Recent advances in lithiophilic materials: material design and prospects for lithium metal anode application

Recent advances in lithiophilic materials: material design and prospects for lithium metal anode application
Author: Jiaxiang Liu
Publisher: OAE Publishing Inc.
Total Pages: 27
Release: 2023-05-19
Genre: Technology & Engineering
ISBN:
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The rapid development of electronic technology and energy industry promotes the increasing desire for energy storage systems with high energy density, thus calling for the exploration of lithium metal anode. However, the enormous challenges, such as uncontrollable lithium deposition, side reaction, infinite volume change and dendrite generation, hinders its application. To address these problems, the deposition behavior of lithium must be exactly controlled and the anode/electrolyte interface must be stabilized. The deposition of lithium is a multi-step process influenced by multi-physical fields, where nucleation is the key to final morphology. Hence, increasing investigations have focused on the employment of lithiophilic materials that can regulate lithium nucleation in recent years. The lithiophilic materials introduced into the deposition hosts or solid electrolyte interphases can regulate the nucleation overpotential and facilitate uniform deposition. However, the concept of lithiophilicity is still undefined and the mechanism is still unrevealed. In this review, the recent advances in the regulation mechanisms of lithiophilicity are discussed, and the applications of lithiophilic materials in hosts and protective interphases are summarized. The in-depth exploration of lithiophilic materials can enhance our understanding of the deposition behavior of lithium and pave the way for practical lithium metal batteries.

Recent advances in lithiophilic materials: material design and prospects for lithium metal anode application

Recent advances in lithiophilic materials: material design and prospects for lithium metal anode application
Author: Jiaxiang Liu
Publisher: OAE Publishing Inc.
Total Pages: 27
Release: 2023-05-19
Genre: Technology & Engineering
ISBN:
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Download Recent advances in lithiophilic materials: material design and prospects for lithium metal anode application Book in PDF, Epub and Kindle

The rapid development of electronic technology and energy industry promotes the increasing desire for energy storage systems with high energy density, thus calling for the exploration of lithium metal anode. However, the enormous challenges, such as uncontrollable lithium deposition, side reaction, infinite volume change and dendrite generation, hinders its application. To address these problems, the deposition behavior of lithium must be exactly controlled and the anode/electrolyte interface must be stabilized. The deposition of lithium is a multi-step process influenced by multi-physical fields, where nucleation is the key to final morphology. Hence, increasing investigations have focused on the employment of lithiophilic materials that can regulate lithium nucleation in recent years. The lithiophilic materials introduced into the deposition hosts or solid electrolyte interphases can regulate the nucleation overpotential and facilitate uniform deposition. However, the concept of lithiophilicity is still undefined and the mechanism is still unrevealed. In this review, the recent advances in the regulation mechanisms of lithiophilicity are discussed, and the applications of lithiophilic materials in hosts and protective interphases are summarized. The in-depth exploration of lithiophilic materials can enhance our understanding of the deposition behavior of lithium and pave the way for practical lithium metal batteries.

Materials Design and Fundamental Understanding of Lithium Metal Anode for Next-generation Batteries

Materials Design and Fundamental Understanding of Lithium Metal Anode for Next-generation Batteries
Author: Yayuan Liu
Publisher:
Total Pages:
Release: 2018
Genre:
ISBN:
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Lithium batteries profoundly impact our society, from portable electronics to the electrification of transportation and even to grid−scale energy storage for intermittent renewable energies. In order to achieve much higher energy density than the state−of−the−art, new battery chemistries are currently being actively investigated. Among all the possible material choices, metallic lithium is the ultimate candidate for battery anode, thanks to its highest theoretical capacity. Therefore, after falling into oblivion for several decades due to safety concerns, metallic Li is now ready for a revival. In the first chapter, I introduce the working mechanisms and limitations of the state−of−the−art battery chemistries and provide an overview of promising new battery chemistries based on metallic lithium anode. The current status of lithium metal anode research is also comprehensively summarized. In the second chapter, I discuss one particular failure mode of metallic lithium anode that has long been overlooked by the battery community, which is the infinite relative volume change of the electrode during cycling. To tackle this problem, novel three−dimensional lithium metal−host material composite designs will be demonstrated. Chapter three focuses on further improving the electrochemical performance of three−dimensional lithium metal anodes with surface coatings. Two examples of lithium metal coatings are given, which have been demonstrated effective for protecting reactive lithium from parasitic reactions with liquid electrolytes and mechanically suppressing nonuniform lithium deposition morphology. Chapter four discusses how the physiochemical properties of the solid−electrolyte interphase, dictated by electrolyte composition, affect the electrochemical behavior of metallic lithium. A special electrolyte additive has been discovered to enable high efficiency lithium cycling in carbonate−based electrolytes used exclusively in almost all commercial lithium-ion batteries. Moreover, the mechanisms behind the improved performance have been studied based on the structure, ion−transport properties, and charge−transfer kinetics of the modified interfacial environment using advanced characterization techniques. In Chapter five, I explore a paradigm shift in designing solid−state lithium metal batteries based on three−dimensional lithium architecture and a flowable interfacial layer. The new design concept can be generally applied to various solid electrolyte systems and the resulting solid-state batteries are capable of high−capacity, high−power operations. In the final part of the dissertation, I present my perspectives and outlooks for the future research in this field. The commercialization of high−energy and safe batteries based on lithium metal chemistry requires continuous efforts in various aspects, including electrode design, electrolyte engineering, development of advanced characterization/diagnosis technologies, full−battery engineering, and possible sensor design for safe battery operation, etc. Ultimately, the combinations of various approaches might be required to make lithium metal anode a viable technology.

Low-Cost and Scalable Material Designs and Processes for Next-Generation Lithium-Ion Battery Anodes

Low-Cost and Scalable Material Designs and Processes for Next-Generation Lithium-Ion Battery Anodes
Author: Jesse Adam Baucom
Publisher:
Total Pages: 112
Release: 2020
Genre:
ISBN:
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Modern human civilization depends on the production and utilization of vast quantities of energy. While innovations in technology are generally met with applause, discoveries over the potential catastrophic impacts of our current ways of generating energy on our climate and society have prompted worldwide efforts to mitigate these issues. Although environmentally-friendly and sustainable methods for electricity generation such as solar photovoltaic energy hold promise for solving our energy issues, a complete shift towards renewable energy would require the development of grid-scale energy storage systems due to the intermittent nature of such technology. In addition, the automotive industry is undergoing a complete transformation to electrification in efforts to reduce the environmental impact of vehicles and comply with increasingly stringent regulations, representing yet another urgent need for high-performance energy storage systems. Of all energy storage technologies for potentially enabling grid storage and electric vehicles, lithium-ion batteries are of particular interest due to their rechargeability, high energy and power densities, and energy efficiency. Although lithium-ion batteries are now widely used for a variety of applications, their prohibitively high cost has prevented their application in these crucial technologies. For specific applications such as electric vehicles and portable electronics, lithium-ion batteries have yet to achieve the energy and power density requirements necessary, posing additional barriers. On top of these obstacles, the commercial viability of lithium-ion batteries for these applications depends on the ability to scale up the production processes to satisfy the market need, creating yet another challenge for solving these important issues. While the development of high-capacity anode materials for lithium-ion batteries is a promising route towards enabling these applications, many of the novel designs for such materials are prohibitively expensive or difficult to scale, preventing them from achieving widespread market adoption. In this dissertation, we describe novel materials and processes for producing three high-capacity anode materials of great industry and academic interest: graphene, silicon, and lithium metal. First, we present a novel method for induction heating-mediated synthesis of freestanding anodes for improving the scalability of traditional chemical vapor deposition processes through reduced process downtimes while enabling higher energy and volumetric densities in lithium-ion batteries by virtue of the freestanding nature of the electrode design, reducing the mass and volume of electrochemically-inactive components. Next, we describe a method for the production of silicon/PVA/graphite composite anodes with long cycling life through the use of a 1-step ball milling method utilizing low-cost precursors for scalable production of high-capacity anode materials. Finally, we reveal a design for air-stable lithium metal hosts fabricated from a scalable powder metallurgic approach, which allows for the fabrication of high-performance lithium metal batteries compatible with existing infrastructure, circumventing the need for a high-cost assembly in an inert atmosphere.

Molecular-level Material Designs for Realistic Lithium Batteries

Molecular-level Material Designs for Realistic Lithium Batteries
Author: Zhiao Yu
Publisher:
Total Pages:
Release: 2022
Genre:
ISBN:
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Lithium (Li)-ion batteries have become the pivot of modern energy storage due to their predominant role in powering consumer electronics and electric vehicles. However, with mature manufacturing and production, the energy density of current Li-ion batteries is reaching the theoretical limit. Substantial efforts in both academia and industry are being made to invent next-generation battery chemistries, such as near-future trending Li-ion electrodes including silicon (Si) based anodes, high-voltage LiNi0.5Mn1.5O4 (LNMO) cathode, layered Li-rich Mn-based oxide (LLMO) cathodes, etc. and far-future high-energy Li metal batteries. For near-future Li-ion chemistries such as Si based anodes, LNMO and LLMO cathodes, the existing electrolyte technologies are far from satisfaction. Therefore, liquid electrolyte engineering becomes a pragmatic and imperative approach, and calls for rational design and in-depth understanding of new electrolytes. Li metal battery is a technology existed and commercialized before Li-ion counterpart but forsaken due to safety issues. The kernel, Li metal anodes, endows batteries with high specific energy; however, this is accomplished at the expense of reduced cycle life and increased safety hazards due to the extremely high reactivity and volume fluctuation of Li metal anodes. Therefore, continuous developments of Li metal batteries are demanded to meet the requirements of practical applications. In Chapter 1, background will be provided on current status and recent research efforts of next-generation Li-ion and Li metal batteries. In Chapter 2 and 3, material design artificial solid-electrolyte interphase for protecting Li metal anodes will be discussed. In Chapters 4 and 5, liquid electrolyte engineering and iterative tuning of molecular structure will be elaborated. In Chapter 6, fine tuning of carbonate electrolytes will be demonstrated in the trending Li-ion batteries for near-future practical applications. In Chapter 7, summary and promising directions of future battery developments will be outlooked.

Quantitatively Designing Lithium Metal Batteries for Practical Applications

Quantitatively Designing Lithium Metal Batteries for Practical Applications
Author: Bingyu Lu
Publisher:
Total Pages: 0
Release: 2023
Genre:
ISBN:
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Lithium-ion battery (LIB) has been playing a vital part in the rapid adoption of electric vehicles and portable electronics. However, due to the limited energy density and poor safety properties of the current generation LIB, the development of longer-range electric vehicles has been largely hindered. There is an urgent need for the new material design for the next generation of LIB, especially on the anode side. Among all the candidates, lithium metal is considered as the holy grail for the next generation battery anodes because of its high theoretical capacity (3,860 mAh/g, or 2,061 mAh/cm3) and low electrochemical potential (-3.04 V versus the standard hydrogen electrode). Although extensive works have been done to prolong the cycle life of Li-metal batteries, including electrolyte engineering, interphase design, there are still a lot of studies need to be performed before the commercialization of the Lithium metal battery (LMB). Here, by utilizing a series of characterization tools, the mechanical behaviors, corrosion process and safety properties of the Lithium metal anode in liquid electrolytes have been quantitatively studied. In addition to that, a porous copper current collector is also designed and synthesized for Lithium metal anode with high cycling Coulombic efficiency (CE). To study how the mechanical properties of the Lithium metal anode would affect the performance of the LMB, a split cell with pressure load cell is designed to precisely control the external stack pressure on the LMB during cycling. By employing Cryogenic Focused Ion Beam/Scanning Electron Microscopy (Cryo FIB/SEM) and Cryogenic Electron Microscopy (Cryo-EM), the effects of external uniaxial stack pressure on the Lithium metal plating/stripping are systematically explored. It is found that by applying a 350-kPa stack pressure on the cell, a nearly 100% dense Lithium can be plated in the electrochemical process. The reversibility of this ultra-dense Lithium is also demonstrated up to 30 cycles. Next, by using three dimensional (3D) reconstruction from Cryo FIB/SEM and Titration Gas Chromatography, the chemical corrosion process of the Lithium metal in liquid electrolyte is thoroughly understood. It is shown that by limiting the contact surface area between the Lithium metal and the electrolyte, the chemical corrosion of the Lithium metal can be largely mitigated. In addition to that, a stable Solid Electrolyte Interphase (SEI) is also crucial for the chemical stability of the Lithium metal anode. The optimized Lithium anode shows less than 0.8% active material loss after 10 days of corrosion in liquid electrolyte. Lastly the safety property of the LMB is quantitatively studied by using Differential Scanning Calorimetry (DSC). The key parameters in controlling the reactivity of the LMB is presented. It is shown that the morphology of the Lithium metal anode, the thermal stability of the cathode and the electrolyte salts and solvents all play a synergetic role in the overall safety of the LMB. By optimizing the all the parameters, a safe LMB is demonstrated which shows no thermal response up to 400 ̊C.

Development of Lithium Powder Based Anode with Conductive Carbon Materials for Lithium Batteries

Development of Lithium Powder Based Anode with Conductive Carbon Materials for Lithium Batteries
Author: Mansu Park
Publisher:
Total Pages:
Release: 2016
Genre:
ISBN:
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Current lithium ion battery with a graphite anode shows stable cycle performance and safety. However, the lithium ion battery still has the limitation of having a low energy density caused by the application of lithium intercalated cathode and anode with low energy density. The combination of high capacity non-lithiated cathode such as sulfur and carbon and lithium metal anode has been researched for a long time to maximize battery's energy density. However, this cell design also has a lot of technical challenges to be solved. Among the challenges, lithium anode's problem related to lithium dendrite growth causing internal short and low cycling efficiency is very serious. Thus, extensive research on lithium metal anode has been performed to solve the lithium dendrite problem and a major part of the research has been focused on the control of the interface between lithium and electrolyte. However, research on lithium anode design itself has not been much conducted. In this research, innovative lithium anode design for less dendrite growth and higher cycling efficiency was suggested. Literature review for the lithium dendrite growth mechanism was conducted in Chapter 2 to develop electrode design concept and the importance of the current density on lithium dendrite growth was also found in the literature. The preliminary test was conducted to verify the developed electrode concept by using lithium powder based anode (LIP) with conductive carbon materials and the results showed that lithium dendrite growth could be suppressed in this electrode design due to its increased electrochemical surface area and lithium deposition sites during lithium deposition. The electrode design suggested in Chapter 2 was extensively studied in Chapter 3 in terms of lithium dendrite growth morphology, lithium cycling efficiency and full cell cycling performance. This electrode concept was further developed to maximize the electrode's performance and safety in Chapter 4. In this new electrode design, electrically isolated super-p carbon agglomerates in the electrode were effectively reduced by adding conductive fillers such as graphite and further improvement in cycling performance and safety was also verified. The lithium powder based anode with conductive carbon materials is very useful concept as an alternative anode design instead of pure lithium metal anode for high energy density lithium batteries such as lithium-sulfur and lithium-air. As shown in Chapter 5, this electrode concept can be further developed and optimized through the application of new carbon materials and structure.

Development of Functional Materials for Fast-charging Graphite Anode and Stabilization of Lithium Metal Anode in Rechargeable Lithium Batteries

Development of Functional Materials for Fast-charging Graphite Anode and Stabilization of Lithium Metal Anode in Rechargeable Lithium Batteries
Author: Pei Shi
Publisher:
Total Pages: 0
Release: 2023
Genre:
ISBN:
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Under the electrification of transportation and deep decarbonization of the energy infrastructure requirement, the development and deployment of the next-generation battery with fast-charging capability and high energy is one of the hottest topics among academic and industrial fields. Current lithium-ion batteries (LIBs) offer moderate energy density enabling limited driving range and take considerably longer to recharge than traditional vehicles. Fast charging and high-energy density batteries are the key requirements for the widespread economic success of electric vehicles., This dissertation focuses on the practical application of rechargeable lithium batteries by designing and synthesizing different kinds of polymers and electrolyte formulation. In Chapter 2, I synthesized a kind of Li ion affinity PEI branched polymer (N-poly) and added it into the graphite anode as the binder material. The N-poly-based polymer composite anode binder could greatly enhance the rate performance the cycle performance at high rate (3 C and 6 C). The functional polymer N-polymer was proven to be favorable for the fast-charging application. In Chapter 3, ionic liquids were chosen to formulate the advanced and nonflammable electrolyte for high-energy-density Li metal batteries due to the anion-rich in the electrolyte. In Li∥NMC811 coin cells, the cell with ionic liquid-based electrolytes could maintain over 175 cycling with 80% capacity retention. The special electrolyte structure could promote an anion decomposition on Li metal anode and lead to high CE and longer cycling life. In Chapter 4, I designed and synthesized a new Li ion affinity polymer based on the aza-crown ether for the artificial SEI layer on the Li metal anode surface had been. The so-formed artificial solid electrolyte interphase has excellent passivation, homogeneity, and mechanical strength, and could tune the Li plating and enable the LiF rich SEI layer thus effectively stabilizing the Li/electrolyte interface and preventing electrolyte decomposition on cycling. In Chapter 5, a facile method to achieve a large size of a kind of reactive polymer PFSPA coated separator in the air atmosphere had been developed. And the coated separator can elongate the cycling number from 65 cycles to 220 cycles. It is because the polymer PFSPA in separator can swell into the electrolyte, attach the lithium surface, and generate LiF after reaction with Li. It helps to form a quite effective SEI layer upon cycling in the carbonate-based electrolyte. Therefore, the work showed tremendous potential for practical application. I concluded this dissertation work in Chapter 6 and briefly discussed the possible future work.

Advanced 3D-structured electrode for potassium metal anodes

Advanced 3D-structured electrode for potassium metal anodes
Author: Dongqing Liu
Publisher: OAE Publishing Inc.
Total Pages: 22
Release: 2023-07-03
Genre: Technology & Engineering
ISBN:
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The potassium (K) metal anode, following the "Holy Grail" Li metal anode, is one of the most promising anode materials for next-generation batteries. In comparison with Li, K exhibits even more pronounced energy storage properties. However, it suffers from similar challenges as most alkali metal anodes, such as safety and cyclability issues. Borrowing strategies from Li/Na metal anodes, the three-dimensional (3D)-structured current collector has proven to be a universal and effective strategy. This study examines the recent research progress of 3D-structured electrodes for K metal anodes, focusing on the most commonly used host materials, including carbon-, metal-, and MXene-related electrode materials. Finally, existing challenges, various perspectives on the rational design of K metal anodes, and the future development of K batteries are presented.