03602nam a22004935i 4500001001800000003000900018005001700027007001500044008004100059020001800100020001900118024003500137040000900172082001500181100002900196245013700225264004600362300003500408336002600443337002600469338003900495347002400534505132800558520058901886650001502475650002602490650003302516650002602549650004402575650002602619650001502645650002202660650004702682650005702729650002402786650002302810650002502833700002902858700002802887710003402915773002002949776003602969856010303005978-0-387-34445-4DE-He21320260521091907.0cr nn 008mamaa100716s2009    xxu|    s    |||| 0|eng d  a9780387344454  a997803873444547 a10.1007/978-0-387-34445-42doi  cCICY04a541.372231 aYoshio, Masaki.eeditor.10aLithium-Ion Batteriesh[recurso electrónico] :bScience and Technologies /cedited by Masaki Yoshio, Ralph J. Brodd, Akiya Kozawa. 1aNew York, NY :bSpringer New York,c2009.  aXXVI, 452 p.bonline resource.  atextbtxt2rdacontent  acomputerbc2rdamedia  arecurso en líneabcr2rdacarrier  atext filebPDF2rda0 aSynopsis of the Lithium-Ion Battery Markets -- A Review of Positive Electrode Materials for Lithium-Ion Batteries -- Carbon Anode Materials -- Role-Assigned Electrolytes: Additives -- Carbon-Conductive Additives for Lithium-Ion Batteries -- Applications of Polyvinylidene Fluoride-related materials for Lithium-Ion Batteries -- SBR Binder (for Negative Electrode) and ACM Binder (for Positive Electrode) -- Production Processes for Fabrication of Lithium-Ion Batteries -- Polyanionic Cathode-Active Materials -- Overcharge Behavior of Metal Oxide-Coated Cathode Materials -- Development of Metal Alloy Anodes -- HEV Application -- Flame-Retardant Additives for Lithium-Ion Batteries -- High-Energy Capacitor Based on Graphite Cathode and Activated Carbon Anode -- Development of LiCoO 2 Used for Rechargeable Lithium-Ion Battery -- Cathode Materials: LiNiO2 and Related Compounds -- Manganese-Containing Cathode-Active Materials for Lithium-Ion Batteries -- Trends in Carbon Material as an Anode in Lithium-Ion Battery -- Functional Electrolytes Specially Designed for Lithium-Ion Batteries -- Lithium-Ion Battery Separators1 -- Polymer Electrolyte and Polymer Battery -- A Novel Hard-Carbon Optimized to Large-Size Lithium-Ion Secondary Batteries -- LiMn2O4 as a Large-Capacity Positive Material for Lithium-Ion Batteries.  aIn developing electrochemical cells, one must keep in mind that the real goal is to package and control all the materials and components (cathode and anode active materials, electrolytes, separators, current collectors etc.) in a limited volume to enable maximum energy storage without creating any safety problems. In this manner, Li-Ion batteries (LIB) were first introduced to practical use in 1991. This book contains an in-depth review of electrode materials, electrolytes and additives for LIB, as well as indicators of the future directions for continued maturation of the LIB. 0aCHEMISTRY. 0aCHEMISTRY, INORGANIC. 0aCHEMISTRY, PHYSICAL ORGANIC. 0aCHEMICAL ENGINEERING. 0aPRODUCTION OF ELECTRIC ENERGY OR POWER. 0aELECTRIC ENGINEERING.14aCHEMISTRY.24aELECTROCHEMISTRY.24aINDUSTRIAL CHEMISTRY/CHEMICAL ENGINEERING.24aPOWER ELECTRONICS, ELECTRICAL MACHINES AND NETWORKS.24aPHYSICAL CHEMISTRY.24aENERGY TECHNOLOGY.24aINORGANIC CHEMISTRY.1 aBrodd, Ralph J.eeditor.1 aKozawa, Akiya.eeditor.2 aSpringerLink (Online service)0 tSpringer eBooks08iPrinted edition:z978038734444740uhttp://dx.doi.org/10.1007/978-0-387-34445-4zVer el texto completo en las instalaciones del CICY