Beyond Li-ion: challenges and opportunities for future battery technology

On the evening of 25 November 2021 RSC Belgium hosted the last of its webinars for the year with a talk from Prof Jean-François Gohy from the Institute of Condensed Matter and Nanosciences at the Université catholique de Louvain. Prof Gohy had previously presented to the section on advances in energy storage and this new talk focused on recent advances and opportunities for future battery technologies. 

The improvement in performance and cost of lithium-ion batteries (LIBs) over the past few years have made them the technology of choice for electrical energy storage. While established battery chemistries and cell architectures for LIBs achieve good power and energy density, Jean-Francois indicated that LIBs are unlikely to meet all the performance, cost, and scaling targets required for future energy storage, in particular, in large-scale applications such as electrified transportation and grids. 

The demand to further reduce cost and/or increase energy density, as well as the growing concerns related to natural resource needs for Li-ion technologies have accelerated the investigation of so-called “beyond Li-ion” technologies. In his talk Prof Gohy discussed recent achievements, challenges, and opportunities for some of these “beyond Li-ion” technologies. While it is unlikely that any given new technology will fully replace Li-ion in the near future, “beyond Li-ion” technologies should be thought of as opportunities for energy storage to grow into mid/large-scale applications.

Range of options

Prof Gohy took the audience through a range of options for promising battery technologies that could provide the required energy density safely and at reasonable cost. Costs for LIBs had dramatically dropped from over $1000 per KWh to less that $150 and this trend was continuing thanks to massive investment LIBs by the car industry.

But next generation technologies were required. Lithium metal batteries are part of the family of All Solid State Batteries (ASSB) and previous significant safety concerns had now been partially solved. Other potential technologies included Li-S, Li-air, Sodium and Potassium ion batteries.

Li-metal based ASSBs could provide a path to achieve high volumetric energy density using established Li-ion cathode technology.

Sodium (NIB) and Potassium (KIB) batteries that rely on naturally abundant sodium and potassium resources are likely to provide a significant advantage in terms of cost for larger stationary applications such as storage for power grid management. 

Magnesium-metal batteries are a wild card technology that could potentially provide a unique combination of high energy density and low cost as a "beyond Li-ion" battery technology. Mg metal as an anode is less prone to failure due to dendritic growth, but the most significant technical barrier to this technology is the achievement of high energy density Mg cathodes.

RSC video at COP26

During the COP26 meeting in Glasgow the RSC held a panel discussion on this topic that debated the cutting edge chemistry underlying next generation battery innovations, their potential, their limitations and their pathways to mass adoption.

The video was part of an initiative demonstrating chemistry’s role in understanding and tackling climate change covering next-generation batteries, hydrogen, agriculture, carbon dioxide utilisation, and more.

Elements in Danger!

On the evening of Thursday 24 September from 19h30 RSC Belgium presented its first ever webinar event. The subject was ‘Elements in Danger’ and our speaker was Professor David Cole-Hamilton, Past President of the European Chemical Society and Irvine Professor of Chemistry at the University of St. Andrews. The webinar was also the occasion for the announcement of our prizewinners in our 2020 Chemistry Challenge and this year’s winner of the coveted Keith Price Award.

The webinar was run via Microsoft Teams with our Chairman and master of ceremonies Bob Crichton in a seminar room at Universite Catholique Louvain with technical maestro Fabio Lucaccioni and Prof Cole-Hamilton (pictured below at a previous RSC Belgium event) 'broadcasting' from his home in St. Andrews.

A couple of rehearsals were arranged before the event itself to iron out any technical glitches and the systems worked well on the night. 

Elemental

As part of their contribution to the International Year of the Periodic Table, the European Chemical Society produced a new Periodic Table (see below).

It is an amazing thought that everything we see, touch, and smell is made up of only 90 building blocks: the 90 naturally occurring chemical elements. The new periodic table only displays those 90 elements + technetium and promethium.

The area occupied by each element relates to its abundance in the earth’s crust and in the atmosphere (on a log scale) and the colour indicates how long we shall be able to use these elements if we carry on as we are. Four elements are coloured black because they can come from mines where wars are fought over mineral rights.

31 of the elements are used in making smartphones (indicated by a phone symbol). All four conflict minerals are included amongst the elements in a phone and six will be dissipated within less than 100 years unless we do something.

Prof Cole-Hamilton presented the new Periodic Table and discussed selected elements with a view to understanding how we can continue to have the lifestyle we have and protect the 90 vital elements that make up our beautiful and diverse planet.

More details on the new Periodic Table including notes for teachers and learners, translations into most European languages and a link to a new Video Game 'Elemental Escapades - A Periodic Table Adventure' can be found at on the EuCheMS website.  

Revisit the webinar

The webinar was recorded using the Teams software and is now available to view whenever you want.

You can also access a copy of the powerpoint presentation used by Prof Cole-Hamilton here.