Prize-winning technology for large-scale energy storage
Water-In-Polymer Salt Electrolyte for Slow Self-discharge in Organic Batteries
- Date:
- November 18, 2021
- Source:
- Linköping University
- Summary:
- Safe, cheap and sustainable technology for energy storage has been developed. It is based on two major breakthroughs: the manufacture of wood-based electrodes in rolled form, and a new type of water-based electrolyte.
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Safe, cheap and sustainable technology for energy storage has been developed at the Laboratory of Organic Electronics, Linköping University. It is based on two major breakthroughs: the manufacture of wood-based electrodes in rolled form, and a new type of water-based electrolyte. The result has been published in the scientific journal Advanced Energy and Sustainability Research. The technology has been patented and is to be commercialised by Norrköping-based spin-off company Ligna Energy AB, which received the award for best "Startup for Climate," during the recent COP26 meeting in Glasgow.
An increasing share of renewable energy in the energy mix and increasing consumption of electricity in society are causing major challenges for balancing power supply networks. In principle, electricity is consumed at the instant of its production, and there are currently limited options for storing large amounts of electricity. The problem is particularly acute during cold periods, when the demand for electricity is highest. Imbalance in the grid can cause serious power outages.
Professor Xavier Crispin and his colleagues at the Laboratory of Organic Electronics, Linköping University, have developed a concept for large-scale energy storage that is safe, cheap and sustainable. The potential power output is sufficiently high for the technology to maintain power balance in the electricity supply.
"Our results allow for safe, environmentally sustainable organic energy storage with high power density, 5 kW/kg, where the electrodes are manufactured from wood-based material in a printing press. We must, however, increase the energy density: our organic batteries are better than normal supercapacitors, and have about the same performance as lead-acid batteries. But lithium-ion batteries are better," says Xavier Crispin.
Previous attempts to develop a sustainable system for energy storage based on cheap organic and water-based electrolytes with carbon-based electrodes have all had problems with rapid self-discharge: it has been difficult to achieve more than one day.
The excellent results presented in the article are based on two breakthroughs: a new type of water-based electrolyte, and electrodes made from lignin, which is a readily available, cheap by-product from the manufacture of paper. The researchers have developed a polyelectrolyte that consists of a highly concentrated water-based polymer, potassium polyacrylate, together with biopolymer lignin (as positive electrode) and polyimide mixed with conductive carbon (as negative electrode).
"The voltage drop, which measures the self-discharge, is less than 0.5 V in 100 hours, which is a world record for energy storage with organic electrodes in water-based electrolytes," says Xavier Crispin.
And the new technology uses cheap raw materials: neither lignin, carbon nor the polyelectrolyte cost more that 1 USD/kg. These are readily available and non-flammable materials, and the technology can be scaled up to large batteries. It is a sustainable solution for large-scale and safe energy storage.
The major sources of funding for the research have been the Knut and Alice Wallenberg Foundation, and the Swedish Government Strategic Research Area in Materials Science on Functional Materials at Linköping University.
Story Source:
Materials provided by Linköping University. Original written by Monica Westman Svenselius. Note: Content may be edited for style and length.
Journal Reference:
- Ziyauddin Khan, Ujwala Ail, Fatima Nadia Ajjan, Jaywant Phopase, Zia Ullah Khan, Nara Kim, Jakob Nilsson, Olle Inganäs, Magnus Berggren, Xavier Crispin. Water‐in‐Polymer Salt Electrolyte for Slow Self‐Discharge in Organic Batteries. Advanced Energy and Sustainability Research, 2021; 2100165 DOI: 10.1002/aesr.202100165
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