Accelerating the development of lithium resources has attracted a great deal of attention with the explosive growth of new energy vehicles.As a new technology,electrochemical lithium ion pumping(ELIP)is featured by en...Accelerating the development of lithium resources has attracted a great deal of attention with the explosive growth of new energy vehicles.As a new technology,electrochemical lithium ion pumping(ELIP)is featured by environment-friendly,low energy consumption and high efficiency.This review summarizes the research progress in ELIP,and focuses on the evaluation methods,electrode materials and electrochemical systems of ELIP.It can be concluded that ELIP is expected to achieve an industrial application and has a promising prospect.In addition,challenges and perspective of electrochemical lithium extraction are also highlighted.展开更多
The rapid commercialization of lithium–ion batteries has caused significant expansion of the lithium demand.Electrochemical lithium ions pump is a promising technology because of its good selectivity and friendly env...The rapid commercialization of lithium–ion batteries has caused significant expansion of the lithium demand.Electrochemical lithium ions pump is a promising technology because of its good selectivity and friendly environment.Herein,an Al_(2)O_(3)–ZrO_(2) film coating of the LiMn_(2)O_(4)(AlZr–LMO) electrode is prepared and operated for recovery of Li^(+)from brine.The Li^(+) maximum extraction capacity of AlZr–LMO reached 49.92 mg/g in one cycle.Compared with the solely LMO electrode,the AlZr–LMO demonstrated evident electrochemical stability and cycle life towards the Li^(+)recovery system.After 30 successive cycles,the extraction capacity for Li^(+)increased from 29.21%to 57.67%.The high cycle capacity of the material could be attributed to its low polarization,high active sites,and good chemical stability of the electrode surface owing to the synergy function of Al_(2)O_(3)–ZrO_(2)in the charging-discharging process.A dynamic model parameter identification method was performed to evaluate the active site of AlZr–LMO.This work may provide a way to design the AlZr–LMO electrode and develop a good method for the recovery of lithium from brine.展开更多
LiMn_(2)O_(4)(LMO)electrochemical lithium-ion pump has gained widespread attention due to its green,high efficiency,and low energy consumption in selectively extracting lithium from brine.However,collapse of crystal s...LiMn_(2)O_(4)(LMO)electrochemical lithium-ion pump has gained widespread attention due to its green,high efficiency,and low energy consumption in selectively extracting lithium from brine.However,collapse of crystal structure and loss of lithium extraction capacity caused by Mn dissolution loss limits its industrialized application.Hence,a multifunctional coating was developed by depositing amorphous AlPO_(4)on the surface of LMO using sol-gel method.The characterization and electrochemical performance test provided insights into the mechanism of Li^(+)embedment and de-embedment and revealed that multifunctional AlPO_(4)can reconstruct the physical and chemical state of LMO surface to improve the interface hydrophilicity,promote the transport of Li^(+),strengthen cycle stability.Remarkably,after 20 cycles,the capacity retention rate of 0.5AP-LMO reached 93.6%with only 0.147%Mn dissolution loss.The average Li^(+)release capacity of 0.5AP-LMO//Ag system in simulated brine is 28.77 mg/(g h),which is 90.4%higher than LMO.Encouragingly,even in the more complex Zabuye real brine,0.5AP-LMO//Ag can still maintain excellent lithium extraction performance.These results indicate that the 0.5AP-LMO//Ag lithium-ion pump shows promising potential as a Li^(+)selective extraction system.展开更多
The extraction of lithium from salt lakes or seawater has attracted worldwide attention because of the explosive growth of global demand for lithium products. The LiMn_(2)O_(4)-based electrochemical lithium recovery s...The extraction of lithium from salt lakes or seawater has attracted worldwide attention because of the explosive growth of global demand for lithium products. The LiMn_(2)O_(4)-based electrochemical lithium recovery system is one of the strongest candidates for commercial application due to its high inserted capacity and low energy consumption. However, the surface orientation of LiMn_(2)O_(4)that facilitates Li diffusion happens to be prone to manganese dissolution making it a great challenge to obtain high lithium inserted capacity and long life simultaneously. Herein, we address this problem by designing a truncated octahedral LiMn_(2)O_(4)(Tr-oh LMO) in which the dominant(111) facets minimize Mn dissolution while a small portion of(100) facets facilitate the Li diffusion. Thus, this Tr-oh LMO-based electrochemical lithium recovery system shows excellent Li recovery performance with high inserted capacity(20.25 mg g^(-1)per cycle) in simulated brine. In addition, the dissolution rate of manganese per 30 cycles is only 0.44% and the capacity maintained 85% of the initial after 30 cycles. These promising findings accelerate the practical application of LiMn_(2)O_(4)in electrochemical lithium recovery.展开更多
In order to satisfy the growing global demand for lithium, selective extraction of lithium from brine has attracted extensive attention. LiMn_(2)O_(4)-based electrochemical lithium recovery system is one of the best c...In order to satisfy the growing global demand for lithium, selective extraction of lithium from brine has attracted extensive attention. LiMn_(2)O_(4)-based electrochemical lithium recovery system is one of the best choices for commercial applications because of its high selectivity and low energy consumption.However, the low ion diffusion coefficient of lithium manganate limits the further development of electrochemical lithium recovery system. In this work, a novel porous disc-like LiMn_(2)O_(4) was successfully synthesized for the first time via two-step annealing manganese(Ⅱ) precursors. The as-prepared LiMn_(2)O_(4) exhibits porous disc-like morphology, excellent crystallinity, high Li^(+)diffusion coefficient(average 7.6×10^(-9)cm^(2)·s^(-1)), high cycle stability(after 30 uninterrupted extraction and release cycles, the crystal structure hardly changed) and superior rate capacity(93.5% retention from 10-120 mA·g^(-1)). The porous structure and disc-like morphology further promote the contact between lithium ions and electrode materials. Therefore, the assembled electrochemical lithium extraction device with LiMn_(2)O_(4) as positive electrode and silver as negative electrode can realize the rapid and selective extraction of lithium in simulated brine(adsorption capacity of lithium can reach 4.85 mg·g^(-1) in 1 h). The mechanism of disc-like LiMn_(2)O_(4) in electrochemical lithium extraction was proposed based on the analysis of electrochemical characterization and quasi in situ XRD. This novel structure may further promote the practical application of electrochemical lithium extraction from brine.展开更多
Lithium is an important raw material for new energy-powered vehicles,and ensuring its supply is of great significance for global green and sustainable development.Salt lake brine is the main lithium resource,but the s...Lithium is an important raw material for new energy-powered vehicles,and ensuring its supply is of great significance for global green and sustainable development.Salt lake brine is the main lithium resource,but the separation of Li+from coexisting metals poses a major challenge.In this work,a lithium-storing metal oxide SnO2 nanoparticle island-modified LiMn_(2)O_(4) electrode material is designed to endow LiMn_(2)O_(4) with higher lithium extraction capacity and cycling stability.The SnO2 nanoparticle islands effectively mitigate stress during the charge–discharge process of LiMn_(2)O_(4),thereby enhancing cycling stability and promoting the diffusion of Li+.The lithium adsorption capacity of the LiMn_(2)O_(4) electrode material modified with SnO2 nanoparticles reaches 19.76 mg g^(-1) within 1 hour,which is 1.7 times higher than that of LiMn_(2)O_(4)(11.45 mg g^(-1)).The LiMn_(2)O_(4) electrode material modified with SnO2 nanoparticles shows good selectivity and cycling stability for the separation of lithium ions.展开更多
With more and more lithium-ion batteries(LIBs)being put into production and application,precious metals such as lithium and cobalt are scarce,so it is imminent to recover various strategic metal resources from spent L...With more and more lithium-ion batteries(LIBs)being put into production and application,precious metals such as lithium and cobalt are scarce,so it is imminent to recover various strategic metal resources from spent LIBs.Meanwhile,the complex and difficult problem of separating and recovering metals from leaching solutions has been an urgent question that needs to be resolved.In this work,a phosphoric acid-based deep eutectic solvent(DES)was developed for extracting metals from spent LIBs and one-step selectively separating and efficiently recovering transition metal.The prepared DES shows excellent extraction performance for Li(100%)and Co(92.8%)at 100°C.In addition,the extraction system can effectively separate and precipitate Co through its own components,avoiding the introduction of new precipitants and the destruction of the original composition structure of DES.This also contributes to the good cycle stability of the extraction system with excellent extraction performance for Li(94.3%)and Co(80.8%)after 5 cycles.This work proposes a green method for one-step selectively separating and recovering valuable metals from spent LIBs.展开更多
基金supported by the National Natural Science Foundation of China(grant numbers 21878133,21908082 and 21722604)the Natural Science Foundation of Jiangsu Province(BK20190854)+2 种基金the China Postdoctoral Science Foundation(2020M671364)the Postgraduate Research&Practice Innovation Program of Jiangsu Province(KYCX191622)the Science&Technology Foundation of Zhenjiang(GY2020027)。
文摘Accelerating the development of lithium resources has attracted a great deal of attention with the explosive growth of new energy vehicles.As a new technology,electrochemical lithium ion pumping(ELIP)is featured by environment-friendly,low energy consumption and high efficiency.This review summarizes the research progress in ELIP,and focuses on the evaluation methods,electrode materials and electrochemical systems of ELIP.It can be concluded that ELIP is expected to achieve an industrial application and has a promising prospect.In addition,challenges and perspective of electrochemical lithium extraction are also highlighted.
基金supported by the National Natural Science Foundation of China (21878133, 21908082, 22178154)the Natural Science Foundation of Jiangsu Province (BK20190854)+1 种基金the China Postdoctoral Science Foundation (2020M671364, 2021M701472)the Science & Technology Foundation of Zhenjiang (GY2020027)。
文摘The rapid commercialization of lithium–ion batteries has caused significant expansion of the lithium demand.Electrochemical lithium ions pump is a promising technology because of its good selectivity and friendly environment.Herein,an Al_(2)O_(3)–ZrO_(2) film coating of the LiMn_(2)O_(4)(AlZr–LMO) electrode is prepared and operated for recovery of Li^(+)from brine.The Li^(+) maximum extraction capacity of AlZr–LMO reached 49.92 mg/g in one cycle.Compared with the solely LMO electrode,the AlZr–LMO demonstrated evident electrochemical stability and cycle life towards the Li^(+)recovery system.After 30 successive cycles,the extraction capacity for Li^(+)increased from 29.21%to 57.67%.The high cycle capacity of the material could be attributed to its low polarization,high active sites,and good chemical stability of the electrode surface owing to the synergy function of Al_(2)O_(3)–ZrO_(2)in the charging-discharging process.A dynamic model parameter identification method was performed to evaluate the active site of AlZr–LMO.This work may provide a way to design the AlZr–LMO electrode and develop a good method for the recovery of lithium from brine.
基金supported by the National Natural Science Foundation of China(21908082,22278426,and 22178154)the Jiangsu Funding Program for Excellent Postdoctoral Talent(2022ZB629)+1 种基金the Natural Science Foundation of Jiangsu Province(BK20221367)the China Postdoctoral Science Foundation(2021M701472)。
文摘LiMn_(2)O_(4)(LMO)electrochemical lithium-ion pump has gained widespread attention due to its green,high efficiency,and low energy consumption in selectively extracting lithium from brine.However,collapse of crystal structure and loss of lithium extraction capacity caused by Mn dissolution loss limits its industrialized application.Hence,a multifunctional coating was developed by depositing amorphous AlPO_(4)on the surface of LMO using sol-gel method.The characterization and electrochemical performance test provided insights into the mechanism of Li^(+)embedment and de-embedment and revealed that multifunctional AlPO_(4)can reconstruct the physical and chemical state of LMO surface to improve the interface hydrophilicity,promote the transport of Li^(+),strengthen cycle stability.Remarkably,after 20 cycles,the capacity retention rate of 0.5AP-LMO reached 93.6%with only 0.147%Mn dissolution loss.The average Li^(+)release capacity of 0.5AP-LMO//Ag system in simulated brine is 28.77 mg/(g h),which is 90.4%higher than LMO.Encouragingly,even in the more complex Zabuye real brine,0.5AP-LMO//Ag can still maintain excellent lithium extraction performance.These results indicate that the 0.5AP-LMO//Ag lithium-ion pump shows promising potential as a Li^(+)selective extraction system.
基金supported by the National Natural Science Foundation of China (21878133,21908082,22178154)the Natural Science Foundation of Jiangsu Province(BK20190854)+1 种基金the China Postdoctoral Science Foundation(2020M671364,2021M701472)the Science&Technology Foundation of Zhenjiang (GY2020027)。
文摘The extraction of lithium from salt lakes or seawater has attracted worldwide attention because of the explosive growth of global demand for lithium products. The LiMn_(2)O_(4)-based electrochemical lithium recovery system is one of the strongest candidates for commercial application due to its high inserted capacity and low energy consumption. However, the surface orientation of LiMn_(2)O_(4)that facilitates Li diffusion happens to be prone to manganese dissolution making it a great challenge to obtain high lithium inserted capacity and long life simultaneously. Herein, we address this problem by designing a truncated octahedral LiMn_(2)O_(4)(Tr-oh LMO) in which the dominant(111) facets minimize Mn dissolution while a small portion of(100) facets facilitate the Li diffusion. Thus, this Tr-oh LMO-based electrochemical lithium recovery system shows excellent Li recovery performance with high inserted capacity(20.25 mg g^(-1)per cycle) in simulated brine. In addition, the dissolution rate of manganese per 30 cycles is only 0.44% and the capacity maintained 85% of the initial after 30 cycles. These promising findings accelerate the practical application of LiMn_(2)O_(4)in electrochemical lithium recovery.
基金supported by the National Natural Science Foundation of China (21878133, 21908082, 22178154)the Natural Science Foundation of Jiangsu Province (BK20190854)+1 种基金the China Postdoctoral Science Foundation (2020 M671364, 2021 M701472)the Science & Technology Foundation of Zhenjiang (GY2020027)。
文摘In order to satisfy the growing global demand for lithium, selective extraction of lithium from brine has attracted extensive attention. LiMn_(2)O_(4)-based electrochemical lithium recovery system is one of the best choices for commercial applications because of its high selectivity and low energy consumption.However, the low ion diffusion coefficient of lithium manganate limits the further development of electrochemical lithium recovery system. In this work, a novel porous disc-like LiMn_(2)O_(4) was successfully synthesized for the first time via two-step annealing manganese(Ⅱ) precursors. The as-prepared LiMn_(2)O_(4) exhibits porous disc-like morphology, excellent crystallinity, high Li^(+)diffusion coefficient(average 7.6×10^(-9)cm^(2)·s^(-1)), high cycle stability(after 30 uninterrupted extraction and release cycles, the crystal structure hardly changed) and superior rate capacity(93.5% retention from 10-120 mA·g^(-1)). The porous structure and disc-like morphology further promote the contact between lithium ions and electrode materials. Therefore, the assembled electrochemical lithium extraction device with LiMn_(2)O_(4) as positive electrode and silver as negative electrode can realize the rapid and selective extraction of lithium in simulated brine(adsorption capacity of lithium can reach 4.85 mg·g^(-1) in 1 h). The mechanism of disc-like LiMn_(2)O_(4) in electrochemical lithium extraction was proposed based on the analysis of electrochemical characterization and quasi in situ XRD. This novel structure may further promote the practical application of electrochemical lithium extraction from brine.
基金supported by the National Key R&D Program of China(No.2022YFE0208300)the National Natural Science Foundation of China(No.22278426 and 21908082)the Science Foundation of China University of Petroleum,Beijing(No.2462024XKBH001,2462022YJRC003,2462022YJRC002).
文摘Lithium is an important raw material for new energy-powered vehicles,and ensuring its supply is of great significance for global green and sustainable development.Salt lake brine is the main lithium resource,but the separation of Li+from coexisting metals poses a major challenge.In this work,a lithium-storing metal oxide SnO2 nanoparticle island-modified LiMn_(2)O_(4) electrode material is designed to endow LiMn_(2)O_(4) with higher lithium extraction capacity and cycling stability.The SnO2 nanoparticle islands effectively mitigate stress during the charge–discharge process of LiMn_(2)O_(4),thereby enhancing cycling stability and promoting the diffusion of Li+.The lithium adsorption capacity of the LiMn_(2)O_(4) electrode material modified with SnO2 nanoparticles reaches 19.76 mg g^(-1) within 1 hour,which is 1.7 times higher than that of LiMn_(2)O_(4)(11.45 mg g^(-1)).The LiMn_(2)O_(4) electrode material modified with SnO2 nanoparticles shows good selectivity and cycling stability for the separation of lithium ions.
基金the financial support for the financial supports from the National Natural Science Foundation of China(grant Nos.21908082,22278426,21878133,and 22178154)the Natural Science Foundation of Jiangsu Province(BK20190854)+1 种基金Jiangsu Funding Program for Excellent Postdoctoral Talent(2022ZB629)the China Postdoctoral Science Foundation(2021M701472)
文摘With more and more lithium-ion batteries(LIBs)being put into production and application,precious metals such as lithium and cobalt are scarce,so it is imminent to recover various strategic metal resources from spent LIBs.Meanwhile,the complex and difficult problem of separating and recovering metals from leaching solutions has been an urgent question that needs to be resolved.In this work,a phosphoric acid-based deep eutectic solvent(DES)was developed for extracting metals from spent LIBs and one-step selectively separating and efficiently recovering transition metal.The prepared DES shows excellent extraction performance for Li(100%)and Co(92.8%)at 100°C.In addition,the extraction system can effectively separate and precipitate Co through its own components,avoiding the introduction of new precipitants and the destruction of the original composition structure of DES.This also contributes to the good cycle stability of the extraction system with excellent extraction performance for Li(94.3%)and Co(80.8%)after 5 cycles.This work proposes a green method for one-step selectively separating and recovering valuable metals from spent LIBs.
