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Magnesium batteries: research and applications PDF

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Magnesium Batteries Research and Applications 1 0 0 P F 7- 0 4 6 1 0 8 8 7 1 8 7 9 9/ 3 0 1 0. 1 oi: d g | or c. s s.r b u p s:// p htt n o 9 1 0 2 er b m e pt e S 3 n 1 o d e h s bli u P View Online Energy and Environment Series Editor-­in-c­hief: Heinz Frei, Lawrence­Berkeley­National­Laboratory,­USA 1 0 0 Series­editors: P F 7- Nigel Brandon OBE FREng, Imperial­College­London,­UK 0 4 Roberto Rinaldi, Imperial­College­London,­UK 6 1 0 Vivian Wing- Wah Yam, University­of­Hong­Kong,­Hong­Kong 8 8 7 1 Titles­in­the­series: 8 7 9/9 1: Thermochemical Conversion of Biomass to Liquid Fuels and Chemicals 03 2: Innovations in Fuel Cell Technologies 1 0. 3: Energy Crops 1 oi: 4: Chemical and Biochemical Catalysis for Next Generation Biofuels d g | 5: Molecular Solar Fuels or c. 6: Catalysts for Alcohol- Fuelled Direct Oxidation Fuel Cells s s.r 7: Solid Oxide Fuel Cells: From Materials to System Modeling b u p 8: Solar Energy Conversion: Dynamics of Interfacial Electron and Excitation ps:// Transfer n htt 9: P hotoelectrochemical Water Splitting: Materials, Processes and Archit ect ures o 9 10: Biological Conversion of Biomass for Fuels and Chemicals: Explorations 1 20 from Natural Utilization Systems ber 11: Advanced Concepts in Photovoltaics m e 12: Materials Challenges: Inorganic Photovoltaic Solar Energy pt Se 13: Catalytic Hydrogenation for Biomass Valorization 3 n 1 14: Photocatalysis: Fundamentals and Perspectives d o 15: Photocatalysis: Applications e h 16: Unconventional Thin Film Photovoltaics s bli 17: Thermoelectric Materials and Devices u P 18: X-R ay Free Electron Lasers: Applications in Materials, Chemistry and Biology 19: Lignin Valorization: Emerging Approaches 20: Advances in Photoelectrochemical Water Splitting: Theory, Experiment and Systems Analysis 21: Electrochemical Reduction of Carbon Dioxide: Overcoming the Limita- tions of Photosynthesis 22: Integrated Solar Fuel Generators 23: Magnesium Batteries: Research and Applications How­to­obtain­future­titles­on­publication: A standing order plan is available for this series. A standing order will bring delivery of each new volume immediately on publication. For­further­information­please­contact: Book Sales Department, Royal Society of Chemistry, Thomas Graham House, Science Park, Milton Road, Cambridge, CB4 0WF, UK Telephone: +44 (0)1223 420066, Fax: +44 (0)1223 420247, Email: [email protected] Visit our website at www.rsc.org/books View Online Magnesium Batteries Research and Applications 1 0 0 P F 7- 0 4 6 1 0 8 8 Edited by 7 1 8 7 9 9/ Maximilian Fichtner 3 10 Helmholtz­Institute­Ulm,­Germany 0. 1 Email: [email protected] oi: d g | or c. s s.r b u p s:// p htt n o 9 1 0 2 er b m e pt e S 3 n 1 o d e h s bli u P View Online 1 0 0 P F 7- 0 4 6 1 0 8 8 7 1 8 7 9 9/ Energy and Environment Series No. 23 3 0 1 0. Print ISBN: 978-1 - 78801- 434- 2 1 oi: PDF ISBN: 978- 1- 78801-6 40- 7 d g | EPUB ISBN: 978- 1- 78801- 896- 8 or Print ISSN: 2044- 0774 c. s.rs Electronic ISSN: 2044- 0782 b u p A catalogue record for this book is available from the British Library s:// p htt © The Royal Society of Chemistry 2020 n o 9 All­rights­reserved 1 0 2 er Apart­from­fair­dealing­for­the­purposes­of­research­for­non-c­ommercial­purposes­or­for­ b m private­study,­criticism­or­review,­as­permitted­under­the­Copyright,­Designs­and­Patents­ e ept Act­1988­and­the­Copyright­and­Related­Rights­Regulations­2003,­this­publication­may­ S 3 not­be­reproduced,­stored­or­transmitted,­in­any­form­or­by­any­means,­without­the­prior­ n 1 permission­in­writing­of­The­Royal­Society­of­Chemistry,­or­in­the­case­of­reproduction­in­ o d accordance­with­the­terms­of­licences­issued­by­the­Copyright­Licensing­Agency­in­the­UK,­ e h s or­in­accordance­with­the­terms­of­the­licences­issued­by­the­appropriate­Reproduction­ bli u Rights­Organization­outside­the­UK.­Enquiries­concerning­reproduction­outside­the­terms­ P stated­here­should­be­sent­to­The­Royal­Society­of­Chemistry­at­the­address­printed­on­ this­page. Whilst­this­material­has­been­produced­with­all­due­care,­The­Royal­Society­of­­ Chemistry­cannot­be­held­responsible­or­liable­for­its­accuracy­and­completeness,­nor­ for­any­consequences­arising­from­any­errors­or­the­use­of­the­information­contained­in­ this­publication.­The­publication­of­advertisements­does­not­constitute­any­endorsement­ by­The­Royal­Society­of­Chemistry­or­Authors­of­any­products­advertised.­The­views­and­ opinions­advanced­by­contributors­do­not­necessarily­reflect­those­of­The­Royal­Society­of­ Chemistry­which­shall­not­be­liable­for­any­resulting­loss­or­damage­arising­as­a­result­of­ reliance­upon­this­material. The Royal Society of Chemistry is a charity, registered in England and Wales, Number 207890, and a company incorporated in England by Royal Charter (Registered No. RC000524), registered office: Burlington House, Piccadilly, London W1J 0BA, UK, Telephone: +44 (0) 20 7437 8656. For further information see our web site at www.rsc.org Printed in the United Kingdom by CPI Group (UK) Ltd, Croydon, CR0 4YY, UK 5 0 0 P F 7- 0 4 6 Preface 1 0 8 8 7 1 8 7 9 9/ 3 0 1 0. 1 oi: Magnesium is one of the few elements on Earth that offers real long- d g | term potential for technical mass applications. One reason for this is that or reserves of Mg minerals are widespread and easy accessible and these c. s s.r reserves should last approximately 430 000 years (seawater not included), b u if the consumption remains constant. Another reason is that magnesium p s:// is recyclable and virtually non- toxic. Rather, it is an essential element in p htt nature and central in photosynthesis and for metabolic functions in ani- n o mals and humans. In batteries, the Mg ion can transport and store two 9 01 charges per ion and, thus, offers the potential for higher storage capacities, 2 er which is complemented by the fact that a Mg metal anode can work safely b m in a cell with a liquid electrolyte. In contrast, Li ions are stored in graphite e ept in the anode of current Li ion batteries, for safety reasons – and are thereby S 3 diluted by a factor of eight. on 1 A good, working and rechargeable Mg battery would not only be technical d e progress, which could potentially improve the performance of battery- driven h s bli applications, it would also be a relief, because it opens up the possibility for u P the mass production of big batteries, which is, in the mid- to long- term, more difficult to achieve with current Li ion technology due to the limitation of certain raw materials and the expensive recycling process for lithium. The work on Mg batteries started with some scattered publications a few decades ago. The feasibility was demonstrated in principle but it became clear that the classical concepts for electrolytes and electrodes cannot just be transferred or applied to Mg battery technology and more questions were raised than answered. Then, the field moved more in the focus of battery research in the 2000s, after a breakthrough had been achieved with the   Energy and Environment Series No. 23 Magnesium Batteries: Research and Applications Edited by Maximilian Fichtner © The Royal Society of Chemistry 2020 Published by the Royal Society of Chemistry, www.rsc.org v View Online vi Preface development of a new and effective electrolyte. However, there were still no more than 10 to 15 publications per year. This changed considerably in the 2010s when the number of publications steadily increased so that at the end of the decade, between 120 and 150 publications per year had been made on 5 00 various topics of Mg batteries. P 7-F After this initial phase, with its quest for the first electrolytes, cathodes and 0 4 anodes and after both progress and frustration, it is our aim to present here 6 1 0 a first extensive summary of the principles, state- of- the art and prospects of 8 8 7 Mg batteries. 1 8 7 The book will start with a general overview and motivation for a Mg battery 9 39/ by M. Fichtner, followed by an electrolyte part with a chapter on the develop- 0 0.1 ment of non-a queous systems by R. Mohtadi and O. Tutusaus and a chapter 1 oi: on solid- state magnesium ion conductors by C. Battaglia et al. Theoretical g | d modelling of multivalent ions in inorganic hosts is critical for an under- or standing of the dynamics and storage process of Mg in materials and will be c. s.rs introduced by G. Gautam and P. Canepa. The anode side seems simple and ub straightforward because pure Mg metal has been claimed to be suitable as p s:// an anode material. However, the chapter by E.M. Sheridan et al. shows that p htt there are many more options, which all have their prospects and drawbacks. on Complementing work is presented by M. Matsui in a chapter where the elec- 9 1 trochemical properties of magnesium metal and intermetallic anodes are 0 2 er discussed. b m One of the most critical issues in the field is the development of effective e pt insertion cathodes for magnesium batteries. Intercalation and conversion e S 3 materials and related mechanisms are introduced by H.D. Yoo and S.H. Oh. n 1 B. Ingram will further expand upon this discussion with a contribution on o ed high voltage cathodes, which includes a techno- economical evaluation based h blis on a methodology developed in their laboratory. The part on cathode mate- Pu rials will be complemented by an overview on organic electrodes by J. Bitenc and R. Dominko and a further contribution from Z. Zhao- Karger, who gives an overview of the properties and status of Mg sulfur batteries. An unusual but interesting concept is the dual- ion battery, which relies on the combination of the Mg ion plus a second ion, both reversibly stored in different electrodes. The concept, first results and interesting effects of the co- intercalation of cations and anions will be presented by H. Li et al. As aqueous (primary) Mg batteries are still one of the most widespread applications, D. Hoeche will present an overview on the sta- tus of this technology. Finally, although the development of Mg batteries is still at an early stage and the performance of Mg batteries is not yet competitive, data already available from laboratory cells has been collected by C. Tomasini Montene- gro et al. The data was evaluated for the first life- cycle analysis of Mg batteries and gives clear indications for further directions in the development of Mg battery cells. View Online Preface vii At this point, I would like to cordially thank all of the authors and co- authors for their commitment and dedication and their contributions to all of the relevant topics of Mg battery technology, making “Magnesium Batter- ies – Research and Applications” a comprehensive reflection of the state- of- 5 00 the art in the field. P F 07- Maximilian Fichtner 4 16 Helmholtz- Institute Ulm (HIU), Helmholtzstr. 11, Ulm, 89081, Germany 0 8 8 7 1 8 7 9 9/ 3 0 1 0. 1 oi: d g | or c. s s.r b u p s:// p htt n o 9 1 0 2 er b m e pt e S 3 n 1 o d e h s bli u P 9 0 0 P F 7- 0 4 6 Contents 1 0 8 8 7 1 8 7 9 9/ 3 0 1 0. 1 oi: Chapter 1 Motivation for a Magnesium Battery 1 d g | Maximilian Fichtner or c. s.rs 1.1 Introduction 1 b u 1.2 Overview on Research Topics 3 p s:// 1.2.1 Electrolytes 3 p htt 1.2.2 Cathodes 6 n o 1.2.3 Anodes 7 9 01 1.2.4 Mg Deposition and the Lack of 2 er Dendrite Formation 8 b m 1.3 Need for Better Batteries 9 e ept 1.4 Need for Sustainable Solutions 10 S 3 1.4.1 Cathode 11 on 1 1.4.2 Anode 11 d e 1.4.3 Electrolyte 12 h s bli 1.5 Magnesium as a Resource 12 u P 1.6 Conclusion 13 Acknowledgement 14 References 14 Chapter 2 Non- aqueous Electrolytes for Mg Batteries 17 R. Mohtadi and O. Tutusaus 2.1 Introduction 17 2.2 Halide- ion Containing Electrolytes 18 2.2.1 Carbon- based Anions 19 2.2.2 Nitrogen- based Anions 20   Energy and Environment Series No. 23 Magnesium Batteries: Research and Applications Edited by Maximilian Fichtner © The Royal Society of Chemistry 2020 Published by the Royal Society of Chemistry, www.rsc.org ix View Online x Contents 2.2.3 Oxygen- based Anions 21 2.2.4 Halides as Anions 27 2.2.5 Weakly Coordinating Anions 32 2.3 Chloride- free Magnesium Electrolytes 33 9 00 2.3.1 Halogen- free Simple Salts 33 P 7-F 2.3.2 Halogen- based Simple Salts 39 0 4 2.3.3 Halogen- based Reagents 45 6 1 0 2.3.4 Electrolytes Based on Non- ethereal Solvents 49 8 8 7 2.3.5 Solid State Electrolytes 50 1 8 7 Acknowledgement 53 9 39/ References 53 0 1 0. 1 oi: Chapter 3 Solid- state Magnesium- ion Conductors 60 g | d S. Payandeh, A. Remhof and C. Battaglia or c. s.rs 3.1 Introduction 60 ub 3.2 Phosphate- based Solid- state Magnesium- p s:// ion Conductors 62 p htt 3.2.1 Cation and Anion Substitution in MZP 64 on 3.2.2 Other Oxygen Containing Solid- state 9 1 Magnesium- ion Conductors 69 0 2 er 3.3 Chalcogenide- based Solid- state Magnesium- ion b m Conductors 70 e pt 3.4 Solid- state Magnesium- ion Conductors Based e S 3 on Complex Metal Hydrides 71 n 1 3.5 Solid- state Magnesium- ion Conductors Based o ed on Metal–Organic Frameworks 73 h blis 3.6 Conclusion 74 Pu References 75 Chapter 4 Theoretical Modelling of Multivalent Ions in Inorganic Hosts 79 Gopalakrishnan Sai Gautam and Pieremanuele Canepa 4.1 Introduction 79 4.1.1 Thermodynamics of Multivalent Electrodes 80 4.1.2 Kinetics of Ionic Diffusion in Materials 91 4.1.3 Density Functional Theory as a Tool to Assess Thermodynamic and Kinetic Properties 96 4.1.4 Application of First- principles Methods to Multivalent Ion Intercalation Hosts 98 4.2 Conclusions 109 Acknowledgement 110 References 110 View Online Contents xi Chapter 5 Anode Materials for Rechargeable Mg Batteries 114 K. Jayasayee, R. Berthelot, K. C. Lethesh and E. M. Sheridan 5.1 Introduction 114 9 00 5.2 Insertion- type Anodes 118 P 7-F 5.2.1 Graphite 118 0 4 5.2.2 Phospherenes 119 6 1 0 5.2.3 Borophenes 120 8 8 7 5.2.4 Transition Metal Carbides 121 1 8 7 5.2.5 Li Ti O 122 9 4 5 12 039/ 5.2.6 Na2Ti3O7 124 0.1 5.2.7 Li3VO4 125 1 oi: 5.2.8 FeVO4 126 g | d 5.3 Alloying- type Negative Electrode Materials 127 or 5.3.1 Electrochemical Behavior of Single c. s.rs Metal Alloy Electrodes 128 ub 5.3.2 Electrochemical Behavior of Bimetallic p s:// Alloy Electrodes 132 p htt 5.3.3 Interest in the Direct Use of MgxM on Alloys 134 9 1 5.4 Conclusions and Perspective 136 0 2 er References 137 b m e pt Chapter 6 Mg Stripping and Plating at Magnesium Metal and e S 3 Intermetallic Anodes 142 n 1 M. Matsui o d e h blis 6.1 Introduction 142 Pu 6.2 Overview of the Electrolyte Solutions 143 6.3 Deposition Mechanism 150 6.4 Surface Morphologies of Electrodeposited Magnesium Metal 151 6.5 Passivation Layer and Possible SEI Layer 157 6.6 Intermetallic Anodes 160 6.7 Summary 163 References 164 Chapter 7 Insertion Electrodes for Magnesium Batteries: Intercalation and Conversion 167 H. D. Yoo and S. H. Oh 7.1 Introduction 167 7.2 Materials for Intercalation 169 7.2.1 Layered Sulfides and Selenides 169 7.2.2 Layered Oxides 171 7.2.3 Graphite 173

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