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

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Total Pages : 0 pages
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Book Synopsis Development of Functional Materials for Fast-charging Graphite Anode and Stabilization of Lithium Metal Anode in Rechargeable Lithium Batteries by : Pei Shi

Download or read book Development of Functional Materials for Fast-charging Graphite Anode and Stabilization of Lithium Metal Anode in Rechargeable Lithium Batteries written by Pei Shi and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: 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.

Theoretical Study on Graphite and Lithium Metal as Anode Materials for Next-Generation Rechargeable Batteries

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Publisher : Springer Nature
ISBN 13 : 9811389144
Total Pages : 75 pages
Book Rating : 4.8/5 (113 download)

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Book Synopsis Theoretical Study on Graphite and Lithium Metal as Anode Materials for Next-Generation Rechargeable Batteries by : Gabin Yoon

Download or read book Theoretical Study on Graphite and Lithium Metal as Anode Materials for Next-Generation Rechargeable Batteries written by Gabin Yoon and published by Springer Nature. This book was released on 2022-07-08 with total page 75 pages. Available in PDF, EPUB and Kindle. Book excerpt: This thesis describes in-depth theoretical efforts to understand the reaction mechanism of graphite and lithium metal as anodes for next-generation rechargeable batteries. The first part deals with Na intercalation chemistry in graphite, whose understanding is crucial for utilizing graphite as an anode for Na-ion batteries. The author demonstrates that Na ion intercalation in graphite is thermodynamically unstable because of the unfavorable Na-graphene interaction. To address this issue, the inclusion of screening moieties, such as solvents, is suggested and proven to enable reversible Na-solvent cointercalation in graphite. Furthermore, the author provides the correlation between the intercalation behavior and the properties of solvents, suggesting a general strategy to tailor the electrochemical intercalation chemistry. The second part addresses the Li dendrite growth issue, which is preventing practical application of Li metal anodes. A continuum mechanics study considering various experimental conditions reveals the origins of irregular growth of Li metal. The findings provide crucial clues for developing effective counter strategies to control the Li metal growth, which will advance the application of high-energy-density Li metal anodes.

Development of High-performance Anode and Cathode Materials for Lithium and Sodium Ion Batteries

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ISBN 13 :
Total Pages : pages
Book Rating : 4.:/5 (12 download)

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Book Synopsis Development of High-performance Anode and Cathode Materials for Lithium and Sodium Ion Batteries by : Adnan Mousharraf

Download or read book Development of High-performance Anode and Cathode Materials for Lithium and Sodium Ion Batteries written by Adnan Mousharraf and published by . This book was released on 2017 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: In todays world, rechargeable lithium-ion batteries are indispensable for the portable electronic industries. They have great potential for revolutionizing the automotive industries as well. Concurrently, rechargeable sodium-ion batteries are also gaining popularity for large-scale grid energy storage in the renewable energy sector. Continuous growth of these industries is creating a great demand for these rechargeable batteries in the market. As a result, there is a great drive among researchers for developing high-performance lithium and sodium ion batteries. This dissertation was focused on developing high-performance anode and cathode materials for lithium and sodium ion batteries. At first, a carbon coated spherical graphite-silicon composite was developed for rechargeable lithium ion battery system. The main purpose of this work was to develop a composite that shows higher capacity than commercial graphite anode material (372 mAhg-1) and maintains long cyclic stability. The composite material exhibited a reversible capacity of ~ 675 mAhg-1 with very decent coulobmic efficiency of 83%. The material also demonstrated long cycle stability with a capacity retention of ~ 85% after 300 cycles. It also showed good compatibility with commercial lithium ion cathode when paired in a full cell setup. Next, a carbon coated SiO-Si-Mg2SiO4 composite anode material was developed for rechargeable lithium ion battery system. The main purpose of this work was to address the lower initial coulombic efficiency of SiO anode material. The composite material demonstrated improved initial coulombic efficiency of ~ 74.2% and higher specific capacity of ~ 2250 mAhg-1. It also showed decent capacity retention after 100 cycles. Finally, a new O3-type layered cathode material namely NaNi0.3Mn0.3Co0.2Fe0.2O2 was developed for rechargeable sodium-ion battery system. The main purpose of this work was to improve the capacity and rate performance of layered cathode material. Due to the synergistic effect of composition optimization and particle size reduction, the cathode material exhibited an impressive capacity of ~100 mAhg-1 at a rate of 240mAg-1, within a voltage range of 1.8-4.1V.

Lithium Metal Anodes and Rechargeable Lithium Metal Batteries

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Publisher : Springer
ISBN 13 : 3319440543
Total Pages : 206 pages
Book Rating : 4.3/5 (194 download)

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Book Synopsis Lithium Metal Anodes and Rechargeable Lithium Metal Batteries by : Ji-Guang Zhang

Download or read book Lithium Metal Anodes and Rechargeable Lithium Metal Batteries written by Ji-Guang Zhang and published by Springer. This book was released on 2016-10-06 with total page 206 pages. Available in PDF, EPUB and Kindle. Book excerpt: This book provides comprehensive coverage of Lithium (Li) metal anodes for rechargeable batteries. Li is an ideal anode material for rechargeable batteries due to its extremely high theoretical specific capacity (3860 mAh g-1), low density (0.59 g cm-3), and the lowest negative electrochemical potential (−3.040 V vs. standard hydrogenelectrodes). Unfortunately, uncontrollable dendritic Li growth and limited Coulombic efficiency during Li deposition/stripping inherent in these batteries have prevented their practical applications over the past 40 years. With the emergence of post Liion batteries, safe and efficient operation of Li metal anodes has become an enabling technology which may determine the fate of several promising candidates for the next generation energy storage systems, including rechargeable Li-air batteries, Li-S batteries, and Li metal batteries which utilize intercalation compounds as cathodes. In this work, various factors that affect the morphology and Coulombic efficiency of Li anodes are analyzed. The authors also present the technologies utilized to characterize the morphology of Li deposition and the results obtained by modeling of Li dendrite growth. Finally, recent developments, especially the new approaches that enable safe and efficient operation of Li metal anodes at high current densities are reviewed. The urgent need and perspectives in this field are also discussed. The fundamental understanding and approaches presented in this work will be critical for the applicationof Li metal anodes. The general principles and approaches can also be used in other metal electrodes and general electrochemical deposition of metal films.

Lithium-ion Batteries

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Publisher : World Scientific
ISBN 13 : 1860943624
Total Pages : 424 pages
Book Rating : 4.8/5 (69 download)

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Book Synopsis Lithium-ion Batteries by : Perla B. Balbuena

Download or read book Lithium-ion Batteries written by Perla B. Balbuena and published by World Scientific. This book was released on 2004 with total page 424 pages. Available in PDF, EPUB and Kindle. Book excerpt: This invaluable book focuses on the mechanisms of formation of a solid-electrolyte interphase (SEI) on the electrode surfaces of lithium-ion batteries. The SEI film is due to electromechanical reduction of species present in the electrolyte. It is widely recognized that the presence of the film plays an essential role in the battery performance, and its very nature can determine an extended (or shorter) life for the battery. In spite of the numerous related research efforts, details on the stability of the SEI composition and its influence on the battery capacity are still controversial. This book carefully analyzes and discusses the most recent findings and advances on this topic.

Rational Design of Composite Cathodes and Functional Electrolytes for High-Energy Lithium-Metal Batteries

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ISBN 13 :
Total Pages : 188 pages
Book Rating : 4.5/5 (97 download)

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Book Synopsis Rational Design of Composite Cathodes and Functional Electrolytes for High-Energy Lithium-Metal Batteries by : Panpan Dong

Download or read book Rational Design of Composite Cathodes and Functional Electrolytes for High-Energy Lithium-Metal Batteries written by Panpan Dong and published by . This book was released on 2020 with total page 188 pages. Available in PDF, EPUB and Kindle. Book excerpt: Metallic lithium has been considered one of the most attractive anode materials for high-energy batteries because it has a low density (0.53 g cm8́23), the lowest reduction potential (8́23.04 V vs. the standard hydrogen electrode), and a high theoretical specific capacity (3,860 mAh g8́21). Chalcogen elements, such as sulfur and selenium, have been widely reported as promising cathode candidates for next-generation lithium-metal batteries (LMBs) that demonstrate much higher energy density than current lithium-ion batteries. However, lithium0́3chalcogen batteries still suffer from the loss of cathode active materials and the degradation of lithium metal anode owing to the shuttle effects of intermediate products (e.g., polysulfides and polyselenides), leading to fast capacity fading and poor cyclability. Moreover, for lithium metal anodes, the cracking of solid electrolyte interphase (SEI) layer during long cycling results in dead lithium formation and lithium dendrite growth, leading to poor Coulombic efficiency and potential safety issues. The abovementioned challenges hinder the commercialization of LMBs. To address these problems, various strategies have been developed to mitigate the dissolution/diffusion of redox intermediates and stabilize metallic lithium anodes. In this dissertation, sulfur- and selenium-based nanocomposites were synthesized and employed as advanced cathode materials for high-energy LMBs. The correlations between syntheses, properties, and performances of such chalcogen cathode materials were established by various characterization methods such as microstructural analyses, solid-state nuclear magnetic resonance, X-ray photoelectron spectroscopy, and nanoscale X-ray computed tomography. Additionally, the interfacial electrochemistry of lithium metal anodes and ionic liquid0́3based electrolytes is comprehensively investigated, revealing the effective stabilization and protection of lithium anode via the formation of an in situ SEI layer with specific compositions. Moreover, strategies for achieving novel solid polymer electrolytes with improved lithium-ion transference number were demonstrated, paving the way toward safe LMBs by mitigating lithium dendrite growth. This dissertation provides a combined strategy of advanced cathode design, electrolyte engineering, and lithium anode stabilization to develop high-energy LMBs for practical applications.

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

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ISBN 13 :
Total Pages : pages
Book Rating : 4.:/5 (951 download)

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Book Synopsis Development of Lithium Powder Based Anode with Conductive Carbon Materials for Lithium Batteries by : Mansu Park

Download or read book Development of Lithium Powder Based Anode with Conductive Carbon Materials for Lithium Batteries written by Mansu Park and published by . This book was released on 2016 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: 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.

Materials Understanding for Development of Next Generation Li-ion Battery Anodes

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ISBN 13 :
Total Pages : 0 pages
Book Rating : 4.:/5 (137 download)

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Book Synopsis Materials Understanding for Development of Next Generation Li-ion Battery Anodes by : Fuqun Grace Vasiknanonte

Download or read book Materials Understanding for Development of Next Generation Li-ion Battery Anodes written by Fuqun Grace Vasiknanonte and published by . This book was released on 2023 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Modern lithium-ion batteries rely on the anode material to contain the capacity of the battery safely and reliably for maximum rechargeability, but the current mode of operation cannot be sustained without new tools and material options as the need for improved fast charging capability increases. Traditional graphite has been able to fulfill demands in consumer electronics with smaller cell capacity, but with industrial automotive cell packs, the anode is limited in its volumetric and gravimetric capacity and highly susceptible to hazardous Li plating, especially at high charging rates. Key to addressing these problems will be industrially relevant strategies to enable new, higher capacity materials and practical characterization tools. This work aims to explore the relevant criteria and methods to develop a mechanically and chemically stable silicon anode through facile carbon coating and conversion techniques. Furthermore, with current understanding of anode volume expansion principles, a platform has been developed to probe the behaviors of pressure in informing long-term cell degradation. It is through this work that improved cycle life of bare silicon anode and reliable measurements of pressure can be achieved.

Advanced Battery Materials

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Publisher : John Wiley & Sons
ISBN 13 : 1119407664
Total Pages : 400 pages
Book Rating : 4.1/5 (194 download)

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Book Synopsis Advanced Battery Materials by : Chunwen Sun

Download or read book Advanced Battery Materials written by Chunwen Sun and published by John Wiley & Sons. This book was released on 2019-03-26 with total page 400 pages. Available in PDF, EPUB and Kindle. Book excerpt: Electrochemical energy storage has played important roles in energy storage technologies for portable electronics and electric vehicle applications. During the past thirty years, great progress has been made in research and development of various batteries, in term of energy density increase and cost reduction. However, the energy density has to be further increased to achieve long endurance time. In this book, recent research and development in advanced electrode materials for electrochemical energy storage devices are presented, including lithium ion batteries, lithium-sulfur batteries and metal-air batteries, sodium ion batteries and supercapacitors. The materials involve transition metal oxides, sulfides, Si-based material as well as graphene and graphene composites.

CVD-Assisted Carbon-Coating on Titanium-Based Silicate Anode Material for Lithium-Ion and Sodium-Ion Batteries

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ISBN 13 :
Total Pages : 151 pages
Book Rating : 4.:/5 (119 download)

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Book Synopsis CVD-Assisted Carbon-Coating on Titanium-Based Silicate Anode Material for Lithium-Ion and Sodium-Ion Batteries by : Dejia Kong

Download or read book CVD-Assisted Carbon-Coating on Titanium-Based Silicate Anode Material for Lithium-Ion and Sodium-Ion Batteries written by Dejia Kong and published by . This book was released on 2020 with total page 151 pages. Available in PDF, EPUB and Kindle. Book excerpt: The communication between humanity and energy sources reflects the evolution of human society. As the landmark of history, from the awe of the prehistoric man about the fire to the steam's popularization in the industrial revolution, different kinds of energy play an unparalleled role in the development of technology. Up to time now, electricity, the ultimate energy source in existence, powers the development of civilizations. Meanwhile, with the more urgent request for improving the quality of life, higher energy consumption, and more diverse forms of energy storage systems (ESS) are integrated into the world. Among all the various ESS, the battery received considerable attention because of its high theoretical energy density, the feasibility of current technology, and applicability for different fields. Whereas, the significant issues rest on the sluggish reaction kinetics of electrode materials during fast charging and discharging process. For instance, graphite is the most used anode material for lithium-ion batteries because it has economical production cost and considerable energy density (theoretical capacity: 372 mAh g-1, discharge plateau: ~ 0.1 V vs. Li+/Li). When employed as high-power batteries, however, graphite shows inadequate endurance with rapid fading of its capacity and delivers reduced capacity. The uncontrollable growth of lithium dendrite will also cause safety problems, particularly at high charging current density. In order to fill the vacancy of the desired high-rate anode candidate, titanium-based materials acquire numerous studies. The most representative candidate is Li4Ti5O12 (LTO), which has been widely studied and commercialized. In respect that LTO has "zero strain" physical property, its cycling stability is exceptionally long, compared with other carbon-based anodic materials. However, low electronic conductivity (10-8 S cm-1), slow ionic diffusivity, low theoretical capacity (175 mAh g-1), and high operational voltage (1.55 V vs. Li+/Li) limit its performance and further development in the matter of power batteries. By contrast, another member from titanium-based materials, lithium titanium silicate (Li2TiSiO5, LTSO), offers an intriguing theoretical capacity of 308 mAh g 1 and a low potential of 0.28 V vs. Li+/Li. Nevertheless, inherent properties like low electric and ionic conductivity are still tangling the growth of such materials in power lithium-ion batteries. For the improvement of these drawbacks, using carbon composites and nanocrystallizations is simple and effective. Nevertheless, they bring new issues like low tap density, low initial coulombic efficiency, and complex synthesis. In brief, there is a conflict between the total amount of carbon materials (for conductivity enhancement), particle size (for ionic diffusivity improvement), and tap density (effect on volumetric energy density), initial coulombic efficiency (related to specific surface area). In this dissertation, we first designed a chemical vapor deposition (CVD)-assisted synthetic strategy to achieve conductive carbon-coating over the surface of fumed-silica and transform the catalysts to LTSO for high-rate anode material of lithium-ion batteries. The application of CVD allows the steerable carbon content and uniform surface carbon growing to compensate for the low conductivity. With optimized carbon content (2.35 wt.%), the obtained LTSO carbon composite could deliver desirable high-rate performance (~ 100 mAh g-1 at 15 C, where 1 C = 300 mA g-1), which is comparable with commercialized LTO. In consideration of using nanosized particles (fumed-silica, with 20-30 nm primary structure), the current state needs to advance regarding the tap density and initial coulombic efficiency. Thereupon we proposed a novel tactic for CVD-assisted in-situ graphitic carbon-coating by employing the dual functional material, LTSO, with both catalytic and electrochemical activity. The catalytic ability of LTSO render the hierarchical structural design with microsphere particulate, which guarantees the tap density at 1.3 g ml-1. The optimized thin layer (15 nm) conductive carbon-coating, with only 3.5 wt.%, dramatically improves the conductivity form ~ 10-7 S m 1 to ~ 103 S m 1. After incorporating all the advantages, carbon-coated LTSO reveals a superior graphite-like volumetric capacity of 441.1 mAh cm-3 and Li4Ti5O12-like rate capability (120.1 mAh cm-3 at 4.5 A g-1). Based on the attained understanding of LTSO, we then started the exploration of relative titanium-based silicate in sodium-ion batteries (Na2TiSiO5, NTSO) as anode candidate. By using inexpensive materials (fumed-silica and P-25) and facilities (ball milling), the obtained NTSO is very practicable for large-scale production. Benefited from the similar catalytic ability as it of LTSO, NTSO carbon composite shows promising performance with excellent cycling stability (100 mAh g-1 at 100 mA g-1 and 90% capacity retention after 3000 cycles).

Stable ultrathin lithium metal anode enabled by self-adapting electrochemical regulating strategy

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Publisher : OAE Publishing Inc.
ISBN 13 :
Total Pages : 9 pages
Book Rating : 4./5 ( download)

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Book Synopsis Stable ultrathin lithium metal anode enabled by self-adapting electrochemical regulating strategy by : Si-Yuan Zeng

Download or read book Stable ultrathin lithium metal anode enabled by self-adapting electrochemical regulating strategy written by Si-Yuan Zeng and published by OAE Publishing Inc.. This book was released on 2024-04-08 with total page 9 pages. Available in PDF, EPUB and Kindle. Book excerpt: Ultrathin lithium (Li) metal foils with controllable capacity could realize high-specific-energy batteries; however, the pulverization of Li metal foils due to its extreme volume change results in rapid active Li loss and capacity fading. Here, we report a strategy to stabilize ultrathin Li metal anode via in-situ transferring Li from ultrathin Li foil into a well-designed three-dimensional gradient host during a cycling process. A three-dimensional carbon fiber with gradient distribution of Ag nanoparticles is placed on the ultrathin Li foil in advance and acts as a Li reservoir, guiding Li deposition into its interior and thus alleviating the volume change of ultrathin Li foil anodes. Hence, a high reversibility of Li metal is achieved and Li pulverization is suppressed, which can be witnessed by a long cyclic life in the symmetric cells. The proposed method offers a versatile and facile approach for protecting ultrathin Li metal anodes, which will boost their commercial application process.

DEVELOPMENT OF STABLE HIGH-CAPACITY SILICON-BASED ANODE AND LITHIUM METAL ANODE FOR LITHIUM-ION BATTERY.

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ISBN 13 :
Total Pages : pages
Book Rating : 4.:/5 (18 download)

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Book Synopsis DEVELOPMENT OF STABLE HIGH-CAPACITY SILICON-BASED ANODE AND LITHIUM METAL ANODE FOR LITHIUM-ION BATTERY. by : Qingquan Huang

Download or read book DEVELOPMENT OF STABLE HIGH-CAPACITY SILICON-BASED ANODE AND LITHIUM METAL ANODE FOR LITHIUM-ION BATTERY. written by Qingquan Huang and published by . This book was released on 2018 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: High-capacity Si-based anode is being considered as promising anode material for next generation of Li-ion battery. The energy density could be increased from 250-260 Wh kg-1 to 300-330 Wh kg-1 via replacing graphite with Si-based anode. However, for high-loading Si-based anode, the huge volume change of Si (400%) or SiO (200%) particles during lithiation/delithiation will arise large electrode thickness change. After repeated electrode expansion and contraction, the electrode integrity is seriously damaged, including large electrode cracking, electrode delamination or peeling-off from Cu current collector, as well as continuous growth of solid electrolyte interphase (SEI) layer. When pairing it with commercial cathode, the damage of electrode integrity results in large amount of irreversible lithium ions loss in each cycle and low full-cell Coulombic efficiency of 99.5-99.7%. Thus the full-cell exhibits fast capacity fading and limited cycle life. Another challenge of SiO anode is its low first cycle Coulombic efficiency of 50-60%, which causes huge irreversible lithium ions loss for the first cycle of full-cell and dramatically decreases the cell capacity.In Chapter 1, we will give an introduction to lithium-ion battery, cell energy density, and advantages and challenges of Si-based anode. The Chapter 2 introduces two strategies to solve the challenges of Si-based anode: including design of nanostructured Si and advanced polymer binder. Also we will also talk about the importance of electrode integrity and the previous work on improving electrode integrity.In Chapter 3, we reported an elastic and stretchable polyurethane-urea (PUU) gel polymer electrolyte (GPE) coating strategy to improve cycling stability of high-areal-capacity SiO anode. The PUU GPE functions as intra-electrode cushion to accommodate the volume change of SiO electrode. It can alleviate electrode thickness change, inhibit electrode cracking, and improve electrode adhesion strength on Cu current collector. The improved electrode structure integrity reduces the continuous growth of SEI layer. The half-cell of SiO electrode with PUU coating shows a reversible capacity of 3.0 mAh cm-2 for 280 cycles. When paring with commercial cathode, the full-cell shows a reversible capacity of 2.1 mAh cm-2 for 200 cycles and 80% capacity retention for 500 cycles with improved full-cell Coulombic efficiency of 99.9%.In Chapter 4, we demonstrate chemical vapor deposition (CVD) growth of carbon layer on SiOx (C-SiOx). The carbon coating is composed of dense graphene layers. It can not only increase the electronic conductivity, but also decrease the amount of electrolyte decomposition. Thus the first cycle Coulombic efficiency increases to 74.1%. Moreover, when blending C-SiOx with graphite anode, the composite anode shows high first cycle CE of 86.4%.In Chapter 5, we report a composite LixSi/gel polymer electrolyte composite protection film on the top of lithium meal via simple cast coating approach. The LixSi functions as seeds for lithium nucleation and it has large surface area, thus it can reduce local current density and prevent lithium dendrite growth. When paring with lithium iron phosphate cathode, the cell with composite protection films shows stable capacity at 2.0 mAh cm-2 for 400 cycles.

Rational Design of Lithium/Sodium Ion Battery Anode for High Performance Energy Storage

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Publisher :
ISBN 13 :
Total Pages : 130 pages
Book Rating : 4.:/5 (113 download)

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Book Synopsis Rational Design of Lithium/Sodium Ion Battery Anode for High Performance Energy Storage by : Xianyang Li

Download or read book Rational Design of Lithium/Sodium Ion Battery Anode for High Performance Energy Storage written by Xianyang Li and published by . This book was released on 2019 with total page 130 pages. Available in PDF, EPUB and Kindle. Book excerpt: The rapid increasing consumption of fossil fuels since the industrial revolution has brought about environmental and ecological contamination and its depletion, thus, humankind must stop to utilize more clean and renewable energy such as solar, hydraulic power, wind power as alternative. In this case, an effective and efficient medium is a must since those sorts of renewable energy are difficult to be stored and utilized in a standard way. As the invention and improvement of battery, electrical power come up to be the chosen solution. Therefore, electrical vehicles are already commercialized for a long time and growing up rapidly, grabbing the market share from traditional Inner Combustion Engine vehicles. Among the various battery chemistries, Lithium-ion Batteries (LIBs) have acquire most of attention from both academia and industry. With a similar mechanism, Sodium-ion Batteries (SIBs) are acting as an alternative for LIBs for their low cost. However, the current battery performance cannot satisfy the market of electrical vehicle and consumer electronics, thus, energy density and power density as two of the crucial factors for battery performance must be enhanced. To address these issues, the anode of LIBs and SIBs need to be improved. In this dissertation, novel ideas for anode materials design were given, towards not only the current anode modification, but next generation anode production as well. With a high theoretical capacity of 2595 mAh g-1 from alloy reaction, phosphorus is one of the most promising candidates as next generation anode material for lithium/sodium ion battery. Nonetheless, it is suffering volume expansion (300% for LIBs and 500% for SIBs) and low conductivity during cycling, leading to sacrificed robustness of the electrode. Herein, we developed an efficient and effective high energy ball milling route to crystalline phosphorus within carbon matrix as anode material for LIB and SIB. The special structure offers many advantages: enhanced the conductivity; shortened distance for Li+ or Na+ diffusion; buffered volumetric expansion and more stable structure. Benefitting from the merits, the composite delivers a capacity over 1000 mAh g-1 for about 300 cycles at a specific current of 1 A g-1. Both half-cell and full cell cycling test show an 80% retention around 300th cycle. More essentially, crystalline phosphorus can be still found after many cycles. As-prepared material also delivered a high sodium capacity over 700 mAh g-1 over 300 cycles. For increasing utilization in electrical vehicles, the limitation of power density has become a severe issue for LIBs. Therefore, LIBs with advanced high rate performance is highly desirable. A major issue for developing high rate battery is the performance of anode as their sluggish intercalation kinetics. Herein, we provide a new strategy for advanced performance LIB anode design and its demonstration. To fabricate anode with both high energy and power density, two different materials with each character respectively were mixed to achieve the goal, meanwhile, they need to have different charge and discharge plateaus. As the redox plateaus of these materials are different, the electrochemical interaction will occur when they are being charged or discharged as composite, thus enhance the performance as anode for LIBs. Phosphorus-carbon composite and commercialized LTO were utilized to demonstrate this strategy. The current anode system in commercialized LIBs are difficult to be substituted in the near future because of their low charging potential which leads to a high energy density for full cell. In this case, the development of LIBs in EV are highly depends on modification of the current system in recent years. Therefore, we developed a new route for graphite anode improvement with the additive of Metal-organic Framework (MOF). With its special structure, open metal sites (OMS), MOF can immobilize the anion of electrolyte by forming coordination bond, thereby prevents the electrolyte from decomposition, so as to eliminate the byproduct and heat release. With these advantages from MOF additive, the graphite anode performance was improved a great deal especially fast discharging (full cell). And post-cycle characterization explores that MOF keeps higher crystallinity of graphite and lower down the decomposition of the electrolyte LiPF6.

High-Quality Carbon-based Composite Materials for High-Performance Lithium-ion Batteries

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Publisher :
ISBN 13 :
Total Pages : 183 pages
Book Rating : 4.:/5 (116 download)

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Book Synopsis High-Quality Carbon-based Composite Materials for High-Performance Lithium-ion Batteries by : Fan Li

Download or read book High-Quality Carbon-based Composite Materials for High-Performance Lithium-ion Batteries written by Fan Li and published by . This book was released on 2020 with total page 183 pages. Available in PDF, EPUB and Kindle. Book excerpt: With the continuous increase of global population and consumption of resources, the dire need for an efficient and reliable energy system is becoming progressively prominent. The current energy system is still heavily dependent on fossil fuel, which is limited and harmful to the environment. In recent years, many countries have taken the initiative to transition into a phase where renewable and clean energy sources are gradually replacing fossil fuels and applied in various scenarios from residential buildings to power grids. However, renewable energies has their intrinsic drawbacks because of their intermittent and fluctuating nature. Consequently, it is crucial for the energy storage system to be highly capable in terms of storage capacity, instant supply, and durability. Among various energy storage systems, lithium-ion batteries have emerged as a preferable choice because of its high capacity, chemical and thermal stability, and gradually decreasing cost. In this dissertation, we developed a series of composite electrode materials for lithium-ion batteries of high performance and low cost. Carbonaceous materials have been reported to improve the battery performance to a certain extent. However, the lack of focus in the designing of the architecture of the carbon materials could limit the effect that they might bring. We thus developed an intercalation method that allows FeCl3 to be directly embedded into the graphite matrix to synthesize LFP/Graphite as a cathode material. This method significantly increased electronic and ionic conductivity through a robust and highly conductive graphite matrix, tremendously improving the performance of commercial LFP to a reversible capacity of 160 mA h g-1, a rate performance of 107 mA h g-1 at 60 C, and an outstanding cycling ability of > 95% reversible capacity retention over 2000 cycles. The intercalation method is then combined with Fe2O3 to improve the performance of graphite, which is the most prevalent material of the anode market. Graphite scaffold made via the intercalation process was able to provide a stable supporting structure to prevent structural failure due to large volumetric expansion and a highly electroconductive network. We synthesized a high-performance anode material with a specific capacity of 391 mAh/g after 350 cycles of charging/ discharging @ 500 mA/g, which improved the capacity of graphite by 50%. With rapidly growing world population and economy growth, the need for high-energy batteries with fast-charging capability is surging. Thus, it is essential to strategically combine materials so that while maintaining a high capacity and energy density, they could also exhibit an ability to accept fast charging. Graphene has been numerously studied and applied in composite materials in recent years, but its performance in terms of fast-charging has always been less than satisfactory because of both the poor quality of graphene, and the irreversible stacking of 2D structure within graphene. With this beard in mind, we designed synthesis processes for a hierarchical flower-like nitrogen-doped graphene-based LiFePO4 composite material for cathodes, and high-quality mesoporous graphene particles for high-energy and fast-charging anodes. In a hierarchical flower-like nitrogen-doped graphene-based LiFePO4 composite, we used a template-based process to obtain a CVD-grown nitrogen-doped graphene; the structure was able to withstand acid etching and subsequent charging/discharging processes, remaining at a ~100% coulombic efficiency at a high rate of 20C. In high-quality mesoporous graphene particles, we strategically combined a robust yet flexible graphene network with LFP nanoparticles that are closely packed. Followed by a microwaving process to largely increase the quality of the graphene to better provide an excellent electronic and ionic conducting network. The HNMG electrode provides a reversible capacity of 448 mA h g-1 even at a high charge-discharge rate of 60 C, 3 times the capacity of the NMG electrode (163 mA h g-1) and 70 times the capacity of the graphite electrode (6 mA h g-1). HNMG electrode also shows an excellent reversibility. Besides, due to the high tap density (0.63 g cm-3) of HNMG particles, the volumetric capacity of 334 mA h mL-1 at a high rate of 60C. These methods provided potential solutions to the current issues of electrode materials of LIBs by synthesizing a series of carbon-based composite materials with unique designs targeting the conductivity issue of high-performance materials.

Battery Technologies

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Author :
Publisher : John Wiley & Sons
ISBN 13 : 3527348581
Total Pages : 386 pages
Book Rating : 4.5/5 (273 download)

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Book Synopsis Battery Technologies by : Jianmin Ma

Download or read book Battery Technologies written by Jianmin Ma and published by John Wiley & Sons. This book was released on 2021-12-28 with total page 386 pages. Available in PDF, EPUB and Kindle. Book excerpt: Battery Technologies A state-of-the-art exploration of modern battery technology In Battery Technologies: Materials and Components, distinguished researchers Dr. Jianmin Ma delivers a comprehensive and robust overview of battery technology and new and emerging technologies related to lithium, aluminum, dual-ion, flexible, and biodegradable batteries. The book offers practical information on electrode materials, electrolytes, and the construction of battery systems. It also considers potential approaches to some of the primary challenges facing battery designers and manufacturers today. Battery Technologies: Materials and Components provides readers with: A thorough introduction to the lithium-ion battery, including cathode and anode materials, electrolytes, and binders Comprehensive explorations of lithium-oxygen batteries, including battery systems, catalysts, and anodes Practical discussions of redox flow batteries, aqueous batteries, biodegradable batteries, and flexible batteries In-depth examinations of dual-ion batteries, aluminum ion batteries, and zinc-oxygen batteries Perfect for inorganic chemists, materials scientists, and electrochemists, Battery Technologies: Materials and Components will also earn a place in the libraries of catalytic and polymer chemists seeking a one-stop resource on battery technology.

Functional Materials For Next-generation Rechargeable Batteries

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Author :
Publisher : World Scientific
ISBN 13 : 9811230684
Total Pages : 229 pages
Book Rating : 4.8/5 (112 download)

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Book Synopsis Functional Materials For Next-generation Rechargeable Batteries by : Jiangfeng Ni

Download or read book Functional Materials For Next-generation Rechargeable Batteries written by Jiangfeng Ni and published by World Scientific. This book was released on 2021-02-10 with total page 229 pages. Available in PDF, EPUB and Kindle. Book excerpt: Over-consumption of fossil fuels has caused deficiency of limited resources and environmental pollution. Hence, deployment and utilization of renewable energy become an urgent need. The development of next-generation rechargeable batteries that store more energy and last longer has been significantly driven by the utilization of renewable energy.This book starts with principles and fundamentals of lithium rechargeable batteries, followed by their designs and assembly. The book then focuses on the recent progress in the development of advanced functional materials, as both cathode and anode, for next-generation rechargeable batteries such as lithium-sulfur, sodium-ion, and zinc-ion batteries. One of the special features of this book is that both inorganic electrode materials and organic materials are included to meet the requirement of high energy density and high safety of future rechargeable batteries. In addition to traditional non-aqueous rechargeable batteries, detailed information and discussion on aqueous batteries and solid-state batteries are also provided.

Structure of Electrified Interfaces

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Author :
Publisher : Wiley-VCH
ISBN 13 :
Total Pages : 424 pages
Book Rating : 4.3/5 (91 download)

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Book Synopsis Structure of Electrified Interfaces by : Jacek Lipkowski

Download or read book Structure of Electrified Interfaces written by Jacek Lipkowski and published by Wiley-VCH. This book was released on 1993 with total page 424 pages. Available in PDF, EPUB and Kindle. Book excerpt: This second volume in the Frontiers of Electrochemistry series provides a modern description of the metal-solution interface and describes the advances made in interfacial electrochemistry during the past decade. Contributing authors summarize the impact of new ex situ and in situ techniques in studying electrode surfaces, and illustrate the significance of the development of new experimental techniques and the availability of reliable data in the theory of electrified interfaces. The review articles demonstrate how a molecular picture of the interface has emerged from traditional models that treated the solution as a dielectric and metal as an electronic continuum. Annotation copyright by Book News, Inc., Portland, OR