The Li-Ion Rechargeable Battery: A Perspective

Goodenough, John B; Park, Kyu‐Sung

doi:10.1021/ja3091438

Cited by 8,027 publications

(5,272 citation statements)

References 47 publications

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“…Moreover, it can store the non‐continuous energy harvesting from other alternative clean energies (wind energy, solar energy, and hydroenergy) as chemical energy and release it as electric energy to power various devices when needed 44. In this field, Goodenough, Tarascon, J. Dahn, L. Chen, and Zhao et al have carried out intensive investigations on new‐types of cathodes and have made meaningful discoveries on the lithiation/delithiation mechanisms as well as anodes with high capacities and stable cycling performances 45, 46, 47, 48, 49, 50, 51, 52. Nowadays, Li‐ion batteries are widely used in portable electric devices and electric vehicles with high energy density, thus reducing the consumption to fossil fuel in some degree 53, 54.…”

Section: Energy Storage Device Applicationsmentioning

confidence: 99%

MoS₂‐Based Nanocomposites for Electrochemical Energy Storage

et al. 2016

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Typical layered transition‐metal chalcogenide materials, in particular layered molybdenum disulfide (MoS2) nanocomposites, have attracted increasing attention in recent years due to their excellent chemical and physical properties in various research fieldsHere, a general overview of synthetic MoS2 based nanocomposites via different preparation approaches and their applications in energy storage devices (Li‐ion battery, Na‐ion battery, and supercapacitor) is presented. The relationship between morphologies and the electrochemical performances of MoS2‐based nanocomposites in the three typical and promising rechargeable systems is also discussed. Finally, perspectives on major challenges and opportunities faced by MoS2‐based materials to address the practical problems of MoS2‐based materials are presented.

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Section: Energy Storage Device Applicationsmentioning

confidence: 99%

MoS₂‐Based Nanocomposites for Electrochemical Energy Storage

et al. 2016

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“…1,2 However, current lithium-ion batteries based on the graphite and transition metal oxide couple have nearly reached their ceiling with respect to storage capability because of the limitations associated with their electrical properties and crystal structure. Therefore, breakthroughs in new energy storage systems that can surpass the current performance barrier of lithium-ion batteries should be brought about in a timely manner.…”

Section: Introductionmentioning

confidence: 99%

Graphene quantum dots: structural integrity and oxygen functional groups for high sulfur/sulfide utilization in lithium sulfur batteries

et al. 2016

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Lithium-sulfur (Li-S) batteries are expected to overcome the limit of current energy storage devices by delivering high specific energy with low material cost. However, the potential of Li-S batteries has not yet been realized because of several technical barriers. Poor electrochemical performance is mainly attributed to the low electrical conductivity of the fully charged and discharged species, the irreversible loss of polysulfide anions and the decrease in the number of electrochemically active reaction sites during battery operation. Here, we report that the introduction of graphene quantum dots (GQDs) into the sulfur cathode dramatically enhanced sulfur/sulfide utilization, yielding high performance. In addition, the GQDs induced structural integrity of the sulfur-carbon electrode composite by oxygen-rich functional groups. This hierarchical architecture enabled fast charge transfer while minimizing the loss of lithium polysulfides, which is attributed to the physicochemical properties of GQDs. The mechanisms through which excellent cycling and rate performance are achieved were thoroughly studied by analyzing capacity versus voltage profiles. Furthermore, experimental observations and theoretical calculations further clarified the role played by GQDs by proving that C-S bonding occurs. Thus, the introduction of GQDs into Li-S batteries will provide an important breakthrough allowing their use as high-performance and low-cost batteries for next-generation energy storage systems. INTRODUCTIONRechargeable lithium-ion batteries are widely used in various applications, such as portable devices, bio-medical implants and electric vehicles, because of their high energy and power density. 1,2 However, current lithium-ion batteries based on the graphite and transition metal oxide couple have nearly reached their ceiling with respect to storage capability because of the limitations associated with their electrical properties and crystal structure. Therefore, breakthroughs in new energy storage systems that can surpass the current performance barrier of lithium-ion batteries should be brought about in a timely manner. Recently, Li-S batteries that can operate by the reversible electrochemical transformation between sulfur (S 8 ) and dilithium sulfide (Li 2 S) have attracted great attention because they can deliver high energy with a moderate voltage owing to the direct use of

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“…This next-generation technology exhibits certain advantages like improved safety, and higher open circuit voltages are also possible. [1][2][3] Despite their advantages, current lithium conducting solid electrolytes exhibit conductivities of ∼1 × 10 −2 S cm −1 , which are still one order of magnitude lower than those of organic liquid electrolytes and therefore limit the feasibility of an all solid-state device. 4 In recent years, research has centered on lithium conducting garnets as a very promising candidate as a solid electrolyte.…”

Section: Introductionmentioning

confidence: 99%

Structural limitations for optimizing garnet-type solid electrolytes: a perspective

Zeier

2014

Dalton Trans.

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Lithium ion batteries exhibit the highest energy densities of all battery types and are therefore an important technology for energy storage in every day life. Today's commercially available batteries employ organic polymer lithium conducting electrolytes, leading to multiple challenges and safety issues such as poor chemical stability, leakage and flammability. The next generation lithium ion batteries, namely all solid-state batteries, can overcome these limitations through employing a ceramic Li + conducting electrolyte. In the past decade, there has been a major focus on the structural and ionic transport properties of lithium-conducting garnets, and the extensive research efforts have led to a thorough understanding of the structure-property relationships in this class of materials. However, further improvement seems difficult due to structural limitations. The purpose of this Perspective article is to provide a brief structural overview of Li conducting garnets and the structural influence on the optimization of Li-ionic conductivities.

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The Li-Ion Rechargeable Battery: A Perspective

Cited by 8,027 publications

References 47 publications

MoS₂‐Based Nanocomposites for Electrochemical Energy Storage

MoS₂‐Based Nanocomposites for Electrochemical Energy Storage

Graphene quantum dots: structural integrity and oxygen functional groups for high sulfur/sulfide utilization in lithium sulfur batteries

Structural limitations for optimizing garnet-type solid electrolytes: a perspective

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The Li-Ion Rechargeable Battery: A Perspective

Cited by 8,027 publications

References 47 publications

MoS2‐Based Nanocomposites for Electrochemical Energy Storage

MoS2‐Based Nanocomposites for Electrochemical Energy Storage

Graphene quantum dots: structural integrity and oxygen functional groups for high sulfur/sulfide utilization in lithium sulfur batteries

Structural limitations for optimizing garnet-type solid electrolytes: a perspective

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Product

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MoS₂‐Based Nanocomposites for Electrochemical Energy Storage

MoS₂‐Based Nanocomposites for Electrochemical Energy Storage