Professor Stefano Passerini is the Director of the Helmholtz Institute Ulm. In this Battery Chat, he talks to Parri Adeli regarding their work on high-voltage LNMO cathodes and electrolyte additives, among other topics.
As electric vehicles (EVs) trend from being niche to mass scale and the lines between EVs and their combustion engine (ICE) counterparts get blurred in terms of usability, consumers, automakers, governments and fire departments continue to have some apprehensions.
Dr. Ilias Belharouak is the head of electrification and energy storage at the Oak Ridge National Laboratory. In this Battery Chat, he talks to Parri Adeli about the various energy storage topics his group are investigating including a new class of cathodes that they developed recently and its scale-up path.
Professor Jeff Dahn, at the Department of Physics and Atmospheric Science, Dalhousie University in Nova Scotia, Canada explains how single crystal technology is proving to be a promising solution to the challenge of overcoming range anxiety which is high on the agenda of electric vehicle manufacturers and battery developers.
Dr. Feng Lin is an assistant professor in the chemistry department of Virginia Tech. In this Battery Chat, he talks to Parri Adeli about his scientific journey and his research into cathodes and catalysts.
If you’re like me and predictive text has led to some awkward if not amusing moments, you might be sceptical about Artificial Intelligence (AI). But its achievements are already overwhelming and changing, even protecting, our lives in many sectors.
Prof. Arumugam Manthiram, a renowned professor at the University of Texas at Austin, has contributed substantially to the field of energy storage with his research having great impact on the scientific community. In this chat, Prof. Manthiram shares his research path briefly, his perspective on current research performed on high-nickel cathodes, and a glimpse of his future research directions.
The present-day principal driver in the Li-ion industry is the large batteries required for electric vehicles. Due to the size of these batteries and the relative growth of electric vehicles it is predicted that the total Li-ion energy capacity will exceed one tera watt-hour by 2030. This anticipation for a dramatically rapidly expanding industry has stakeholders all along the value chain very motivated to be ready.
New advances in the use of Artificial Intelligence have the potential to speed up the process of alloy development.
The short answer is: yes, nickel can be a sustainable material throughout the entire value chain, from mining, manufacturing, to use and end of life – if all actors throughout the value chain step up and take their responsibility. Now let's look at the longer answer...
Food safety starts with rigorous hygiene, and nickel-containing stainless steels are the superior, reliable standard at every link of the food chain.
Around two-thirds of today’s buildings will still be around in 2050, and by 2060, the world is projected to add 230 billion m² of buildings - an area equivalent to the entire current global building stock. What can the building and construction sector do to reduce the environmental burden of buildings?
European nickel producers need a consistent regulatory framework. There must be coherence between different EU policy objectives with rules based on principles of sound science, risk-based approaches, full life-cycle thinking and impact assessments.
Partially corrugated stainless steel service pipes have reduced water leakage rates drastically in Tokyo where they were introduced in the 1980s. Now other innovative water authorities faced with the urgent need to reduce water loss are also examining the nickel-containing stainless steel solution.
Should we be worried about there being enough nickel to supply the transition to electric vehicles and cleaner energy sources? Given its wide range of uses in important existing and emerging technologies, this is a frequently asked question.