Scientists at Vienna University of Technology have invented a new oxygen ion battery chemistry based on ceramic materials. If it degrades, it can be regenerated, therefore it potentially has an extremely long lifespan. Also, it does not require any rare elements and it is incombustible. For large energy storage systems, this could be an optimal solution.

Power and energy density comparison chart of modern battery chemistries and a fuel cell with a plot of the new oxygen ion chemistry. Image Credit: Vienna University of Technology. Click the study paper link for the largest image.

Lithium-ion batteries are common today – from electric cars to smartphones. But that does not mean that they are the best solution for all areas of application. TU Wien has now succeeded in developing an oxygen-ion battery that has some important advantages. Although it does not allow for as high of energy densities as the lithium-ion battery, its storage capacity does not decrease irrevocably over time: it can be regenerated and thus may enable an extremely long service life.

In addition, oxygen-ion batteries can be produced without rare elements and are made of incombustible materials. A patent application for the new battery idea has already been filed together with cooperation partners from Spain. The oxygen-ion battery could be an excellent solution for large energy storage systems, for example to store electrical energy from renewable sources.

The paper describing the research ‘Rechargeable Oxide Ion Batteries Based on Mixed Conducting Oxide Electrodes.’ has been published in the journal Advanced Energy Materials.

Ceramic materials as a new solution

Alexander Schmid from the Institute for Chemical Technologies and Analytics at TU Wien noted, “We have had a lot of experience with ceramic materials that can be used for fuel cells for quite some time. That gave us the idea of investigating whether such materials might also be suitable for making a battery.”

The ceramic materials that the TU Wien team studied can absorb and release doubly negatively charged oxygen ions. When an electric voltage is applied, the oxygen ions migrate from one ceramic material to another, after which they can be made to migrate back again, thus generating electric current.

Professor Jürgen Fleig explained, “The basic principle is actually very similar to the lithium-ion battery. But our materials have some important advantages.”

Ceramics are not flammable – so fire accidents, which occur time and again with lithium-ion batteries, are practically ruled out. In addition, there is no need for rare elements, which are expensive or can only be extracted in an environmentally harmful way.

Tobias Huber expanded the explanation with, “In this respect, the use of ceramic materials is a great advantage because they can be adapted very well. You can replace certain elements that are difficult to obtain with others relatively easily.”

The prototype of the battery still uses lanthanum – an element that is not exactly rare but not completely common either. But even lanthanum is to be replaced by something cheaper, and research into this is already underway. Cobalt or nickel, which are used in many batteries, are not used at all.

High life span

 But perhaps the most important advantage of the new battery technology is its potential longevity.

“In many batteries, you have the problem that at some point the charge carriers can no longer move,” said Alexander Schmid. “Then they can no longer be used to generate electricity, the capacity of the battery decreases. After many charging cycles, that can become a serious problem.”

The oxygen-ion battery, however, can be regenerated without any problems: If oxygen is lost due to side reactions, then the loss can simply be compensated for by oxygen from the ambient air.

The new battery concept is not intended for smartphones or electric cars, because the oxygen-ion battery only achieves about a third of the energy density that one is used to from lithium-ion batteries and runs at temperatures between 200 and 400° C. The technology is, however, extremely interesting for storing energy.

Alexander Schmid makes the case this way, “If you need a large energy storage unit to temporarily store solar or wind energy, for example, the oxygen-ion battery could be an excellent solution. If you construct an entire building full of energy storage modules, the lower energy density and increased operating temperature do not play a decisive role. But the strengths of our battery would be particularly important there: the long service life, the possibility of producing large quantities of these materials without rare elements, and the fact that there is no fire hazard with these batteries.”

***

This battery technology does have a serious level of promise. Even at only a third of lithium ion capacity the longevity has to have a very large impact. A daily cycled lithium ion battery should perform well into the third year, but how would that compete with a battery that might last 20 years or more? Would the lithium ion solution of the same capacity cost 80% less?

The metric of concern is the cost to make the ceramic and package it. Building a service center of these batteries might be lower cost or not, but a comparison to lithium ion needs to come.

The problem is going to be the costs to heat the battery sets and keep them at 200 to 400° C. That’s a bit under the ignition temp of paper up past the temperature of dry steam.

But nothing mentioned exceeds or even really heavily challenges conventional engineering. So. Lets hope getting a prototype up and running happens soon to find the unforeseen matters that need exposed.


Comments

Name (required)

Email (required)

Website

Speak your mind

css.php