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Electrodes for li-ion batteries . Volume 2 Materials, mechanisms and performance / / Laure Monconduit, Laurence Croguennec, Rémi Dedryvère
| Electrodes for li-ion batteries . Volume 2 Materials, mechanisms and performance / / Laure Monconduit, Laurence Croguennec, Rémi Dedryvère |
| Autore | Monconduit Laure |
| Pubbl/distr/stampa | London, England ; ; Hoboken, New Jersey : , : ISTE : , : Wiley, , 2015 |
| Descrizione fisica | 1 online resource (102 p.) |
| Disciplina | 621.31242 |
| Collana | Energy Series : Energy Storage - Batteries and Supercapacitors Set |
| Soggetto topico |
Electric batteries - Materials
Energy storage - Materials Power electronics - Materials |
| ISBN |
1-119-00738-0
1-119-00737-2 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
""Cover""; ""Title Page""; ""Copyright""; ""Contents""; ""Acknowledgments""; ""Preface""; ""Introduction""; ""Toward efficient Li-ion batteries""; ""1: Negative Electrodes""; ""1.1. Preamble""; ""1.2. Classic materials: insertion mechanism""; ""1.2.1. Graphitic carbon""; ""1.2.1.1. Lithium intercalation mechanisms""; ""1.2.1.2. Electrode/electrolyte interface and additives""; ""1.2.2. Titanium oxides""; ""1.2.2.1. Li4Ti5O12""; ""1.2.2.2. TiO2""; ""1.2.2.3. Different crystallographic arrangements""; ""1.2.2.4. Performances and mechanisms""; ""1.2.2.5. Optimizations""
""1.3. Toward other materials and other mechanisms""""1.3.1. Silicon""; ""1.3.1.1. Lithiation/delithiation mechanisms""; ""1.3.1.2. Nanostructured silicon""; ""1.3.1.3. Electrode formulation""; ""1.3.1.4. Aging mechanisms""; ""1.3.2. Other block p elements""; ""1.3.2.1. The alloys""; ""1.3.2.2. The conversion materials""; ""1.3.2.3. Limitations: volume changes and instability of the SEI""; ""1.3.2.4. Nanostructuration""; ""1.3.2.5. Electrode formulation""; ""1.3.2.6. Electrolyte formulation: the effect of additives""; ""1.4. Summary on negative electrodes""; ""2: Positive Electrodes"" ""2.1. Preamble""""2.2. Layered transition metal oxides as positive electrode materials for Li-ion batteries: from LiCoO2 to Li1+xM1-xO2""; ""2.2.1. The layered oxide LiCoO2: the starting point""; ""2.2.2. From LiNiO2, initially explored as an alternative to LiCoO2, to the commercialization of LiNi0.80Co0.15Al0.05O2 (NCA) and LiNi1/3Mn1/3Co1/3O2 (NMC)""; ""2.2.3. Electrode/electrolyte interfaces and aging phenomena in layered oxides""; ""2.2.4. High-capacity Li-rich layered oxides""; ""2.2.4.1. Toward unprecedented gravimetric capacities"" ""2.2.4.2. Surface phenomena and electrode/electrolyte interface stabilization""""2.2.4.3. Conclusion""; ""2.3. Alternatives to layered oxides""; ""2.3.1. Materials with spinel structure: from LiMn2O4 to LiNi1/2Mn3/2O4""; ""2.3.1.1. LiMn2O4, a material with three-dimensional structure""; ""2.3.1.2. Dissolution of LiMn2O4 at the interface with the electrolyte""; ""2.3.1.3. LiNi0.5Mn1.5O4: toward high potentials""; ""2.3.1.4. Improving the electrode/electrolyte interface at high potential""; ""2.3.2. The olivine phase LiFePO4: a small revolution""; ""Conclusion""; ""Bibliography""; ""Index"" |
| Record Nr. | UNINA-9910131256803321 |
Monconduit Laure
|
||
| London, England ; ; Hoboken, New Jersey : , : ISTE : , : Wiley, , 2015 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Electrodes for li-ion batteries . Volume 2 Materials, mechanisms and performance / / Laure Monconduit, Laurence Croguennec, Rémi Dedryvère
| Electrodes for li-ion batteries . Volume 2 Materials, mechanisms and performance / / Laure Monconduit, Laurence Croguennec, Rémi Dedryvère |
| Autore | Monconduit Laure |
| Pubbl/distr/stampa | London, England ; ; Hoboken, New Jersey : , : ISTE : , : Wiley, , 2015 |
| Descrizione fisica | 1 online resource (102 p.) |
| Disciplina | 621.31242 |
| Collana | Energy Series : Energy Storage - Batteries and Supercapacitors Set |
| Soggetto topico |
Electric batteries - Materials
Energy storage - Materials Power electronics - Materials |
| ISBN |
1-119-00738-0
1-119-00737-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
""Cover""; ""Title Page""; ""Copyright""; ""Contents""; ""Acknowledgments""; ""Preface""; ""Introduction""; ""Toward efficient Li-ion batteries""; ""1: Negative Electrodes""; ""1.1. Preamble""; ""1.2. Classic materials: insertion mechanism""; ""1.2.1. Graphitic carbon""; ""1.2.1.1. Lithium intercalation mechanisms""; ""1.2.1.2. Electrode/electrolyte interface and additives""; ""1.2.2. Titanium oxides""; ""1.2.2.1. Li4Ti5O12""; ""1.2.2.2. TiO2""; ""1.2.2.3. Different crystallographic arrangements""; ""1.2.2.4. Performances and mechanisms""; ""1.2.2.5. Optimizations""
""1.3. Toward other materials and other mechanisms""""1.3.1. Silicon""; ""1.3.1.1. Lithiation/delithiation mechanisms""; ""1.3.1.2. Nanostructured silicon""; ""1.3.1.3. Electrode formulation""; ""1.3.1.4. Aging mechanisms""; ""1.3.2. Other block p elements""; ""1.3.2.1. The alloys""; ""1.3.2.2. The conversion materials""; ""1.3.2.3. Limitations: volume changes and instability of the SEI""; ""1.3.2.4. Nanostructuration""; ""1.3.2.5. Electrode formulation""; ""1.3.2.6. Electrolyte formulation: the effect of additives""; ""1.4. Summary on negative electrodes""; ""2: Positive Electrodes"" ""2.1. Preamble""""2.2. Layered transition metal oxides as positive electrode materials for Li-ion batteries: from LiCoO2 to Li1+xM1-xO2""; ""2.2.1. The layered oxide LiCoO2: the starting point""; ""2.2.2. From LiNiO2, initially explored as an alternative to LiCoO2, to the commercialization of LiNi0.80Co0.15Al0.05O2 (NCA) and LiNi1/3Mn1/3Co1/3O2 (NMC)""; ""2.2.3. Electrode/electrolyte interfaces and aging phenomena in layered oxides""; ""2.2.4. High-capacity Li-rich layered oxides""; ""2.2.4.1. Toward unprecedented gravimetric capacities"" ""2.2.4.2. Surface phenomena and electrode/electrolyte interface stabilization""""2.2.4.3. Conclusion""; ""2.3. Alternatives to layered oxides""; ""2.3.1. Materials with spinel structure: from LiMn2O4 to LiNi1/2Mn3/2O4""; ""2.3.1.1. LiMn2O4, a material with three-dimensional structure""; ""2.3.1.2. Dissolution of LiMn2O4 at the interface with the electrolyte""; ""2.3.1.3. LiNi0.5Mn1.5O4: toward high potentials""; ""2.3.1.4. Improving the electrode/electrolyte interface at high potential""; ""2.3.2. The olivine phase LiFePO4: a small revolution""; ""Conclusion""; ""Bibliography""; ""Index"" |
| Record Nr. | UNINA-9910813342903321 |
|
Monconduit Laure
|
||
| London, England ; ; Hoboken, New Jersey : , : ISTE : , : Wiley, , 2015 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Les Batteries Na-Ion
| Les Batteries Na-Ion |
| Autore | Monconduit Laure |
| Pubbl/distr/stampa | London : , : ISTE Editions Ltd., , 2021 |
| Descrizione fisica | 1 online resource (402 pages) |
| Altri autori (Persone) | CroguennecLaurence |
| Collana | Sciences |
| ISBN | 1-78949-013-8 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | fre |
| Record Nr. | UNINA-9910861981003321 |
|
Monconduit Laure
|
||
| London : , : ISTE Editions Ltd., , 2021 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Na-ion batteries / / edited by Laure Monconduit, Laurence Croguennec
| Na-ion batteries / / edited by Laure Monconduit, Laurence Croguennec |
| Pubbl/distr/stampa | London, England ; ; Hoboken, New Jersey : , : ISTE Ltd. : , : John Wiley & Sons, Incorporated, , [2020] |
| Descrizione fisica | 1 online resource (375 pages) : illustrations |
| Disciplina | 621.31242 |
| Soggetto topico | Sodium ion batteries |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-5231-4364-9
1-119-81804-4 1-119-81805-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Half-Title Page -- Title Page -- Copyright Page -- Contents -- Introduction -- I.1. Why Na-ion batteries? -- I.2. From the electrodes to the electrolyte for NIBs -- I.2.1. Positive electrodes -- I.2.2. Negative electrodes -- I.2.3. Electrolytes and the solid electrolyte interphase -- I.3. Future commercialization of NIBs -- I.4. References -- 1. Layered NaMO2 for the Positive Electrode -- 1.1. Research history of layered transition metal oxides as electrode materials for Na-ion batteries until 2009 -- 1.2. Crystal structures of layered materials -- 1.2.1. Crystal structures of synthesizable NaxMO2 -- 1.2.2. Structural changes of O3-NaMO2 by Na extraction -- 1.2.3. Structural changes of P2-NaxMO2 by Na extraction -- 1.3. O3-type layered materials -- 1.3.1. NaMO2 (M = Sc, Ti, V, Cr, Mn, Fe, Co, Ni) -- 1.3.2. O3-Na[M,M']O2 (M, M' = transition metals) -- 1.3.3. Moist air stability of O3-NaMO2 and surface coating -- 1.4. P2-type layered materials -- 1.4.1. Practical issues of P2-type materials for Na-ion batteries -- 1.4.2. P2-Na2/3[Mn,Co,M]O2 -- 1.4.3. P2-Na2/3[Mn,Fe,M]O2 -- 1.4.4. P2-Na2/3[Ni,Mn,M]O2 -- 1.5. Summary and prospects -- 1.6. Acknowledgments -- 1.7. References -- 2. Polyanionic-Type Compounds as Positive Electrodes for Na-ion batteries -- 2.1. Introduction -- 2.1.1. Oxides and polyanionic frameworks as positive electrodes for sodium ion-batteries -- 2.1.2. NASICONs and Na3V2(PO4)2F3 -- 2.2. NASICON structures as model frameworks in sodium-ion battery applications -- 2.2.1. Compositional diversity from solid electrolytes to electrodes -- 2.2.2. NASICON-typed materials as electrodes for Na batteries -- 2.2.3. Na3V2(PO4)3 (NVP) -- 2.3. Na3V2(PO4)2F3 used as a model framework in sodium-ion battery applications -- 2.3.1. Structural description and compositional diversity.
2.3.2. Na3V2(PO4)2F3: a promising active material for positive electrodes in NIBs -- 2.3.3. Oxygen substitution in Na3V2(PO4)2F3 and its effects on the electrochemical performance of substituted phases -- 2.3.4. Paving the way toward Na3V2(PO4)2F3 with superior performance -- 2.4. Conclusion and perspectives -- 2.5. References -- 3. Hard Carbon for Na-ion Batteries: From Synthesis to Performance and Storage Mechanism -- 3.1. Introduction -- 3.2. What is a hard carbon? -- 3.3. Hard carbon synthesis and microstructure -- 3.3.1. Synthetic precursors-based hard carbon synthesis -- 3.3.2. Bio-polymers derived hard carbon synthesis -- 3.3.3. Biomass-based hard carbon synthesis -- 3.4. Hard carbon characteristics -- 3.4.1. Hard carbon structure -- 3.4.2. Hard carbon porosity -- 3.4.3. Hard carbon surface chemistry -- 3.4.4. Hard carbon structural defects -- 3.5. Electrochemical performance -- 3.5.1. Materials performance -- 3.5.2. Full Na-ion system performance -- 3.5.3. Sodium insertion mechanisms in hard carbon -- 3.6. Conclusion -- 3.7. References -- 4. Non-Carbonaceous Negative Electrodes in Sodium Batteries -- 4.1. Introduction -- 4.2. Insertion materials -- 4.2.1. Insertion anodes based on titanium oxide and titanates -- 4.2.2. Insertion anodes based on transition metal chalcogenides -- 4.2.3. Insertion MXene-based anodes -- 4.2.4. Insertion organic anodes -- 4.3. Negative electrode materials based on electrochemical alloying with sodium -- 4.3.1. Silicon and germanium -- 4.3.2. Tin -- 4.3.3. Phosphorus -- 4.3.4. Antimony -- 4.3.5. Other post-transition metal elements -- 4.4. Negative electrode materials based on conversion reactions -- 4.4.1. Reaction mechanisms of CM -- 4.4.2. Approaches toward efficient anode CM for NIB -- 4.5. Conclusion -- 4.6. References -- 5. Electrolytes for Sodium Batteries -- 5.1. Introduction. 5.2. Liquid and solid electrolytes for sodium batteries -- 5.2.1. Organic liquid electrolytes -- 5.2.2. IL-based electrolytes -- 5.2.3. Hybrid electrolytes -- 5.2.4. Effects of additives and impurities -- 5.2.5. Solid-state electrolytes -- 5.3. Properties of IL-based electrolytes for Na batteries -- 5.3.1. Physical properties -- 5.3.2. Thermal stability -- 5.3.3. Electrochemical stability -- 5.4. Modeling IL-based electrolytes -- 5.5. Conclusion and future perspectives -- 5.6. Abbreviations -- 5.7. References -- 6. Solid Electrolyte Interphase in Na-ion batteries -- 6.1. Introduction -- 6.1.1. The solid electrolyte interphase -- 6.1.2. Characterization of the SEI -- 6.2. Physical properties of the Na-ion SEI -- 6.2.1. Electrochemical stability -- 6.2.2. Mechanical properties -- 6.2.3. Dissolution of SEI components -- 6.3. Comparisons of SEI in sodium- and lithium-based electrolytes -- 6.3.1. Formation and composition -- 6.3.2. Resistance -- 6.4. Conclusion -- 6.5. References -- 7. Batteries Containing Prussian Blue Analogue Electrodes -- 7.1. Introduction -- 7.1.1. Chapter introduction -- 7.1.2. History of Prussian blue -- 7.1.3. Physical characteristics: structure, composition and morphology -- 7.1.4. Synthetic methods -- 7.2. Electrochemistry of PBAs -- 7.2.1. Mechanism and resulting characteristics -- 7.2.2. Reaction potentials -- 7.2.3. PBA cathodes -- 7.2.4. PBA anodes -- 7.3. Prussian blue batteries -- 7.3.1. Cells containing two PBA electrodes -- 7.3.2. Cells containing one PBA electrode -- 7.3.3. Challenges for PBA batteries -- 7.4. Conclusion and future outlook -- 7.5. References -- 8. The Design, Performance and Commercialization of Faradion's Non-aqueous Na-ion Battery Technology -- 8.1. Introduction -- 8.2. Experimental -- 8.2.1. Active materials -- 8.2.2. Electrode fabrication -- 8.2.3. Pouch cell fabrication. 8.2.4. Faradion electrolyte -- 8.3. Cell performance -- 8.3.1. Half-cell cycling -- 8.3.2. Full Na-ion cell cycling: curves and stability -- 8.3.3. Rate capability -- 8.3.4. Temperature studies -- 8.3.5. Three-electrode cell studies -- 8.4. Safety and zero energy storage and transportation -- 8.5. Scale-up and prototyping -- 8.6. Demonstrators: stacks and packs -- 8.7. Business and IP strategy -- 8.8. Cost analysis -- 8.9. Future developments -- 8.10. Conclusion -- 8.11. Acknowledgments -- 8.12. References -- List of Authors -- Index -- EULA. |
| Record Nr. | UNINA-9910554883403321 |
| London, England ; ; Hoboken, New Jersey : , : ISTE Ltd. : , : John Wiley & Sons, Incorporated, , [2020] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Na-ion batteries / / edited by Laure Monconduit, Laurence Croguennec
| Na-ion batteries / / edited by Laure Monconduit, Laurence Croguennec |
| Pubbl/distr/stampa | London, England ; ; Hoboken, New Jersey : , : ISTE Ltd. : , : John Wiley & Sons, Incorporated, , [2020] |
| Descrizione fisica | 1 online resource (375 pages) : illustrations |
| Disciplina | 621.31242 |
| Soggetto topico | Sodium ion batteries |
| ISBN |
1-5231-4364-9
1-119-81804-4 1-119-81805-2 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto |
Cover -- Half-Title Page -- Title Page -- Copyright Page -- Contents -- Introduction -- I.1. Why Na-ion batteries? -- I.2. From the electrodes to the electrolyte for NIBs -- I.2.1. Positive electrodes -- I.2.2. Negative electrodes -- I.2.3. Electrolytes and the solid electrolyte interphase -- I.3. Future commercialization of NIBs -- I.4. References -- 1. Layered NaMO2 for the Positive Electrode -- 1.1. Research history of layered transition metal oxides as electrode materials for Na-ion batteries until 2009 -- 1.2. Crystal structures of layered materials -- 1.2.1. Crystal structures of synthesizable NaxMO2 -- 1.2.2. Structural changes of O3-NaMO2 by Na extraction -- 1.2.3. Structural changes of P2-NaxMO2 by Na extraction -- 1.3. O3-type layered materials -- 1.3.1. NaMO2 (M = Sc, Ti, V, Cr, Mn, Fe, Co, Ni) -- 1.3.2. O3-Na[M,M']O2 (M, M' = transition metals) -- 1.3.3. Moist air stability of O3-NaMO2 and surface coating -- 1.4. P2-type layered materials -- 1.4.1. Practical issues of P2-type materials for Na-ion batteries -- 1.4.2. P2-Na2/3[Mn,Co,M]O2 -- 1.4.3. P2-Na2/3[Mn,Fe,M]O2 -- 1.4.4. P2-Na2/3[Ni,Mn,M]O2 -- 1.5. Summary and prospects -- 1.6. Acknowledgments -- 1.7. References -- 2. Polyanionic-Type Compounds as Positive Electrodes for Na-ion batteries -- 2.1. Introduction -- 2.1.1. Oxides and polyanionic frameworks as positive electrodes for sodium ion-batteries -- 2.1.2. NASICONs and Na3V2(PO4)2F3 -- 2.2. NASICON structures as model frameworks in sodium-ion battery applications -- 2.2.1. Compositional diversity from solid electrolytes to electrodes -- 2.2.2. NASICON-typed materials as electrodes for Na batteries -- 2.2.3. Na3V2(PO4)3 (NVP) -- 2.3. Na3V2(PO4)2F3 used as a model framework in sodium-ion battery applications -- 2.3.1. Structural description and compositional diversity.
2.3.2. Na3V2(PO4)2F3: a promising active material for positive electrodes in NIBs -- 2.3.3. Oxygen substitution in Na3V2(PO4)2F3 and its effects on the electrochemical performance of substituted phases -- 2.3.4. Paving the way toward Na3V2(PO4)2F3 with superior performance -- 2.4. Conclusion and perspectives -- 2.5. References -- 3. Hard Carbon for Na-ion Batteries: From Synthesis to Performance and Storage Mechanism -- 3.1. Introduction -- 3.2. What is a hard carbon? -- 3.3. Hard carbon synthesis and microstructure -- 3.3.1. Synthetic precursors-based hard carbon synthesis -- 3.3.2. Bio-polymers derived hard carbon synthesis -- 3.3.3. Biomass-based hard carbon synthesis -- 3.4. Hard carbon characteristics -- 3.4.1. Hard carbon structure -- 3.4.2. Hard carbon porosity -- 3.4.3. Hard carbon surface chemistry -- 3.4.4. Hard carbon structural defects -- 3.5. Electrochemical performance -- 3.5.1. Materials performance -- 3.5.2. Full Na-ion system performance -- 3.5.3. Sodium insertion mechanisms in hard carbon -- 3.6. Conclusion -- 3.7. References -- 4. Non-Carbonaceous Negative Electrodes in Sodium Batteries -- 4.1. Introduction -- 4.2. Insertion materials -- 4.2.1. Insertion anodes based on titanium oxide and titanates -- 4.2.2. Insertion anodes based on transition metal chalcogenides -- 4.2.3. Insertion MXene-based anodes -- 4.2.4. Insertion organic anodes -- 4.3. Negative electrode materials based on electrochemical alloying with sodium -- 4.3.1. Silicon and germanium -- 4.3.2. Tin -- 4.3.3. Phosphorus -- 4.3.4. Antimony -- 4.3.5. Other post-transition metal elements -- 4.4. Negative electrode materials based on conversion reactions -- 4.4.1. Reaction mechanisms of CM -- 4.4.2. Approaches toward efficient anode CM for NIB -- 4.5. Conclusion -- 4.6. References -- 5. Electrolytes for Sodium Batteries -- 5.1. Introduction. 5.2. Liquid and solid electrolytes for sodium batteries -- 5.2.1. Organic liquid electrolytes -- 5.2.2. IL-based electrolytes -- 5.2.3. Hybrid electrolytes -- 5.2.4. Effects of additives and impurities -- 5.2.5. Solid-state electrolytes -- 5.3. Properties of IL-based electrolytes for Na batteries -- 5.3.1. Physical properties -- 5.3.2. Thermal stability -- 5.3.3. Electrochemical stability -- 5.4. Modeling IL-based electrolytes -- 5.5. Conclusion and future perspectives -- 5.6. Abbreviations -- 5.7. References -- 6. Solid Electrolyte Interphase in Na-ion batteries -- 6.1. Introduction -- 6.1.1. The solid electrolyte interphase -- 6.1.2. Characterization of the SEI -- 6.2. Physical properties of the Na-ion SEI -- 6.2.1. Electrochemical stability -- 6.2.2. Mechanical properties -- 6.2.3. Dissolution of SEI components -- 6.3. Comparisons of SEI in sodium- and lithium-based electrolytes -- 6.3.1. Formation and composition -- 6.3.2. Resistance -- 6.4. Conclusion -- 6.5. References -- 7. Batteries Containing Prussian Blue Analogue Electrodes -- 7.1. Introduction -- 7.1.1. Chapter introduction -- 7.1.2. History of Prussian blue -- 7.1.3. Physical characteristics: structure, composition and morphology -- 7.1.4. Synthetic methods -- 7.2. Electrochemistry of PBAs -- 7.2.1. Mechanism and resulting characteristics -- 7.2.2. Reaction potentials -- 7.2.3. PBA cathodes -- 7.2.4. PBA anodes -- 7.3. Prussian blue batteries -- 7.3.1. Cells containing two PBA electrodes -- 7.3.2. Cells containing one PBA electrode -- 7.3.3. Challenges for PBA batteries -- 7.4. Conclusion and future outlook -- 7.5. References -- 8. The Design, Performance and Commercialization of Faradion's Non-aqueous Na-ion Battery Technology -- 8.1. Introduction -- 8.2. Experimental -- 8.2.1. Active materials -- 8.2.2. Electrode fabrication -- 8.2.3. Pouch cell fabrication. 8.2.4. Faradion electrolyte -- 8.3. Cell performance -- 8.3.1. Half-cell cycling -- 8.3.2. Full Na-ion cell cycling: curves and stability -- 8.3.3. Rate capability -- 8.3.4. Temperature studies -- 8.3.5. Three-electrode cell studies -- 8.4. Safety and zero energy storage and transportation -- 8.5. Scale-up and prototyping -- 8.6. Demonstrators: stacks and packs -- 8.7. Business and IP strategy -- 8.8. Cost analysis -- 8.9. Future developments -- 8.10. Conclusion -- 8.11. Acknowledgments -- 8.12. References -- List of Authors -- Index -- EULA. |
| Record Nr. | UNINA-9910830484903321 |
| London, England ; ; Hoboken, New Jersey : , : ISTE Ltd. : , : John Wiley & Sons, Incorporated, , [2020] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||