Advanced Battery Materials E-Book

Guide

Cover

Copyright

Table of Contents

Begin Reading

List of Illustrations

Chapter 1

Figure 1.1

Schematic illustrations of SIBs (a) and recent research progress in anode for SI...

Figure 1.2

(a) The graphite intercalation compounds of Li

+

and Na

+

io...

Figure 1.3

The charge-discharge (voltage vs. capacity) curves of glucose derived hard carbo...

Figure 1.4

Initial two charge-discharge curves of the HCNWs in (a) SIBs and (b) LIBs. (c) I...

Figure 1.5

(a) XRD patterns of the activated samples (CPM-A) obtained at different temperat...

Figure 1.6

(a) The evolution of characteristics of hard carbons, including V

micro

...

Figure 1.7

(a) Sodiation (discharge) profiles of different carbons, the sucrose derived har...

Figure 1.8

TEM images of different carbon samples: (a) HC, (b) P-HC, (c) S-HC, and (d) B-HC...

Figure 1.9

(a,b,c) A series of charge-discharge curves of hard carbons carbonized at variou...

Figure 1.10

(a) The schematic illustration of Na+ ions storage in graphite-based materials, ...

Figure 1.11

(a) TEM image, (b) HRTEM image, (c) cycle performance, and (d) rate property of ...

Figure 1.12

(a,b) SEM) images, (c) TEM image, and (d) HRTEM image of the G@HPC. (e) The sche...

Figure 1.13

(a) SEM image, (b) TEM image, and (c) HRTEM image of the 3D PCFs. (d, f, g) Cycl...

Figure 1.14

(a) The SEM image of MoO

2

@C nanofibers annealing at 850 °C. (b...

Figure 1.15

(a,b) SEM images, (c) TEM image, and (d) HRTEM image of the N-doped graphene foa...

Figure 1.16

(a,b) SEM images, (c) TEM image, (d) HRTEM image, (e) high-angle annular dark-fi...

Figure 1.17

(a) Raman spectra, (b) XPS spectra (N1s), (c) porosity distribution, (d, e, g) S...

Figure 1.18

(a) SEM image, (b) HRTEM image, and (c) high-resolution XPS spectra of S2p of th...

Figure 1.19

(a) TEM image, (b) HRTEM image, (c) SEM image, and (d) elemental mappings of the...

Figure 1.20

(a) The schematic illustration of the preparation process of GPC by annealing th...

Figure 1.21

(a) The schematic of synthetic process of S/N-codoped carbon (S-N/C). (b) SEM im...

Figure 1.22

(a) SEM and (b) TEM images of the N/O-codoped carbon (NOC) network. (c) The sche...

Figure 1.23

(a) The synthesis process of BN-CNFs. SEM images of (b) bacterial cellulose (BC)...

Figure 1.24

(a) The schematic illustration of the preparation process of oxygen-rich carbon ...

Figure 1.25

SEM images of (a) cotton and (b) carbonized cotton, the inset is the digital ima...

Figure 1.26

The typical synthetic process of hard carbon from biowaste apple. Reproduced wit...

Figure 1.27

Digital images of the leaf (a) before and (b) after carbonization. (c) The SEM i...

Figure 1.28

(a) The digital image of camphor tree. (b, c) SEM, d, e) TEM, and (f) HRTEM imag...

Figure 1.29

(a) SEM image of the cross-section of the raw apricot shell, (b) SEM and (c) TEM...

Chapter 2

Figure 2.1

(a) Hexagonal supercell of LTO in spinel phase with correct stoichiometry (Li...

Figure 2.2

The voltage of a spinel lithium titanium oxide anode and various cathode materia...

Figure 2.3

(a) 0D, (b) 1D, (c) 2D and (d) 3D nano-architectures.

Figure 2.4

(a) Schematic formation process of microemulsion-assisted ultrafine Li

4

...

Figure 2.5

FESEM (a) and TEM (b) images of SiO

2

@a-TiO

2

. FESEM (c) and...

Figure 2.6

(a) Schematic illustration for the fabrication of H-LTO nanowires[64]; (b) Schem...

Figure 2.7

(a and b) SEM images of electrospun LTONFs before heat treatment at low and high...

Figure 2.8

(a) Schematic representation of the fabrication sequence of Na

x

...

Figure 2.9

TEM images and scheme of single-layer (a) and overlapped LTO nanosheets (b); (c)...

Figure 2.10

TEM images of as-prepared samples: (a) precursor of LTO and (b) precursor of LTO...

Figure 2.11

Cross-sectional (a) and top-view (b) SEM images of Li

4

Ti

5

O...

Figure 2.12

(a) Scheme illustration of the preparation of LTO/G materials89; (b) The synthet...

Figure 2.13

Schematic illustration of the formation process of HLTOMs [92].

Figure 2.14

(a) Fabrication schematics of CC-CNTs/LTO core/shell arrays; SEM images of (b,c)...

Figure 2.15

SEM images of LTO/VACNT composites: (a) side view, (b) higher magnification SEM ...

Figure 2.16

Schematic of (a) aerosol spray drying process and (b) the prepared nanostructure...

Figure 2.17

Schematic illustration of the formation process of LTO-TO microspheres [100].

Figure 2.18

Schematic presentation of the conventional solid-state process for micron-size L...

Figure 2.19

Schematic illustration of the synthetic process of microscale spherical, carbon-...

Figure 2.20

Comparison of cycling performance for five Na

x

Li

4-x

Ti...

Figure 2.21

(a) Illustration of the formation mechanism for Cr-modified Li

4

Ti...

Figure 2.22

Schematic model of synthetic procedure: (a) mixed raw materials heated at 400 ...

Figure 2.23

Electrochemical performance of the all-fiber LIB device with gel electrolyte. (a...

Figure 2.24

LTO batteries can be used for multi-usages (SCIB

TM

).

Figure 2.25

(a-b) The 1 MW model of the energy storage system (ESS) built by Altairnano Tech...

Figure 2.26

(a) Zhangbei flexible HVDC project converter station; (b) Shenzheng Baoqing batt...

Figure 2.27

Schematic illustration of the electrostatic and electrochemical charge and disch...

Figure 2.28

(a) Discharging-charging voltage profiles of the C-Gd-LTO nanosheets at differen...

Chapter 3

Figure 3.1

A schematic illustration of three typical reaction mechanisms between transition...

Figure 3.2

The TEM and HRTEM images of TiO

2

hollow (a) and mesoporous (b) nanosp...

Figure 3.3

(a) Schematic illustration of the coating of TiO

2

nanospheres with a-...

Figure 3.4

(a) Schematic illustration for the synthesis of mesopore MnO@N-C/rGO hybrids. SE...

Figure 3.5

SEM images (a-b) and cycling properties (c) at 1C rate of GF@Fe

3

O...

Figure 3.6

SEM images of single-shelled (a), doulbe-shelled (b) and triple-shelled (c) Co...

Figure 3.7

(a-d) Typical SEM images of ZnCo

2

O

4

nanowire arrays growin...

Figure 3.8

SEM and TEM images of (a,b) Ni(dmg)

2

and (c,d) porous NiO microtubes....

Figure 3.9

(a) Schematic illustration of the formation of CuO/Cu

2

O-GPC. (b) Cycl...

Figure 3.10

SEM (a), TEM (b), HRTEM (c), STEM and the corresponding element mappings (d) of ...

Figure 3.11

(a) Schematic illustration of the fabrication of sandwich like Ag-C@ ZnO-C@Ag-C ...

Figure 3.12

(a) Schematic illustration of the structure and phase evolution for common SnO...

Chapter 4

Figure 4.1

SEM images of (a) LiFePO

4

-stacked graphene composites and (b) LiFePO...

Figure 4.2

STEM, TEM and mapping images of the LiFePO

4

-graphene-carbon composite...

Figure 4.3

TEM images. High-resolution TEM images of the carbon-coated LiFePO

4

c...

Figure 4.4

Schematic flow-process diagram of the self-assembly process for LiFePO

4

/RGO particles [61].

Figure 4.5

TEM images of the LiMn

2

O

4

nanoparticles with low (a) and h...

Figure 4.6

(a) XRD patterns of bare Li

4

Ti

5

O

12

, Li...

Chapter 5

Figure 5.1

Summary of key features of different rechargeable batteries. Reprinted with perm...

Figure 5.2

Three failure mechanisms of Si electrodes: (a) Pulverization of Si particles; (b...

Figure 5.3

Relationship between different coulombic efficiency and capacity retention [13]....

Figure 5.4

Schematic process of preparing pomegranate-like silicon/carbon microparticles. R...

Figure 5.5

Relevance among energy density, press density, volume variation and specific cap...

Figure 5.6

Flow chart of typical synthesis methods of Si-based anodes [54–55].

Figure 5.7

Scheme of H

2

O assisted ball milling. Reprinted with permission from R...

Figure 5.8

Scheme of synthesis for graphene caged micro-Si composites. Reprinted with permi...

Figure 5.9

Self-healing mechanism of SHP coated Si particles (a) and chemical structures of...

Figure 5.10

Schematic diagram of preparation for freestanding macro-porous Si/C composites. ...

Figure 5.11

SEM images of silicon produced by MACE method: nanowires (a), nano porous (b), h...

Figure 5.12

SEM figures and cycle performances of nest-like Si. Reprinted with permission fr...

Figure 5.13

Scheme of 3D-nanoporous Si from de-alloying (a); SEM and cycle performances. Rep...

Figure 5.14

Schematic diagram of synthetic process of mesoporous Si(a); TEM(b) and SEM (c) i...

Figure 5.15

Schematic illustration of preparation process of mesoporous Si/C nanocomposites....

Figure 5.16

Scheme of synthetic process for interconnected 3D macro-/mesoporous silicon. Rep...

Figure 5.17

Scheme of preparation and lithium storage mechanism of hierarchically porous Si ...

Figure 5.18

Synthetic process of silicon nano sheet from natural clay (a), cycle performance...

Figure 5.19

Scheme of porous Si/C composites from SiO. Reprinted with permission from Ref 17...

Figure 5.20

Schematic illustration of preparation (a) and SEM(b) of carbon coated porous Si;...

Figure 5.21

Research trend of silicon anodes.

Chapter 6

Figure 6.1

Structure of MoO

2

shows the available empty sites for Li action. Repr...

Figure 6.2

FE-SEM image of the calcined product. Reproduced with permission from ref. 19, C...

Figure 6.3

(a) Cyclic voltammetry curves of MoO

2

electrode at a scan rate of 0.5...

Figure 6.4

(a) FE-SEM micrographs of MoO

2

/GO;(b) Enlarged FESEM micrographs of t...

Figure 6.5

Continuous discharge and charge curves of (a) MoO

2

/GO structures and ...

Figure 6.6

Structure of α-MoO

3

showing the available empty sites for Li i...

Figure 6.7

(a) The growth mechanism of h-MoO

3

nanorods. (b) Discharge-charge vol...

Figure 6.8

(a) Schematic representation of the synthesis of C-MoO

3

NRs. (b) Galv...

Figure 6.9

(a) Schematic representation of the syntheses of few-layer MoO

3

nanos...

Figure 6.10

(a) Schematic illustration of the growth mechanism of α-MoO

3

/I...

Figure 6.11

(a) The illustration of formation process for 3D-OHP-

a

-VO

x

/MoO...

Figure 6.12

The refined structural model of the MoS

2

. Reproduced with permission ...

Figure 6.13

(a) XRD patterns of the MoS

2

samples and HRTEM images of (b) FG-MoS...

Figure 6.14

(a) Charge and discharge curves of the as-prepared FG-MoS

2

, CG-MoS...

Figure 6.15

Schematic of MoSe

2

structure. Reproduced with permission from ref. 74...

Figure 6.16

(a) SEM image and (b) TEM image of the hybrids, revealing that MoSe

2

...

Figure 6.17

Structure of CoMoO

4

showing the chains of close-packed octahedral par...

Figure 6.18

(a) SEM and (b) TEM images of CoMoO

4

nanosheets constructed hollow na...

Figure 6.19

The structure of the FeMoO

4

. Reproduced with permission from ref. 90,...

Figure 6.20

(a) The schematic illustration of the formation of FeMoO

4

cubes; (b) ...

Figure 6.21

The crystal structure of NiMoO

4

. Reproduced with permission from ref....

Figure 6.22

Cyclicvoltammograms (a) and galvanostatic charge-discharge voltageprofile at 200...

Figure 6.23

Crystal structure of CaMoO

4

. Reproduced with permission from ref. 88,...

Figure 6.24

TEM images (a, b) and HRTEM (c) of CaMoO

4

sample. Cyclic voltammogram...

Chapter 7

Figure 7.1

Schematic configuration of a typical Li-S battery in organic electrolyte. Reprin...

Figure 7.2

Voltage profiles of a typical Li-S battery in organic electrolyte. Reprinted wit...

Figure 7.3

Sketch of hierarchical porous carbon network with

in-situ

formed graphene...

Figure 7.4

(a) High resolution TEM images of HCSs/S-LBL. (b) Prolonged cycle performance an...

Figure 7.5

Schematic formation of shell protected graphene–Li

2

S–C ...

Figure 7.6

FESEM images of Si/SiO

x

electrode: cross-sectional view (a) before pr...

Chapter 8

Figure 8.1

Comparison of volumetric and gravimetric energy density of different types of ba...

Figure 8.2

Scheme of charge carrier’s diffusion on the cathode side of a Lithium Bat...

Figure 8.3

Discharging (a) and charging (b) of a lithium battery.

Figure 8.4

Comparison of typical voltage profiles of lithium-ion battery anode materials: (...

Figure 8.5

(a) Schematic of Li

+

transport on cathode with a) carbon black partic...

Figure 8.6

Graphical representation of the polysulfide formation and shuttle effect affecti...

Figure 8.7

Schematic of the different structures of graphene composite electrode materials....

Figure 8.8

Scheme of the synthesized nanocomposite based on Wang

et al.,

[158].

Figure 8.9

A scheme of a GO membrane inside a Li-S battery. The GO membrane is sandwiched b...

Chapter 9

Figure 9.1

Molecular structures and abbreviations of the typical anions of ILs.

Figure 9.2

(Left) Electrostatic potential profiles for a range of surface charge densities ...

Figure 9.3

SEM of curved graphene sheets (scale bar 10 µm) prepared by the chemical ...

Figure 9.4

(a) TEM images of porous graphene nanofibers. (b) enlarged magnification of whit...

Figure 9.5

(a) Optical images of a suspension of a graphene oxide in propylene carbonate an...

Figure 9.6

SEM images of platelet CMK-5 (a) and the graphene-CMK-5 composite (b-d) with dif...

Figure 9.7

(a) SEM, (b,c) TEM, and (d) EDAX analysis of F-MWCNT/graphene/BMIM-TFSI ternary ...

Figure 9.8

Electrochemical characteristics of as-made asymmetric SCs: (a) schematic of the ...

Figure 9.9

(a) Digital photograph of the as-fabricated ternary hybrid film transferred onto...

Figure 9.10

(a) CV curves of the GQDs//MnO

2

asymmetric MSC at different scan rate...

Chapter 10

Figure 10.1

Energy densities (Whkg

−1

) for several types of rechargeable ba...

Figure 10.2

LIB operation illustration [2]. (Reprint with permission from [2] copyright (201...

Figure 10.3

LIBs Cathode and anode materials voltage versus capacity [3]. (Reprint with perm...

Figure 10.4

(a) Reversible capacity during the first cycle (b) Reversible capacity of gas an...

Figure 10.5

Demonstrated dependent of adsorption of Li ions on CNTs diameters, top view from...

Figure 10.6

Illustrated variation of Li/C ratio versus tube diameter, white balls represents...

Figure 10.7

SEM images for various diameters of tubes (a) 10–20 nm (b) 20–40 n...

Figure 10.8

High resolution TEM images for different lengths of tubes (c, d) long (a, b) mor...

Figure 10.9

Reversible capacity stability at 25 mAg

−1

for 30 cycles [39]. ...

Figure 10.10

Electrochemical measurements for various lengths and diameters of CNTs [40]. (Re...

Figure 10.11

The electrochemical measurements for freestanding paper CNTs [43]. (Reprint with...

Figure 10.12

Schematic illustration of LOBs operation [53]. (Reprint with permission from [53...

Figure 10.13

SEM images for (a) pure SWCNT paper (b) Ge/SWCNT-2 paper (c) cross-sectional vie...

Figure 10.14

(a) SEM image of the Ge/SWCNT-2 paper (b) EDS spectrum (c) EDS mapping of carbon...

Figure 10.15

Galvano static Charge-discharge curves for SWCNT paper and Ge/SWCNT-2 paper [66]...

Figure 10.16

Cyclic stability of SWCNT and Ge/SWCNT composite paper [66]. (Reprint with permi...

Figure 10.17

EIS for SWCNT and Ge/SWCNT-2 paper anode [66]. (Reprint with permission from [66...

Figure 10.18

EIS for PbGeO

3

and PbGeO

3

-GNS

2

(20 wt.%) anode be...

Figure 10.19

Comparison of CV curves of pure PNCNFs and Pd/PNCNF-2 composite O

2

-sa...

Figure 10.20

The discharge/charge capacities of LOBs from 2.35 to 4.35 V for PNCNF, and the P...

Figure 10.21

(a) XRD patterns for various charge discharge cycles (b) SEM images of Pd/PNCNF-...

Chapter 11

Figure 11.1

Energy and power densities of graphene-based SCs compared with commercially avai...

Figure 11.2

(a) Schematic formation of N-G by CVD. (b) CVD precursors with different functio...

Figure 11.3

(a) Schematic representation of optimized experimental parameters (temperature p...

Figure 11.4

Synthesis of N-GRW. Synthesis steps: (1) polymerization at 600 °C for 2 h...

Figure 11.5

The formation of NG by ball milling graphite with melamine. [113]

Figure 11.6

(a) Several possible SG clusters shown from left to right; S atoms adsorbed on t...

Figure 11.7

Fabrication of sulfur-doped graphene by thermal exfoliation of graphite oxide pr...

Figure 11.8

Preparation of PG. (a) Addition of H

2

PO

4

−...

Figure 11.9

Molecular model of S-, N-dual doped graphene [205].

Figure 11.10

Schematic illustration of the procedures for the synthesis of SNG [206].

Figure 11.11

Schematic diagrams of (a) an EDLC and (b) a PCs [229].

Figure 11.12

(a) Bonding configurations of nitrogen atoms in NG.7 Scanning electron microscop...

Figure 11.13

(a) SEM morphology of GO; (b) SEM morphology of the NG. (c) XPS spectra of the N...

Figure 11.14

(a) Photograph of an as-prepared superlight graphene framework (GF). (b) SEM ima...

Figure 11.15

(a) BH

3

-THF adduct and reaction scheme for the reduction of GO and pr...

Figure 11.16

(a) CV curves at a scan rate of 10 mV s

−1

, (b) specific capaci...

Figure 11.17

(a) CV of EGO, REGO, PEGO and PREGO at scan rate of 5 mV s

−1

w...

Figure 11.18

(a) Schematic illustration of the preparation of S-doped porous rGO hollow frame...

Figure 11.19

(a) Illustration of asymmetric solid-state SCs (ASCs) based on BN-doped graphene...

Figure 11.20

(a) Schematic of preparation BCN graphene; (b) CV curves of BCN graphene anneale...

Figure 11.21

A typical lithium-ion battery.

Figure 11.22

The calculated spin electronic density of states (DOS) of (a) graphitic, (b) pyr...

Figure 11.23

(a) Schematic representation of optimized experimental parameters for the growth...

Figure 11.24

(a) SEM image of the NG. (b) N1 s XPS spectrum of the NG. Inset schematic struct...

Figure 11.25

Schematic illustration for the preparation of N-doped MnO (N-MnO)/N-doped graphe...

Figure 11.26

(a) STEM image of BG and (b) C- and (c) B-elemental mapping of the square region...

Figure 11.27

(a) Schematic illustration of synthesis procedures of 3D N,S co-doped graphene h...

Figure 11.28

Comparison between different rechargeable battery chemistries in terms of gravim...

Figure 11.29

Diagram of a typical LSB (left), illustrating the movement of Li ions from the a...

Figure 11.30

(a) Schematic illustration of GO anchoring S. Yellow, red, and white balls denot...

Figure 11.31

Schematic illustration of the preparation process of graphene/sulfur electrode [...

Figure 11.32

NEXAFS spectra of the S K-edge (a) and C K-edge (b) of the S-GO cathode material...

Figure 11.33

(a) N 1 s XPS spectrum of the NG sheets. (b) The absorption of Li

2

S...

Figure 11.34

Schematic illustration of preparing S@NG nanocomposite and these soluble Li...

Figure 11.35

Electrochemical performance of the S@NG electrode at 0.5C (a), 1C (b) and 2C (c)...

Figure 11.36

S 2p

XPS spectra of S/CMK-3, S/NPC and S/BPC [304]....

Figure 11.37

Photographs of graphene sponges and schematic model of the assembled cell. (a) P...

Figure 11.38

Theoretical capacities, energy densities, and cell voltages of various metal ele...

Figure 11.39

Schematic operation principle of (a) ZABs and (b) LABs [308]....

Figure 11.40

(a) UPS spectra collected using an HeI (21.2 eV) radiation. (b) and (c) Carbon a...

Figure 11.41

(a) Schematic of a ZAB at charging and discharging conditions. (b) GCD profiles ...

Figure 11.42

The optical images of electrodes (a) before and (b) after water splitting powere...

Figure 11.43

(a, b) Optical images showing the utilization of a centimeter-sized freestanding...

Figure 11.44

Representative voltage profiles of the LABs with (a) NS-G300, (b) NS-G500 and (c...

Figure 11.45

Electrode materials and corresponding electrochemical performances in current NI...

Figure 11.46

(a) Initial charge–discharge curves of the NG, rGF, and N–GF at 0....

Chapter 12

Figure 12.1

The US Naval Research Laboratory’s large area plasma processing system (L...

Figure 12.2

XRD pattern for drop-cast graphene oxide film deposited on a glass substrate, a ...

Figure 12.3

Raman spectrum for the sample, (a) untreated (broken line) and (b) plasma treate...

Figure 12.4

Current-voltage curves for plasma plasma reduced graphene oxide sample at room t...

Figure 12.5

(a) Raman spectra of GO and PTGO monolayers and (b) the de-convoluted G-mode pea...

Figure 12.6

I–V plots for GO and PTGO monolayers. The plasma treatment durations (at ...

Figure 12.7

Raman spectra and XPS spectra of GO and r-GO. (a) Raman spectra and correspondin...

Figure 12.8

Electrical properties of r-GO sheet. (a) Schematic diagram (top) and a typical A...

Figure 12.9

The characteristics of plasma-fluorinated graphene [148] Shown are the C 1 s hig...

Figure 12.10

The concentration of functional groups added to graphene versus the operating pr...

Figure 12.11

Typical changes in the properties of graphene after exposure to beamdriven plasm...

List of Tables

Chapter 1

Table 1.1

Summary of the sodium storage performances of reported carbon materials.

Chapter 2

Table 2.1

Single crystal data of Li

4

Ti

5

O

12

Was obtained by a flux method [34].

Table 2.2

Different features of commercial anodes.

Table 2.3

The methods and performance of 0d lto based materials.

Table 2.4

The methods and performance of 1d lto based materials.

Table 2.5

The methods and performance of 2d lto based materials.

Table 2.6

Effect of different coating layers on the li

4

Ti

5

O

12

.

Table 2.7

The performance of doped lto materials.

Table 2.8

The electrochemical behaviors of Li

4

Ti

5

O

12

Full...

Chapter 4

Table 4.1

Summary of lifepo

4

/Graphene composites synthesized by doping modification.

Table 4.2

Summary of lifepo

4

/Graphene composites synthesized by surface modification.

Table 4.3

Summary of LiMn

2

O

4

/Graphene composites synthesized by different methods.

Table 4.4

Summary of li[ni

1-x-

y

Co

X

Mn

Y

]O...

Chapter 5

Table 5.1.

Price of Graphite and Common Si Sources [11, 56–60].

Chapter 6

Table 6.1

Electrochemical performances of carbon-based moo

3

Composites prepared...

Chapter 7

Table 7.1

Summary of trials to improve the anode performance of li-s batteries.

Table 7.2

Description of different electrolytes for li-s batteries.

Chapter 8

Table 8.1

Summary of experimental data for different cathode materials.

Chapter 11

Table 11.1

Summary of N-doping methods and N concentration on graphene.

Table 11.2

Summary of B-doping methods and B concentration on graphene.

Table 11.3

Summary of S-doped graphene and its applications.

Table 11.4

Summarizes the main methods for the synthesis of PG.

Table 11.5

Charge density of atoms in graphene model [205].

Pages

ii

iii

iv

vi

vii

1

2

3

4

5

6

7

8

9

10

11

12

13

14

15

16

17

18

19

20

21

22

23

24

25

26

27

28

29

30

31

32

33

34

35

36

37

38

39

40

41

42

43

44

45

46

47

48

49

50

51

52

53

54

55

56

57

58

59

60

61

62

63

64

65

66

67

68

69

70

71

72

73

74

75

76

77

78

79

80

81

82

83

84

85

86

87

88

89

90

91

92

93

94

95

96

97

98

99

100

101

102

103

104

105

106

107

108

109

110

111

112

113

114

115

116

117

118

119

120

121

122

123

124

125

126

127

128

129

130

131

132

133

134

135

136

137

138

139

140

141

142

143

144

145

146

147

148

149

150

151

152

153

154

155

156

157

158

159

160

161

162

163

164

165

166

167

168

169

170

171

172

173

174

175

176

177

178

179

180

181

182

183

184

185

186

187

188

189

190

191

192

193

194

195

196

197

198

199

200

201

202

203

204

205

206

207

208

209

210

211

212

213

214

215

216

217

218

219

220

221

222

223

224

225

226

227

228

229

230

231

232

233

234

235

236

237

238

239

240

241

242

243

244

245

246

247

248

249

250

251

252

253

254

255

256

257

258

259

260

261

262

263

264

265

266

267

268

269

270

271

272

273

274

275

276

277

278

279

280

281

282

283

284

285

286

287

288

289

290

291

292

293

294

295

296

297

298

299

300

301

302

303

304

305

306

307

308

309

310

311

312

313

314

315

316

317

318

319

320

321

322

323

324

325

326

327

328

329

330

331

332

333

334

335

336

337

338

339

340

341

342

343

344

345

346

347

348

349

350

351

352

353

354

355

356

357

358

359

360

361

362

363

364

365

366

367

368

369

370

371

372

373

374

375

376

377

378

379

380

381

382

383

384

385

386

387

388

389

390

391

392

393

394

395

396

397

398

399

400

401

402

403

404

405

406

407

408

409

410

411

412

413

414

415

416

417

418

419

420

421

422

423

424

425

426

427

428

429

430

431

432

433

434

435

436

437

438

439

440

441

442

443

444

445

446

447

448

449

450

451

452

453

454

455

456

457

458

459

460

461

462

463

464

465

466

467

468

469

470

471

472

473

474

475

476

477

478

479

480

481

482

483

484

485

486

487

488

489

490

491

492

493

494

495

496

497

498

499

500

501

502

503

504

505

506

507

508

509

510

511

512

513

514

515

516

517

518

519

520

521

522

523

524

525

526

527

528

529

530

531

532

533

534

535

536

537

538

539

540

541

542

543

544

545

546

547

548

549

550

551

552

553

554

555

556

557

558

559

560

561

562

563

564

565

566

567

568

569

570

571

572

573

574

575

576

577

578

579

580

581

582

583

584

585

586

587

588

589

590

591

592

593

594

595

596

597

598

599

600

601

602

603

604

605

606

607

608

609

610

611

612

613

614

615

616

617

618

619

620

621

622

623

624

625

626

627

628

629

630

631

632

633

634

635

636

637

638

639

640

641

642

643

644

645

646

647

648

649

650

651

652

Scrivener Publishing100 Cummings Center, Suite 541JBeverly, MA 01915-6106

Publishers at ScrivenerMartin Scrivener ([email protected])Phillip Carmical ([email protected])

Managing Editors: Sachin Mishra, S. Patra and Anshuman Mishra

Advanced Battery Materials

Edited by

This edition first published 2019 by John Wiley & Sons, Inc., 111 River Street, Hoboken, NJ 07030, USA and Scrivener Publishing LLC, 100 Cummings Center, Suite 541J, Beverly, MA 01915, USA© 2019 Scrivener Publishing LLCFor more information about Scrivener publications please visit www.scrivenerpublishing.com.

All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or by any means, electronic, mechanical, photocopying, recording, or otherwise, except as permitted by law. Advice on how to obtain permission to reuse material from this title is available at http://www.wiley.com/go/permissions.

Wiley Global Headquarters111 River Street, Hoboken, NJ 07030, USA

For details of our global editorial offices, customer services, and more information about Wiley products visit us at www.wiley.com.

Limit of Liability/Disclaimer of WarrantyWhile the publisher and authors have used their best efforts in preparing this work, they make no representations or warranties with respect to the accuracy or completeness of the contents of this work and specifically disclaim all warranties, including without limitation any implied warranties of merchantability or fitness for a particular purpose. No warranty may be created or extended by sales representatives, written sales materials, or promotional statements for this work. The fact that an organization, website, or product is referred to in this work as a citation and/or potential source of further information does not mean that the publisher and authors endorse the information or services the organization, website, or product may provide or recommendations it may make. This work is sold with the understanding that the publisher is not engaged in rendering professional services. The advice and strategies contained herein may not be suitable for your situation. You should consult with a specialist where appropriate. Neither the publisher nor authors shall be liable for any loss of profit or any other commercial damages, including but not limited to special, incidental, consequential, or other damages. Further, readers should be aware that websites listed in this work may have changed or disappeared between when this work was written and when it is read.

Library of Congress Cataloging-in-Publication Data

ISBN 978-1-119-40755-3

Preface

Electrochemical energy storage has played important roles in energy storage technologies for portable electronics and electric vehicle applications. During the past three decades, great progress has been made in research and development of various batteries, in terms of energy density increase and cost reduction. However, the energy density has to be further increased to achieve long endurance time. In this book, recent research and development in advanced electrode materials for electrochemical energy storage devices are showcased, including lithium ion batteries, lithium-sulfur batteries and metal-air batteries, sodium ion batteries and supercapacitors. The materials involve transition metal oxides, sulfides, Si-based material as well as graphene and graphene composites.

The contributors to the volume are battery scientists and engineers with excellent academic records and expertise. Each chapter is relatively independent of the others, with a structure which is easy for readers quickly find topics of interest. I hope that this book will be helpful for scientists and engineers working in the field of energy storage, especially the graduate students.

This book mainly addresses a primary discussion, latest research & developments, industry and the future of battery materials. The book begins with the discussion on the recent progress of the carbonaceous anode materials including the sodium storage performances of amormphous carbons, graphite/graphene-based carbons, heteroatoms-doped carbons, biomass derived carbons, and the corresponding sodium storage mechanism. In addition, the current critical issues, challenges and perspectives of carbon anode materials for sodium ion batteries are also discussed in this chapter. Chapter 2 summarizes the performance of lithium titanate-based lithium-ion batteries with three classified themes including organic half Li-ion cells, organic full Li-ion cells and Na-ion batteries. The outlook and perspective on lithium titanate-based lithium-ion batteries have also been concisely provided in this chapter. Recent research advance in the controllable fabrication and the future of various transition metal oxide-based electrode materials and their lithium storage properties are presented in chapter 3. In chapter 4, there is a discussion on the recent progresses on the effects of the graphene on the electrochemical performances of cathode materials. Additionally, the preparation and applications of the composites of carbonaceous materials with graphene in the anodes of lithium ion batteries has also been incorporated in this chapter. Chapter 5 summarizes the practically relevant studies on silicon anodes for Li-ion batteries. Chapter 6 provides a systematic summary of the synthesis techniques, modification methods, as well as electrochemical property and performance of Mo-based compounds in lithium/sodium-ion batteries. The electrochemical performances and the related charge/discharge mechanism is also discussed in this chapter. The current application situations have been described to introduce the state-of-art of Li-S battery in chapter 7.

Chapter 8 presents a critical overview of the state-of-art in the optimization and application of graphene derived materials for anodes, cathodes and separators in lithium batteries. In chapter 9, the recent achievements in the design and fabrication of flexible graphene-ionic liquids supercapacitors, and their application in portable electronics has been discussed. Chapter 10 provides an overview on composites of conducting polymers and activated carbon. Along with a detailed perspective on the reported experimental techniques and theoretical strategies to tune the properties of carbon and conducting copolymers composites based electrode materials. The preparation and application of doped graphene in the electrochemical energy storage systems has been summarized in chapter 11. Chapter 12 emphasizes the techniques of low temperature plasma processing and electron beam irradiation techniques to enhance the electrical properties of graphene oxide.

I would like to express my gratitude to all the contributors for their collective and fruitful work. It is their efforts and expertise that have made this book comprehensive, valuable and unique. Grateful thanks to Sachin Mishra, S. Patra and Anshuman Mishra for managing the chapters and their help and useful suggestions in preparing Advanced Battery Materials.

Finally, I would like to thank the International Association of Advanced Materials for all their help and direction.

Chunwen SunBeijing November 2018