BioElectrochemical LIthium rEcoVEry (BELIEVE)
Lead Research Organisation:
University of Surrey
Department Name: Microbial & Cellular Sciences
Abstract
There is an increasing demand for Li-ion batteries (LiB) in portable electronic devices and energy storage in stationary applications and electric vehicles. Lithium (Li) is a high-tech metal found only in a few locations worldwide, and its extraction is costly, energy-demanding and pollutes the environment. The demand for batteries has resulted in an ever-increasing amount of used and spent LiB, containing large amounts of Li. Current Li recovery and recycling methods are complex, expensive, and environmentally damaging, so it is necessary to develop efficient alternative methods.
Biotechnology-based methods for recovering metals represent a promising approach to integrating and/or replacing current technologies. Those methods use the metabolic capabilities of microorganisms to carry out processes typically done using physicochemical approaches. One such bio-based strategy is the exploitation of the ability of some microbial species to transfer electrons to solid external electron acceptors, such as metals or electrodes, an approach known as microbial electrochemical technology. This project aims to design and optimise a bioelectrochemical system (BES) to recover high purity Li.
In BESs such as microbial fuel cells (MFCs), electrical energy is produced from the microbial degradation in the anode of organic compounds (e.g., wastewaters). Microorganisms degrade nutrients and transfer electrons to the anode; the electrons circulate to the cathode, generating an electric current. In the cathode, the electrons are used to reduce an electron acceptor (e.g., metals). When the cathode is colonised by microorganism able to transfer the electrons to Li, high purity recyclable Li can be recovered from waste streams.
In this project, we will design and analyse a microbial electrochemical system for the recovery of Li from actual LiB waste, focusing on the main aspects affecting the process, such as the microorganisms and their capabilities, the design of the system (configuration, types of electrodes, catalysts, metal concentration, etc.), and the operational conditions that produce increased yields and efficiencies of Li recovery. We will screen diverse microbial species and communities for their capability to remove Li from the waste and test them in different reactor designs (microbial fuel cell, microbial electrochemical cell, microbial desalination cell and tubular reactors). We will conduct a detailed life cycle assessment and techno-economic analysis to evaluate the environmental and economic implications of the process, which will allow us to explore the feasibility of economic scales of operation and understand the role of bio-based metal recycling in the circular economy.
The combination of experimental approaches with sustainability assessment will provide a clear understanding of the system and generate strategies for scale-up. The project will deliver an optimal biotechnology-based solution for attaining high purity and yield of Li from LiB waste. Recovered Li can be returned to LiB, which will be proven by testing its quality to complete the economic circularity of Li.
Biotechnology-based methods for recovering metals represent a promising approach to integrating and/or replacing current technologies. Those methods use the metabolic capabilities of microorganisms to carry out processes typically done using physicochemical approaches. One such bio-based strategy is the exploitation of the ability of some microbial species to transfer electrons to solid external electron acceptors, such as metals or electrodes, an approach known as microbial electrochemical technology. This project aims to design and optimise a bioelectrochemical system (BES) to recover high purity Li.
In BESs such as microbial fuel cells (MFCs), electrical energy is produced from the microbial degradation in the anode of organic compounds (e.g., wastewaters). Microorganisms degrade nutrients and transfer electrons to the anode; the electrons circulate to the cathode, generating an electric current. In the cathode, the electrons are used to reduce an electron acceptor (e.g., metals). When the cathode is colonised by microorganism able to transfer the electrons to Li, high purity recyclable Li can be recovered from waste streams.
In this project, we will design and analyse a microbial electrochemical system for the recovery of Li from actual LiB waste, focusing on the main aspects affecting the process, such as the microorganisms and their capabilities, the design of the system (configuration, types of electrodes, catalysts, metal concentration, etc.), and the operational conditions that produce increased yields and efficiencies of Li recovery. We will screen diverse microbial species and communities for their capability to remove Li from the waste and test them in different reactor designs (microbial fuel cell, microbial electrochemical cell, microbial desalination cell and tubular reactors). We will conduct a detailed life cycle assessment and techno-economic analysis to evaluate the environmental and economic implications of the process, which will allow us to explore the feasibility of economic scales of operation and understand the role of bio-based metal recycling in the circular economy.
The combination of experimental approaches with sustainability assessment will provide a clear understanding of the system and generate strategies for scale-up. The project will deliver an optimal biotechnology-based solution for attaining high purity and yield of Li from LiB waste. Recovered Li can be returned to LiB, which will be proven by testing its quality to complete the economic circularity of Li.
Technical Summary
The increased use of Li-ion batteries (LiB) has caused a high demand for Li, a high-tech metal found only in a few locations worldwide. Li production is costly, energy-demanding, and environmentally damaging: It is essential to design and optimize methods for recovery spent Li. Li recycling is complex, expensive and inefficient, recovering only a small quantity of low-grade Li. The EU Green Deal 2020 set regulations to achieve 65% recycling efficiency for LiB and 70% material recovery rate for Li by 2030.
Similar regulations are expected to be introduced in the UK to ensure the high recovery of strategic metals.
We will design and optimise a bioelectrochemical system (to recover high purity Li. Exploiting the ability of some microbial species to transfer electrons to external acceptors, we will design a microbial electrochemical system to recover Li from LiB waste, focusing on the main aspects affecting the process: microorganisms, reactor configuration, electrodes, metal concentration, substrates, etc. We will screen diverse microbial species and microbial communities for their capability to remove Li from the waste and test them in different reactor designs (MFC, MEC, MDC, tubular). This will provide a qualitative and quantitative correlation between metal removal, the composition of the microbial community, electrochemical performance and the characterisation of different designs of microbial electrochemical reactors for efficient processing of LiB.
We will conduct a detailed life cycle assessment and techno-economic analysis to analyse the environmental and economic implications of the process to reach circular economy-focused policy requirements. Combining sustainability assessment with experimentation will facilitate understanding of the system and guide scale-up strategies. The ultimate objective is the optimisation of this biotechnology-based solution for attaining high purity and yield of recyclable Li from spent LiB's black mass waste.
Similar regulations are expected to be introduced in the UK to ensure the high recovery of strategic metals.
We will design and optimise a bioelectrochemical system (to recover high purity Li. Exploiting the ability of some microbial species to transfer electrons to external acceptors, we will design a microbial electrochemical system to recover Li from LiB waste, focusing on the main aspects affecting the process: microorganisms, reactor configuration, electrodes, metal concentration, substrates, etc. We will screen diverse microbial species and microbial communities for their capability to remove Li from the waste and test them in different reactor designs (MFC, MEC, MDC, tubular). This will provide a qualitative and quantitative correlation between metal removal, the composition of the microbial community, electrochemical performance and the characterisation of different designs of microbial electrochemical reactors for efficient processing of LiB.
We will conduct a detailed life cycle assessment and techno-economic analysis to analyse the environmental and economic implications of the process to reach circular economy-focused policy requirements. Combining sustainability assessment with experimentation will facilitate understanding of the system and guide scale-up strategies. The ultimate objective is the optimisation of this biotechnology-based solution for attaining high purity and yield of recyclable Li from spent LiB's black mass waste.
Organisations
Publications
Muazu RI
(2023)
Hexavalent chromium waste removal via bioelectrochemical systems - a life cycle assessment perspective.
in Environmental science : water research & technology
| Description | We have developed a process for recovery of Lithium (and potentially, other metals) from exhausted lithium batteries (LiB). The process involves a combination of various techniques ranging from microbiological processes to microbial electrochemistry. Typically, exhausted LiB are mechanically disrupted to recover some materials, but a residue is generated (called "black mass") which is an extremely fine powder of complex composition, and contains large amounts of metal salts (lithium, cobalt, nickel, etc). The black mass can be dissolved using strong mineral acids, generating an extremely corrosive liquid containing all the metals in solution. It is possible to recover the metals using electrochemical methods, which require the input of electrical power leaving an acidic solution as waste. Our process combines the dissolution of the black mass using an organic acid produced by a microorganism. which dissolves the metals in the black mass. The liquid produced (called "bioleachate") is then fed into a device called a microbial fuel cell (MFC), which consists of one anodic chamber and one cathodic chamber separated by an ion exchange membrane. The anodic chamber is inoculated with electroactive microorganisms that colonise the anode and oxidise the organic matter contained in the liquid filling the chamber, and the cathodic chamber contains an electron acceptor. The electrons generated by the oxidation of organic matter are transferred to the anode and circulate across an external circuit towards the cathode, where they are used to reduce the electron acceptors in the catholyte. In our system, lithium and other positive ions in the bioleachate are driven towards the cathodic chamber where they form a precipitate which can be separated and purified. An external potential is introduced to drive the movement of Lithium. The electric potential produced by the microorganisms offsets the demand of external electric power by approx 30%. |
| Exploitation Route | We are exploring the possibility of protecting the findings via a patent: this can be taken forward for commercial exploitation. We will also submit a research proposal to use the same approach to the recovery and recycling of other metals in LiB waste (Ni, Mn, Co). |
| Sectors | Chemicals Environment Manufacturing including Industrial Biotechology |
| Description | We are in the process of protecting our development by a filing a patent, whcih could lead to the commercial exploitation of the process. Our research aims to significantly enhance the UK's capability to recycle the metals present in the waste of lithium-ion battery and secure an enduring domestic supply of critical metals. Global demand for LiBs, driven by electric vehicles, consumer electronics, and renewable energy storage, has risen sharply in recent years. In 2022, worldwide EV sales represented a 60% increase over 2021, and by 2030, the International Energy Agency projects that the global EV fleet could exceed 140 million. This immense scale underscores the urgency for advanced recycling methods to recover and reintroduce critical materials into the supply chain. Our research is timely and necessary, given the rapid global expansion of EV fleets and projected surges in end-of-life LIBs. In the UK specifically, sales of battery electric vehicles doubled year-on-year in 2021 and show no signs of slowing. Traditional landfilling or partial recovery methods squander valuable resources and pose environmental risks. Our recycling technology curtails chemical and energy inputs, addressing the pressing demand for critical metals and minimizing environmental harm. Furthermore, this integrated technology will reduce the overall carbon footprint of battery recycling, an increasingly urgent priority as the UK drives toward net-zero targets. The societal and economic benefits are equally significant. Recovering critical metals curbs dependence on imports, strengthens the UK's EV supply chain, and fosters a robust circular economy. |
| First Year Of Impact | 2024 |
| Sector | Chemicals,Manufacturing, including Industrial Biotechology,Other |
| Impact Types | Economic |
| Description | BIOREM - Systems Biology, Artificial Intelligence and Advanced BiOtechnology Approaches to Improve Soil BioREMediation |
| Amount | £80,084 (GBP) |
| Funding ID | APP59305 |
| Organisation | Biotechnology and Biological Sciences Research Council (BBSRC) |
| Sector | Public |
| Country | United Kingdom |
| Start | 01/2025 |
| End | 12/2028 |
| Description | Microbes that listen: Sono-bio technology for persistent organic pollutants |
| Amount | £950,000 (GBP) |
| Funding ID | APP27753 |
| Organisation | University of Surrey |
| Sector | Academic/University |
| Country | United Kingdom |
| Start | 03/2025 |
| End | 02/2027 |