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References (40)
-
A. Hayashi, T. Ohtomo, Fuminori Mizuno, K. Tadanaga, M. Tatsumisago (2003)
All-solid-state Li/S batteries with highly conductive glass–ceramic electrolytesElectrochemistry Communications, 5
-
Xiulei Ji, K. Lee, L. Nazar (2009)
A highly ordered nanostructured carbon-sulphur cathode for lithium-sulphur batteries.Nature materials, 8 6
-
Hirokazu Kitaura, A. Hayashi, K. Tadanaga, M. Tatsumisago (2010)
Electrochemical performance of all-solid-state lithium secondary batteries with Li–Ni–Co–Mn oxide positive electrodesElectrochimica Acta, 55
-
B. Ellis, K. Lee, L. Nazar (2010)
Positive Electrode Materials for Li-Ion and Li-Batteries†Chemistry of Materials, 22
-
Fuminori Mizuno, A. Hayashi, K. Tadanaga, M. Tatsumisago (2005)
Effects of Conductive Additives in Composite Positive Electrodes on Charge-Discharge Behaviors of All-Solid-State Lithium Secondary BatteriesJournal of The Electrochemical Society, 152
-
T. Takeuchi, H. Kageyama, K. Nakanishi, M. Tabuchi, H. Sakaebe, T. Ohta, Hiroshi Senoh, T. Sakai, K. Tatsumi (2010)
All-Solid-State Lithium Secondary Battery with Li2S – C Composite Positive Electrode Prepared by Spark-Plasma-Sintering ProcessJournal of The Electrochemical Society, 157
-
J. Hassoun, B. Scrosati (2010)
A high-performance polymer tin sulfur lithium ion battery.Angewandte Chemie, 49 13
-
A. Sakuda, Hirokazu Kitaura, A. Hayashi, K. Tadanaga, M. Tatsumisago (2008)
Improvement of High-Rate Performance of All-Solid-State Lithium Secondary Batteries Using LiCoO2 Coated with Li2O-SiO2 GlassesElectrochemical and Solid State Letters, 11
-
A. Hayashi, Ryoji Ohtsubo, T. Ohtomo, Fuminori Mizuno, M. Tatsumisago (2008)
All-solid-state rechargeable lithium batteries with Li2S as a positive electrode materialJournal of Power Sources, 183
-
Yuan Yang, M. McDowell, A. Jackson, J. Cha, S. Hong, Yi Cui (2010)
New nanostructured Li2S/silicon rechargeable battery with high specific energy.Nano letters, 10 4
-
Bohai Zhang, C. Lai, Zhen Zhou, X. Gao (2009)
Preparation and electrochemical properties of sulfur–acetylene black composites as cathode materialsElectrochimica Acta, 54
-
A. Sakuda, A. Hayashi, M. Tatsumisago (2010)
Interfacial Observation between LiCoO2 Electrode and Li2S−P2S5 Solid Electrolytes of All-Solid-State Lithium Secondary Batteries Using Transmission Electron Microscopy†Chemistry of Materials, 22
-
Wen-yi Zheng, Yuyan Liu, Xinchun Hu, Chengwen Zhang (2006)
Novel nanosized adsorbing sulfur composite cathode materials for the advanced secondary lithium batteriesElectrochimica Acta, 51
-
A. Hayashi, Shigenori Hama, T. Minami, M. Tatsumisago (2003)
Formation of superionic crystals from mechanically milled Li2S–P2S5 glassesElectrochemistry Communications, 5
-
Hirokazu Kitaura, A. Hayashi, T. Ohtomo, Shigenori Hama, M. Tatsumisago (2011)
Fabrication of electrode–electrolyte interfaces in all-solid-state rechargeable lithium batteries by using a supercooled liquid state of the glassy electrolytesJournal of Materials Chemistry, 21
-
K. Aso, Hirokazu Kitaura, A. Hayashi, M. Tatsumisago (2011)
Synthesis of nanosized nickel sulfide in high-boiling solvent for all-solid-state lithium secondary batteriesJournal of Materials Chemistry, 21
-
D. Peramunage, S. Licht (1993)
A Solid Sulfur Cathode for Aqueous BatteriesScience, 261
-
A. Hayashi, Ryoji Ohtsubo, M. Tatsumisago (2008)
Electrochemical performance of all-solid-state lithium batteries with mechanochemically activated Li2S–Cu composite electrodesSolid State Ionics, 179
-
Motohiro Nagao, Hirokazu Kitaura, A. Hayashi, M. Tatsumisago (2009)
Characterization of all-solid-state lithium secondary batteries using CuxMo6S8−y electrode and Li2S–P2S5 solid electrolyteJournal of Power Sources, 189
-
M. Obrovac, J. Dahn (2002)
Electrochemically Active Lithia/Metal and Lithium Sulfide/Metal CompositesElectrochemical and Solid State Letters, 5
-
A. Pradel, M. Ribes (1986)
Electrical properties of lithium conductive silicon sulfide glasses prepared by twin roller quenchingSolid State Ionics
-
Y. Nishio, Hirokazu Kitaura, A. Hayashi, M. Tatsumisago (2009)
All-solid-state lithium secondary batteries using nanocomposites of NiS electrode/Li2S–P2S5 electrolyte prepared via mechanochemical reactionJournal of Power Sources, 189
-
Motohiro Nagao, A. Hayashi, M. Tatsumisago (2011)
Sulfur–carbon composite electrode for all-solid-state Li/S battery with Li2S–P2S5 solid electrolyteElectrochimica Acta, 56
-
Sang-Eun Cheon, Ki-Seok Ko, Jihoon Cho, Sun-wook Kim, E. Chin, Hee‐Tak Kim (2003)
Rechargeable Lithium Sulfur Battery II. Rate Capability and Cycle CharacteristicsJournal of The Electrochemical Society, 150
-
K. Takada, Noboru Aotani, K. Iwamoto, S. Kondo (1996)
Solid state lithium battery with oxysulfide glassSolid State Ionics
-
E. Peled, A. Gorenshtein, M. Segal, Y. Sternberg (1989)
Rechargeable lithiumsulfur battery (extended abstract)Journal of Power Sources, 26
-
Sang-Cheol Han, Min-Sang Song, H. Lee, Hyunseok Kim, H. Ahn, Jai-Young Lee (2003)
Effect of Multiwalled Carbon Nanotubes on Electrochemical Properties of Lithium/Sulfur Rechargeable BatteriesJournal of The Electrochemical Society, 150
-
Fuminori Mizuno, Shigenori Hama, A. Hayashi, K. Tadanaga, T. Minami, M. Tatsumisago (2002)
All Solid-state Lithium Secondary Batteries Using High Lithium Ion Conducting Li2S-P2S5 Glass-Ceramics.Chemistry Letters, 2002
-
A. Hayashi, Shigenori Hama, H. Morimoto, M. Tatsumisago, T. Minami (2001)
High Lithium Ion Conductivity of Glass-Ceramics Derived from Mechanically Milled Glassy PowdersChemistry Letters, 2001
-
A. Hayashi, Y. Nishio, Hirokazu Kitaura, M. Tatsumisago (2008)
Novel technique to form electrode-electrolyte nanointerface in all-solid-state rechargeable lithium batteriesElectrochemistry Communications, 10
-
Xiulei Ji, L. Nazar (2010)
Advances in Li–S batteriesJournal of Materials Chemistry, 20
-
A. Hayashi, Ryoji Ohtsubo, Motohiro Nagao, M. Tatsumisago (2010)
Characterization of Li2S–P2S5–Cu composite electrode for all-solid-state lithium secondary batteriesJournal of Materials Science, 45
-
Fuminori Mizuno, A. Hayashi, K. Tadanaga, M. Tatsumisago (2005)
New, Highly Ion‐Conductive Crystals Precipitated from Li2S–P2S5 GlassesAdvanced Materials, 17
-
Takeshi Kobayashi, Yuki Imade, Daisuke Shishihara, K. Homma, Miki Nagao, Ryota Watanabe, T. Yokoi, A. Yamada, R. Kanno, T. Tatsumi (2008)
All solid-state battery with sulfur electrode and thio-LISICON electrolyteJournal of Power Sources, 182
-
A. Hayashi, T. Ohtomo, Fuminori Mizuno, K. Tadanaga, M. Tatsumisago (2004)
Rechargeable lithium batteries, using sulfur-based cathode materials and Li2S–P2S5 glass-ceramic electrolytesElectrochimica Acta, 50
-
Lixia Yuan, Hui-ping Yuan, X. Qiu, Liquan Chen, Wentao Zhu (2009)
Improvement of cycle property of sulfur-coated multi-walled carbon nanotubes composite cathode for lithium/sulfur batteriesJournal of Power Sources, 189
-
P. Cunningham, S. Johnson, Elton Cairns (1971)
Phase Equilibria in Lithium‐Chalcogen Systems II . Lithium‐SulfurJournal of The Electrochemical Society, 119
-
Keiichi Minami, A. Hayashi, S. Ujiie, M. Tatsumisago (2011)
Electrical and electrochemical properties of glass–ceramic electrolytes in the systems Li2S–P2S5–P2S3 and Li2S–P2S5–P2O5Solid State Ionics, 192
-
N. Machida, Kazuma Kobayashi, Yutaka Nishikawa, T. Shigematsu (2004)
Electrochemical properties of sulfur as cathode materials in a solid-state lithium battery with inorganic solid electrolytesSolid State Ionics, 175
-
R. Kanno, M. Murayama (2001)
Lithium Ionic Conductor Thio-LISICON: The Li2 S GeS2 P 2 S 5 SystemJournal of The Electrochemical Society, 148
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- Royal Society of Chemistry
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Abstract
All-solid-state lithium secondary batteries with Li2S active materials and sulfide-based solid electrolytes (SEs) were fabricated and the Li2S electrodes were characterized. Li2S–nanocarbon composite electrodes were prepared by hand grinding and mechanical milling. Mechanical milling of a mixture of Li2S, acetylene black (AB), and Li2S–P2S5 SE enhanced the reversible capacity of the all-solid-state cells. Cross-sectional transmission electron microscopy images and electron-energy-loss spectroscopy maps revealed the formation of favorable contacts among Li2S, AB, and SE. Nanocomposites consisting of approximately 500 nm Li2S particles and AB and SE particles were well-dispersed both before and after charge–discharge cycles. The effect of reducing the particle size of the Li2S active material in the composite electrodes on cell performance was investigated. Cells containing milled Li2S with small particle sizes exhibited a charge capacity of about 1000 mA h g−1 under 0.064 mA cm−2 at 25 °C and they were charged and discharged at a high current density of 6.4 mA cm−2 (3.5 C). To improve the reversible capacity and the rate performance of all-solid-state cells, it is important to realize intimate contact among electrode components and reduce the particle size of active materials and composite electrodes by mechanical milling.
Journal
Journal of Materials Chemistry – Royal Society of Chemistry
Published: Apr 24, 2012