The First Lithium-ion Battery with Ionic Liquid Electrolyte Demonstrated in Extreme Environment of Space (Innovative Battery Development)
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- Material Type
- 記事
- Author/Editor
- Masaki YAMAGATAKohei TANAKAYoshihiro TSURUDA 他
- Series Title
- Author Heading
- Alternative Title
- 宇宙極限環境で作動した初めてのイオン液体リチウム二次電池 ウチュウ キョクゲン カンキョウ デ サドウ シタ ハジメテ ノ イオン エキタイ リチウム ニジ デンチ
- Periodical title
- 電気化学および工業物理化学 = Denki kagaku
- No. or year of volume/issue
- 83(10):2015.10
- Volume
- 83
- Issue
- 10
- Pages
- 918-924
- Publication date of volume/issue (W3CDTF)
- 2015-10
- ISSN (Periodical Title)
- 1344-3542
- ISSN-L (Periodical Title)
- 1344-3542
- Publication (Periodical Title)
- 東京 : 電気化学協会
- Place of Publication (Country Code)
- JP
- Text Language Code
- eng
- NDLC
- Target Audience
- 一般
- Holding library
- 国立国会図書館
- Call No.
- Z17-14
- Data Provider (Database)
- 国立国会図書館 : 国立国会図書館雑誌記事索引
- Bibliographic ID (NDL)
- 026770570
- Bibliographic Record Category (NDL)
- 632
- Summary, etc.
- A prototype lithium-ion battery with a bis(fluorosulfonyl)imide (FSI)-based ionic liquid electrolyte was developed. The prototype was mounted on a demonstration module of the “Hodoyoshi-3” microsatellite, which was successfully launched on June 20, 2014. Qualification tests for space application, including radiation tolerance and vacuum tests, revealed negligible degradation of the ionic liquid-based lithium-ion battery (IL-LIB) cell. According to the flight data, the IL-LIB cell can exist stably in an ultra-high vacuum environment despite its thin and flexible pouch casing without any rigid anti-vacuum reinforcements. Furthermore, the power unit showed the same charge–discharge performance as that predicted by the charge–discharge behavior of an identical cell on the ground, suggesting that the IL-LIB cell maintains performance in high vacuum a microgravity environment. These results prove that LIB cells with FSI-based ionic liquids can be used as a power source for space applications.
- DOI
- 10.5796/electrochemistry.83.918
- Access Restrictions
- インターネット公開
- Data Provider (Database)
- 科学技術振興機構 : J-STAGE
- Summary, etc.
- A prototype lithium-ion battery with a bis(fluorosulfonyl)imide (FSI)-based ionic liquid electrolyte was developed. The prototype was mounted on a demonstration module of the “Hodoyoshi-3” microsatellite, which was successfully launched on June 20, 2014. Qualification tests for space application, including radiation tolerance and vacuum tests, revealed negligible degradation of the ionic liquid-based lithium-ion battery (IL-LIB) cell. According to the flight data, the IL-LIB cell can exist stably in an ultra-high vacuum environment despite its thin and flexible pouch casing without any rigid anti-vacuum reinforcements. Furthermore, the power unit showed the same charge–discharge performance as that predicted by the charge–discharge behavior of an identical cell on the ground, suggesting that the IL-LIB cell maintains performance in high vacuum a microgravity environment. These results prove that LIB cells with FSI-based ionic liquids can be used as a power source for space applications.
- DOI
- 10.5796/electrochemistry.83.918
- Access Restrictions
- インターネット公開
- Related Material
- The First Lithium-ion Battery with Ionic Liquid Electrolyte Demonstrated in Extreme Environment of Space
- Related Material (URI)
- Has Version
- The First Lithium-ion Battery with Ionic Liquid Electrolyte Demonstrated in Extreme Environment of Space
- Is Referenced By
- Microfabricated emitter array for an ionic liquid electrospray thrusterAnalysis of the interfacial reaction between Si-based anodes and electrolytes in Li-ion batteriesDevelopment of High-Performance Compact On-Board Computer for Micro/Nano-Satellites with Software Resource Sharing FrameworkImpact of Low Temperatures on the Lithiation and Delithiation Properties of Si-Based Electrodes in Ionic Liquid ElectrolytesApplication of Ionic Liquids to Energy Storage and Conversion Materials and DevicesThermophysical Properties of Binary Amide Anion-Based Ionic Liquids; TMPAFSA<i><sub>x</sub></i>TFSA<sub>1−</sub><i><sub>x</sub></i>イオン液体リチウム二次電池の実現と応用イオン液体の応用展開Effects of Lithium Salt Concentration in Ionic Liquid Electrolytes on Battery Performance of LiNi<sub>0.5</sub>Mn<sub>0.3</sub>Co<sub>0.2</sub>O<sub>2</sub>/Graphite CellsDevelopment of Lithium-Ion Pouch Cell Using Stainless-Steel Laminated Film for JAXA’s SLIM Lunar Lander
- References
- Charge–discharge behavior of graphite negative electrodes in bis(fluorosulfonyl)imide-based ionic liquid and structural aspects of their electrode/electrolyte interfacesLithium-ion rechargeable batteriesA Review of Ionic Liquid LubricantsThe Second Evolution of Ionic Liquids: From Solvents and Separations to Advanced Materials—Energetic Examples from the Ionic Liquid CookbookDevelopment and on-orbit operation of lithium-ion pouch battery for small scientific satellite “REIMEI”Energetic Nitrogen‐Rich Salts and Ionic LiquidsLithium bis(fluorosulfonyl)imide–PYR14TFSI ionic liquid electrolyte compatible with graphiteHigh-performance graphite negative electrode in a bis(fluorosulfonyl)imide-based ionic liquidFuel Cell or Battery: Electric Cars are the FutureIonic-liquid materials for the electrochemical challenges of the futurePure ionic liquid electrolytes compatible with a graphitized carbon negative electrode in rechargeable lithium-ion batteriesPhilosophy and key features of 'Hodoyoshi' concept for optical remote sensing using 50kg class satellitesApplications of Ionic Liquids in Science and TechnologyIonic liquids containing carbonate solvent as electrolytes for lithium ion cellsUse of Organic Esters as Cosolvents in Electrolytes for Lithium-Ion Batteries with Improved Low Temperature PerformanceLithium batteries for aerospace applications: 2003 Mars Exploration RoverReport of the Electrolytic Industries for the Year 1997Application of bis(fluorosulfonyl)imide-based ionic liquid electrolyte to silicon–nickel–carbon composite anode for lithium-ion batteriesStable cycling of graphite in an ionic liquid based electrolyteThe Initial Stages of Radiation Damage in Ionic Liquids and Ionic Liquid-Based Extraction SystemsToward Radiation-Resistant Ionic Liquids. Radiation Stability of Sulfonyl Imide AnionsRecent developments in lithium ion batteriesScreening Li-ion batteries for internal shortsChallenge of portable powerIonic liquids as electrolytesOverview of Hodoyoshi microsatellites for remote sensing and its future prospectDesign of an electrolyte composition for stable and rapid charging–discharging of a graphite negative electrode in a bis(fluorosulfonyl)imide-based ionic liquidReversibility of Lithium Secondary Batteries Using a Room-Temperature Ionic Liquid Mixture and Lithium MetalThe present status of the Japanese Penetrator Mission: LUNAR-AIonic electroactive polymer artificial muscles in space applicationsN-Allyl-N-methylpiperidinium bis(trifluoromethanesulfonyl)imide—A film forming ionic liquid for graphite anode of Li-ion batteriesThe PROBA/CHRIS mission: a low-cost smallsat for hyperspectral multiangle observations of the Earth surface and atmosphereThe impedance characteristics of Mars Exploration Rover Li-ion batteriesQuaternary Ammonium Ionic Liquid Electrolyte for a Silicon Nanowire-Based Lithium Ion BatteryIonic liquid electrolytes compatible with graphitized carbon negative without additive and their effects on interfacial propertiesReversible Lithium‐Graphite Anodes in Room‐Temperature Chloroaluminate MeltsElectrochemistry and the Future of the AutomobileRadiation Induced Redox Reactions and Fragmentation of Constituent Ions in Ionic Liquids. 1. AnionsHighly reversible lithium metal secondary battery using a room temperature ionic liquid/lithium salt mixture and a surface-coated cathode active materialElectrochemical intercalation of lithium into a natural graphite anode in quaternary ammonium-based ionic liquid electrolytesThe Performance of the Lithium-Ion Secondary Cells under Micro-Gravity Conditions-In-Orbit Operation of the Interplanetary Spacecraft 'HAYABUSA'Charge and discharge performance of over-discharged lithium-ion secondary battery: lessons learned from the operation of the interplanetary spacecraft HAYABUSAImpact of Lithium Salt Addition to Ionic Liquid Electrolytes for High-performance Electric Double-layer CapacitorsElectrochemical Behavior of Graphite–Lithium Intercalation Electrode in AlCl3–EMIC–LiCl–SOCl2 Room-Temperature Molten SaltCharge-Discharge Characteristics of a LiNi₁/₃Mn₁/₃Co₁/₃O₂ Cathode in FSI-based Ionic Liquids
- Data Provider (Database)
- 国立情報学研究所 : CiNii Research
- Original Data Provider (Database)
- Japan Link Center雑誌記事索引データベースCrossrefCiNii Articles学術機関リポジトリデータベース学術機関リポジトリデータベースCrossrefCrossrefCrossrefCrossrefCrossrefCrossrefCrossrefCrossrefCrossrefCrossref
- Bibliographic ID (NDL)
- 026770570
- NAID
- 130005100785