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001442840 001__ 1442840
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001442840 020__ $$a9783030798994$$q(electronic bk.)
001442840 020__ $$a3030798992$$q(electronic bk.)
001442840 020__ $$z9783030798987
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001442840 0247_ $$a10.1007/978-3-030-79899-4$$2doi
001442840 035__ $$aSP(OCoLC)1286662857
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001442840 049__ $$aISEA
001442840 050_4 $$aTA418.9.N35$$bI56 2022
001442840 08204 $$a620.1/15$$223
001442840 24500 $$aInorganic materials for energy, medicine and environmental remediation /$$cSaravanan Rajendran, Mu. Naushad, Dai-Viet N. Vo, Eric Lichtfouse, editors.
001442840 264_1 $$aCham :$$bSpringer,$$c[2022]
001442840 264_4 $$c©2022
001442840 300__ $$a1 online resource
001442840 336__ $$atext$$btxt$$2rdacontent
001442840 337__ $$acomputer$$bc$$2rdamedia
001442840 338__ $$aonline resource$$bcr$$2rdacarrier
001442840 347__ $$atext file
001442840 347__ $$bPDF
001442840 4901_ $$aEnvironmental chemistry for a sustainable world,$$x2213-7122 ;$$vvolume 69
001442840 504__ $$aReferences-Chapter 2: Titanium Dioxide/Graphene Nanocomposites as High-Performance Anode Material for Lithium Ion Batteries-2.1 Introduction-2.2 Graphene Synthesis-2.2.1 Exfoliation of Graphite-2.2.2 Deposition on Targets-2.3 Graphene for Energy Applications-2.3.1 Graphene as Active Electrode Material in Lithium Ion Batteries-2.4 Lithium ion Batteries-2.5 Graphene-Based Anodes for LIBs-2.5.1 Anode Materials and Their Properties-2.5.2 Graphene Anodes for Lithium Ion Batteries-2.5.3 Graphene Metal Oxide Composite Anode for Lithium Ion Batteries.
001442840 5050_ $$aChapter 1 Localized surface plasmon resonance in colloidal copper sulphide (Cu2-xS, x=0d"^nts in wastewater -- Chapter 9 Removal of persistent organic pollutants using redox active metal oxide nanocatalysts via advanced oxidation process -- Chapter 10 Metal-based particles as a catalyst for Proton exchange membrane fuel cells.
001442840 506__ $$aAccess limited to authorized users.
001442840 520__ $$aThis book presents concepts, methods and applications of inorganic nanomaterials for energy applications such as fuel cells and batteries, for environmental applications such as water purification, and for medicinal applications such as cancer treatments. The founding father of nanotechnology, Eric Drexler, always communicated a unique vision in exploring new materials and creating advancements in molecular nanotechnology. He emphasized the potential advantages of smaller size, higher efficiency and less needed resources for applications in energy, environment and medicine. A higher surface to volume ratio of inorganic nanomaterials is a key property.
001442840 588__ $$aOnline resource; title from PDF title page (SpringerLink, viewed December 6, 2021).
001442840 650_0 $$aNanostructured materials.
001442840 650_6 $$aNanomatériaux.
001442840 655_0 $$aElectronic books.
001442840 7001_ $$aRajendran, Saravanan,$$eeditor.
001442840 7001_ $$aNaushad, Mu,$$eeditor.
001442840 7001_ $$aN. Vo, Dai-Viet,$$eeditor.
001442840 7001_ $$aLichtfouse, Eric,$$eeditor.
001442840 77608 $$iPrint version:$$z3030798984$$z9783030798987$$w(OCoLC)1253474255
001442840 830_0 $$aEnvironmental chemistry for a sustainable world ;$$vv. 69.$$x2213-7122
001442840 852__ $$bebk
001442840 85640 $$3Springer Nature$$uhttps://univsouthin.idm.oclc.org/login?url=https://link.springer.com/10.1007/978-3-030-79899-4$$zOnline Access$$91397441.1
001442840 909CO $$ooai:library.usi.edu:1442840$$pGLOBAL_SET
001442840 980__ $$aBIB
001442840 980__ $$aEBOOK
001442840 982__ $$aEbook
001442840 983__ $$aOnline
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