A new thermally regenerative ammonia battery design has improved stability and affordability and may help address the country’s growing grid-scale energy storage problem. Credit: Adobe Stock. All Right Reserved.
Thermally regenerative battery produces ample energy using low-grade waste heat
July 11, 2022
Editor’s note: This article originally appeared on Penn State News. It mentions Nicholas Cross, doctoral candidate in chemical engineering; Christopher Gorski, associate professor of environmental engineering; Bruce Logan, Kappe Professor of Environmental Engineering and Evan Pugh University Professor; and Matthew Rau, assistant professor of mechanical engineering.
By Jennifer Matthews
UNIVERSITY PARK, Pa. — Thermally regenerative ammonia batteries can produce electricity on demand from low-grade waste heat. A new process for creating these batteries improves their stability and affordability and may help address the country’s growing grid-scale energy storage problem, according to a team led by Penn State researchers.
Their results were recently published in the Journal of Power Sources.
“We can use ammonia as an energy carrier to harness waste heat and recharge some battery chemistries,” said paper co-author Derek Hall, assistant professor of energy engineering in the College of Earth and Mineral Sciences. “But previous battery chemistries used metallic zinc or copper electrodes, which had major setbacks in terms of electrode stability. What we did was replace these deposition-based reactions with a novel copper complex chemistry to solve a lot of the major problems facing previous researchers."
Low-grade waste heat is a significant source of unused energy in the U.S. and around the world, with 60 terawatt-hours of energy discarded into the environment each year by power plants and industry, according to recent studies. Technologies exist that can turn this low-grade waste heat into energy, including thermo-electrochemical cells (TECs), thermally regenerative electrochemical cycles (TRECs) and thermally regenerative ammonia batteries (TRABs); however, there remain limitations precluding wider use of these battery configurations.
Solid-state TECs are simpler to operate than electrochemical systems but exhibit exceptionally low power densities and lack the ability to store energy. TECs and TRECs have higher thermal efficiencies but still suffer from low power densities, limiting their viability. Of all these technologies, TRABs have the largest power densities and energy efficiencies that are competitive with the rest, but TRABs have relied on either cost-prohibitive precious metals like silver or used metal electrodes that degraded quickly, the scientists said.
The Penn State researchers tested all-aqueous copper complexes in TRABs. In all-aqueous copper complexes, all the electroactive species —reactants and products — are contained in aqueous electrolytes. Previous thermally regenerative batteries required their electrodes to be built with electroactive materials. But all-aqueous copper reactions had never been used in a thermally regenerative ammonia battery before, so Hall said the first step was to see if this chemistry would work.
“The sourcing and manufacturing of copper is a lot easier compared to other rare elements and critical minerals used in batteries,” Hall said. “The all-aqueous feature of our battery allows us to decouple the energy and power capacity of this system, which is advantageous.”
TRABs operate similarly to other hybrid and conventional flow batteries, Hall said. Battery electrolytes are contained in storage tanks, which are pumped into an electrochemical reactor to produce or store electricity. The size of the reactor directly correlates to the power capacity, and tank size correlates to energy capacity. Most TRABs are hybrid flow battery concepts, that is, they operate using redox reactions that deposit and deplete metals at the electrodes. Unlike other flow batteries, however, TRABs can recharge using low-grade waste heat through an ammonia separation process.
The researchers investigated the limitations of power and energy density and how they are impacted by the electrolyte composition and discharge currents through a series of single cell tests. By increasing the ammonia concentration, the power density of the battery increased, but the energy density decreased. Increasing discharge current densities increased the average power density during discharge without substantial losses in energy density. Increasing the copper concentration increased both energy density and energy efficiency but did not greatly impact the power density. Depending on the electrolyte composition, the battery produced power density up to 30 milliwatts per square centimeter and energy densities up to two Watt-hours per liter. These results represent some of the highest performances ever achieved for a membrane-based low-grade waste heat to electricity system.
“What this battery addresses is a technical gap in our energy utilization process,” Hall said. “Only a fraction of the incoming heat we use for fossil fuels gets turned into useful energy. More than 50% is wasted in some cases, so being able to have something like this that can utilize that waste stream and create more power provides additional value from these precious resources. It is good for the environment by making us more energy efficient.”
The researchers’ next steps are to further optimize their design and to consider how this technology can be implemented in the field from both system design and economic perspectives. They plan to explore how it would integrate into a thermal energy system, and how big of a physical footprint it would need to produce usable amounts of power and energy.
“The global energy transition is going to happen in myriad ways because decarbonization needs to occur in many different sectors,” said Nicholas Cross, doctoral candidate in chemical engineering at Penn State and lead author on the project. “This technology could push forward that transition of how and where power and energy are produced by coupling new systems into already existing infrastructure.”
Other researchers on this project include Christopher Gorski, associate professor of environmental engineering; Bruce Logan, Kappe Professor of Environmental Engineering and Evan Pugh University Professor; Serguei Lvov, professor of energy and mineral engineering and materials science and engineering; and Matthew Rau, assistant professor of mechanical engineering.
The U.S. Department of Energy supported this research. The Lubrizol Corporation, a Berkshire Hathaway Company, advised Penn State on this research to ensure that project goals aligned with industry needs. The Lubrizol Corporation develops energy storage technologies for a wide range of industrial applications.