries. Owing to their low-cost and recyclable technology, they’re used in most portable electronic devices, electric and hybrid vehicles, and renewable power-generation systems. And why shouldn’t they be? They offer an elegant solution to the world’s growing energy demands. Moreover, rechargeable batteries are an essential tool in systems that harvest renewable energy, such as wind and sun, because these sources can fluctuate greatly with the weather. Rechargeable batteries allow us to store the generated electricity and dispatch it on demand. Thus, it is no surprise that researchers globally have been focused on improving rechargeable batteries as a step towards developing sustainable energy resources.
Since their commercialization, lithium-ion batteries (LIBs) have been the go-to rechargeable batteries because of their excellent performance. However, with the ensuing spike in their demand, coupled with the limited availability of lithium and cobalt (another necessary element for LIBs) in Earth’s crust, using LIBs may soon become a major problem. This is why a team of scientists at Tokyo University of Science, led by Prof Shinichi Komaba, decided to walk the road less traveled: they focused on replacing the exhaustible element lithium with better alternatives like sodium and potassium. Sodium and potassium are in the same alkali metal group in the periodic table of elements, and their chemical natures are, therefore, quite similar. But, unlike lithium, these elements are widely abundant on Earth, and using them to develop high-performance rechargeable batteries would be a breakthrough towards creating a more sustainable society.
In 2014, Professor Komaba, along with Professor M. Stanley Whittingham, who won the Nobel Prize in Chemistry in 2019, analyzed the current state of development of sodium-ion batteries and published his assessments as a review. This became a highly cited study, with over 2,000 citations only in the past 5 years. Professor Komaba and his team then explored other plausible alternative to LIBs, potassium-ion batteries (KIBs), which have slowly become the focus of extensive research since 2015 after certain pioneering studies (e.g., a study published in Nature Materials in 2012), some of which were carried out by Komaba’s group. The use of potassium in batteries is promising because they show comparable (or even better) performance to LIBs. What’s more, the materials necessary to build KIBs are all nontoxic and much more abundant than those required for LIBs. Professor Komaba states, “By studying new materials for applications in lithium, sodium, potassium-ion batteries, we wanted to develop an energy-efficient and environment-friendly technology.”
In a remarkable effort to facilitate further research on KIBs, the research group led by Professor Komaba analyzed the workings of KIBs in great detail in a comprehensive review published in Chemical Reviews. Their paper encompasses everything related to the development of KIBs, from cathode and anode materials, various electrolytes and all-solid KIBs, to electrode doping and electrolyte additives. Moreover, the review compares the different materials used in lithium, sodium, and potassium-ion batteries. Being the only study that comprehensively analyzes several aspects of rechargeable batteries, it could prove really useful for leading current and future researchers in the right direction. Having comprehensive volumes of past research on KIBs and all the acquired insight condensed onto a single article is of immense value to anyone interested in delving in this research topic.
The continuous development of KIBs will hopefully bring about a rise in the use of this coveted alternative to LIBs. “As evidenced by recent intensive research, KIBs are recognized as promising next-generation battery candidates owing to their unique characteristics, such as cost-effectiveness, high voltage, and high-power operation. Further improvements to the performance of KIBs would pave the way for their practical application,” explains Professor Komaba.
However, research on certain aspects of KIBs, such as their safety, has been limited, and focus should be placed on obtaining more insight into what’s going on physically and chemically between the different components and elements. Prof Komaba is hopeful in this regard and concludes by saying, “Research on KIBs, including electrode materials, nonaqueous/solid electrolytes, and additives will provide new insights into the electrode reactions and solid ionics, opening up new strategies that would allow for the creation of next-generation batteries.” His research group has also focused on supercapacitors and biofuel cells along with both LIBs and sodium-ion batteries, which could all find very important functions in a more sustainable society in the future.
About Professor Shinichi Komaba from Tokyo University of Science
Prof Shinichi Komaba obtained his Ph.D. from Waseda University, Japan, and then joined Iwate University as a research associate. After one-year post-doctoral research in France, he joined Tokyo University of Science in 2005 to work on developing electrodes, electrolytes, and binding materials for various types of rechargeable batteries. His research group carries out cutting-edge research in the field of rechargeable batteries and their electrochemical applications. He is also the corresponding author of this review article. With more than 250 publications to his credit, Prof Komaba has won numerous international awards, including the title of “Highly Cited Researcher” in 2019.