Scalable fabrication of on-chip Li CO2 batteries for efficient electrocatalysts screening and energy storage mechanism study
Lead Research Organisation:
University of Surrey
Department Name: ATI Electronics
Abstract
The gradual depletion of fossil fuels and continuous emissions of greenhouse gas are two major energy and environmental problems that confront the world. To solve these worldwide issues, the UK becomes the first major economy to pass the net-zero emissions law. The new target requires the UK to bring all greenhouse gas emissions to net-zero by 2050. Thus, how to maximise the electrical energy supplies and balance the CO2 emissions becomes a critical issue to realise the low carbon society. Metal-CO2 batteries, with the dual characteristics of both effective CO2 fixation and advanced energy storage/conversion, will be perfectly aligned with the national strategy in clean energy and sustainability. Among different metal-CO2 batteries, Li-CO2 batteries are considered the best candidates due to their high theoretical specific energy density (~1800 Wh/kg) and relatively high discharge potential (~2.8 V). However, the development of Li-CO2 batteries is still in its infancy stage. This project aims to make advancements in Li-CO2 batteries with a focus on screening efficient cathode electrocatalysts and studying reaction mechanisms.
The high charge potential and unclear reaction mechanisms of current Li-CO2 batteries results in its poor reversibility and short cycle life. Therefore, massive efforts need to devote to find efficient catalysts and understand the comprehensive mechanisms. This project proposes a versatile screening and in situ characterisation platform for rapid screening of highly efficient electrocatalysts and in-depth studying of reaction mechanisms. This project details a specific method to fabricate on-chip Li-CO2 batteries. Combine a unique four-electrode circuit with advanced high-resolution characterisation methods, the structure-property relationship and underlying mechanism of Li-CO2 batteries will be revealed, which could further guide the optimisation of Li-CO2 batteries.
Project partners NPL (in situ characterisations), Johnson Matthey (materials and batteries) and QinetiQ (manufacturing and batteries) will provide essential know-how in order to help achieve the project aims: to fabricate on-chip Li-CO2 batteries prototype; to select optimal electrocatalysts; to construct in situ characterisation platform and uncover the underlying mechanism; to optimise the performance of Li-CO2 batteries.
This project is the natural result of the PI's expertise in the scalable fabrication of on-chip devices, rational design of electrocatalysts and battery, and in situ electrochemical characterisations. The framework of the proposed work will be underpinned by extensive energy materials characterisation expertise and infrastructure, as well as extensive expertise and facilities in battery manufacturing and testing at the University of Surrey.
The high charge potential and unclear reaction mechanisms of current Li-CO2 batteries results in its poor reversibility and short cycle life. Therefore, massive efforts need to devote to find efficient catalysts and understand the comprehensive mechanisms. This project proposes a versatile screening and in situ characterisation platform for rapid screening of highly efficient electrocatalysts and in-depth studying of reaction mechanisms. This project details a specific method to fabricate on-chip Li-CO2 batteries. Combine a unique four-electrode circuit with advanced high-resolution characterisation methods, the structure-property relationship and underlying mechanism of Li-CO2 batteries will be revealed, which could further guide the optimisation of Li-CO2 batteries.
Project partners NPL (in situ characterisations), Johnson Matthey (materials and batteries) and QinetiQ (manufacturing and batteries) will provide essential know-how in order to help achieve the project aims: to fabricate on-chip Li-CO2 batteries prototype; to select optimal electrocatalysts; to construct in situ characterisation platform and uncover the underlying mechanism; to optimise the performance of Li-CO2 batteries.
This project is the natural result of the PI's expertise in the scalable fabrication of on-chip devices, rational design of electrocatalysts and battery, and in situ electrochemical characterisations. The framework of the proposed work will be underpinned by extensive energy materials characterisation expertise and infrastructure, as well as extensive expertise and facilities in battery manufacturing and testing at the University of Surrey.
Planned Impact
This project aims to further the advancement of Li-CO2 battery technology. The project will lead multidisciplinary research to enable the tuning of materials for improved performance and faster development of Li-CO2 battery technology.
The successful delivery of this project will lead to the production of on-chip Li-CO2 batteries prototype and future commercialisation of this technology, which provides a cheaper, cleaner, safer and sustainable energy storage solution. Moreover, the versatile in situ characterisation platform from this research could contribute to the understanding of reaction mechanism and optimisation of performance in metal-air/CO2 batteries. Besides, those on-chip batteries could also be incorporated with flexible substrates or other electronic components, making it a multifunctional system for wearable and implantable electronics.
Commercial beneficiaries of the research (wealth generation in 10 - 25 years) will be companies in the UK and worldwide in, or part of, the supply chain for renewable energy, catalyst or electronics companies. More specifically, in the 5 - 15 years window, the UK industry will directly benefit if the outcomes of the research lead to more developed and focussed academic-industry collaborations (Innovate UK / Knowledge Transfer Partnerships). The potential IP that could be generated in the area of energy storage and carbon capture will yield opportunities for spin-out companies, providing employment opportunities and adding value to the UK economy.
Societal benefits will include, for example:
- balance the CO2 emissions and maximise the electrical energy supplies to meet the net-zero target by 2050;
- large-scale employment of renewable energies and thus the transition to a low carbon society;
- enhancement of the UK's energy security and environmental sustainability.
In the short-term (1-3 years), this project will provide highly skilled researchers who will have developed multidisciplinary skills and will have experienced a broad range of technological fields that are important for R&D programmes required for market innovation for Li-CO2 battery technology and beyond.
The PI will benefit from several new collaborations with NPL, Johnson Matthey and QinetiQ, in addition to the above-established collaborations associated with the PI's current research programmes. The UK-based and international partners are committed to supporting aspects of this project within their research capacity. Further collaboration with leading groups and the development of multidisciplinary research projects will be fostered during this project.
The successful delivery of this project will lead to the production of on-chip Li-CO2 batteries prototype and future commercialisation of this technology, which provides a cheaper, cleaner, safer and sustainable energy storage solution. Moreover, the versatile in situ characterisation platform from this research could contribute to the understanding of reaction mechanism and optimisation of performance in metal-air/CO2 batteries. Besides, those on-chip batteries could also be incorporated with flexible substrates or other electronic components, making it a multifunctional system for wearable and implantable electronics.
Commercial beneficiaries of the research (wealth generation in 10 - 25 years) will be companies in the UK and worldwide in, or part of, the supply chain for renewable energy, catalyst or electronics companies. More specifically, in the 5 - 15 years window, the UK industry will directly benefit if the outcomes of the research lead to more developed and focussed academic-industry collaborations (Innovate UK / Knowledge Transfer Partnerships). The potential IP that could be generated in the area of energy storage and carbon capture will yield opportunities for spin-out companies, providing employment opportunities and adding value to the UK economy.
Societal benefits will include, for example:
- balance the CO2 emissions and maximise the electrical energy supplies to meet the net-zero target by 2050;
- large-scale employment of renewable energies and thus the transition to a low carbon society;
- enhancement of the UK's energy security and environmental sustainability.
In the short-term (1-3 years), this project will provide highly skilled researchers who will have developed multidisciplinary skills and will have experienced a broad range of technological fields that are important for R&D programmes required for market innovation for Li-CO2 battery technology and beyond.
The PI will benefit from several new collaborations with NPL, Johnson Matthey and QinetiQ, in addition to the above-established collaborations associated with the PI's current research programmes. The UK-based and international partners are committed to supporting aspects of this project within their research capacity. Further collaboration with leading groups and the development of multidisciplinary research projects will be fostered during this project.
Publications
Bi J
(2022)
A Highly integrated flexible photo-rechargeable system based on stable ultrahigh-rate quasi-solid-state zinc-ion micro-batteries and perovskite solar cells
in Energy Storage Materials
Chen S
(2023)
Rational catalyst structural design to facilitate reversible Li-CO2 batteries with boosted CO2 conversion kinetics
in Nano Energy
Wang J
(2023)
Advances in thermal-related analysis techniques for solid-state lithium batteries
in InfoMat
Wang M
(2023)
Probing interfacial electrochemistry by in situ atomic force microscope for battery characterization
in Battery Energy
Wang M
(2023)
Developing highly reversible Li-CO 2 batteries: from on-chip exploration to practical application
in Energy & Environmental Science
Yao X
(2022)
Xenon Ion Implantation Induced Surface Compressive Stress for Preventing Dendrite Penetration in Solid-State Electrolytes.
in Small (Weinheim an der Bergstrasse, Germany)
Yao X
(2021)
Degradation Diagnostics from the Subsurface of Lithium-Ion Battery Electrodes
in ENERGY & ENVIRONMENTAL MATERIALS
Yao X
(2023)
Rectifying interphases for preventing Li dendrite propagation in solid-state electrolytes
in Energy & Environmental Science
| Description | In the first year of our project, we have successfully fabricated a versatile on-chip platform for efficient electrocatalyst screening and reaction mechanism investigation of Li-CO2 batteries: On-chip Li-CO2 battery arrays are fabricated and tested with more than 7 typical electrocatalysts, together with the characterisation of product morphology and chemical component via (ex-situ) atomic force microscopy and Raman. On-chip batteries with optimised electrocatalyst yield the lowest polarization (0.58 V), highest reversibility and potential new reaction pathways. In the second year of our project, the reaction pathways and reversible nature of the Li-CO2 batteries were further studied using in situ electrochemical Raman spectroscopy and in-situ atomic force microscopy. The new reaction pathway is supported by the as-mentioned characterisation and ab initio calculations. Moreover, as a result of the platform studies, Li-CO2 coin cells were fabricated and demonstrated an exceptional performance of record low overpotential (~0.55 V), ultrahigh-energy efficiency (up to 90%) and outstanding stability (stable cycling over 1000 hours). |
| Exploitation Route | The multimodal lab-on-a-chip platform has a wide range of applications for other systems, such as metal-air batteries, electrocatalysis, fuel cells, and photoelectrochemical systems, thereby opening up new opportunities for rapid catalyst screening, mechanism investigation, and the development of practical applications. We have had the industrial engagement and reached a consensus with our existing partners, Johnson Matthey (JM) and National Physical Lab(NPL). JM has provided us with many electrocatalysts and we have used our on-chip platform to rapidly screen electrocatalysts, not only for Li-CO2 batteries but also for other applications. I believe our unique platform and advanced testing methods can become very helpful tools to catalyst/chemicals companies (e.g., Johnson Matthey) for rational synthesis and rapid screening of electrocatalysts. Our multimodal lab-on-a-chip platform has also been used at NPL for advanced characterization, including a three-electrode configuration, in situ electrochemical Raman (EC-Raman), and electrochemical atomic force microscopy (EC-AFM), providing a new characterization technology with the enhanced temporal and nano-scale spatial resolution is essential for an improved understanding, better decision-making, and a more informed design of this new technology. As a new negative emissions technology, the Li-CO2 coin cells exhibit the exceptional performance of record low overpotential (~0.55 V), ultrahigh-energy efficiency (up to 90%) and outstan stability. Airbus and Siemens Mobility also show strong interest in Li-CO2 battery technology and committed future investments. |
| Sectors | Chemicals,Energy |
| Description | We have been working with our industrial partners (Johnson Matthey) on the rapid screening of electrocatalysts. Current public knowledge in energy storage/conversion, especially Li-CO2 electrochemical technology, is limited. Thus, we have and will continue to seek opportunities to engage with the general public to promote these technologies. For example, I introduce this technology to the general public via IET talk. It is important to train skilled researchers and let them devote themselves to the development of efficient CO2 fixation and advanced energy storage/conversion technologies, which aligns well with the recent UK National Audit Office Report "Delivering STEM". I enable the PDRA and PhD students to take advantage of professional development courses and equipment training at the university for improving research skills and enable them to develop their communication and management skills. |
| Title | multimodal lab-on-a-chip electrochemical testing platform |
| Description | A pioneering on-chip electrocatalyst screening and electrochemical testing platform is developed with deterministic electrocatalyst loading results in a more economical, efficient, and controllable approach as compared to traditional synthesis or manufacturing methods. This platform allows for the high-throughput evaluation of catalysts and the optimization of operating parameters. Advanced testing and characterisation techniques, including a three-electrode configuration, in situ electrochemical Raman (EC-Raman), and electrochemical atomic force microscopy (EC-AFM), are integrated, providing in-situ probing of decoupled potential analysis, product chemical composition, and morphology evolution. |
| Type Of Material | Improvements to research infrastructure |
| Year Produced | 2022 |
| Provided To Others? | No |
| Impact | This platform allows for the high-throughput evaluation of catalysts, along with the optimization of operating parameters and advanced testing and characterisation. The implementation of this multimodal lab-on-a-chip platform is expected to significantly broaden the understanding and enhance the perception of the development of not only advanced Li-CO2 batteries, but also other systems, such as metal-air batteries, electrocatalysis, fuel cells, and photoelectrochemical cells. It will open up new opportunities for rapid catalyst screening, mechanism investigation, and practical applications, ranging from nanoscience and technology to cutting-edge negative emissions technologies. |
| Description | Johnson Matthey |
| Organisation | Johnson Matthey |
| Country | United Kingdom |
| Sector | Private |
| PI Contribution | JM has offered advice and supports both the technical challenges and commercial aspects of the project. They shared rich experience on catalysis synthesis on large scale as well as provided different electrocatalysts and precursor chemicals to us for free. |
| Collaborator Contribution | We have tested more than 7 typical metal electrocatalysts (some of them comes from JM), together with the characterisation of product morphology and chemical component via in-situ AFM and surface-enhanced Raman. Optimized electrocatalysts based on-chip batteries yield the lowest polarization (0.58 V), highest reversibility and potential new reaction pathways. JM has provided us with many other electrocatalysts and we have used our on-chip platform to rapidly screen, not only for Li-CO2 batteries but also for other applications. |
| Impact | We have tested more than 7 typical metal electrocatalysts (some of them comes from JM), together with the characterisation of product morphology and chemical component via in-situ AFM and surface-enhanced Raman. Optimized electrocatalysts based on-chip batteries yield the lowest polarization (0.58 V), highest reversibility and potential new reaction pathways. JM has provided us with many electrocatalysts and we have used our on-chip platform to rapidly screen, not only for Li-CO2 batteries but also for other applications. |
| Start Year | 2022 |
| Description | National Physical Laboratory |
| Organisation | National Physical Laboratory |
| Country | United Kingdom |
| Sector | Academic/University |
| PI Contribution | The development of innovative measurement techniques for multimodal operando/in situ monitoring of electrochemical reactions is one of the key research areas at NPL. We have successfully developed a unique on-chip multimodal platform with the capability of conducting different innovative measurements, such as three-electrode testing, in-situ atomic force microscopy (AFM) and surface-enhanced Raman. This platform provides a clean surface and well-controlled configuration and could be used for other in situ measurements at NPL. |
| Collaborator Contribution | To assist this project, the Electronic and Magnetic Materials group at NPL has developed state-of-the-art measurement and imaging techniques to study the properties of solid-liquid interface properties of Li-CO2 batteries. In the first year, they have provided free access to surface analysis & interface characterization of on-chip Li-CO2 battery for the battery reversibility and mechanism study, including in-situ Raman and TERS measurements. |
| Impact | We have successfully built the in-situ Raman testing system at NPL and adopted it to investigate the products changes at the discharge and charge process. The changes of Li2CO3 and G peak of carbon have been detected during the discharge process, indicating the high reversibility of on-chip Li-CO2 battery using our screened electrocatalyst. Our multimodal lab-on-a-chip platform has also been used at NPL for advanced characterization, including a three-electrode configuration, in situ electrochemical Raman (EC-Raman), and electrochemical atomic force microscopy (EC-AFM), providing a new characterization technology with the enhanced temporal and nano-scale spatial resolution is essential for an improved understanding, better decision-making, and a more informed design of this new technology. |
| Start Year | 2021 |