Citation: | Wanyao Zhang, Yufang Chen, Hongjing Gao, Wei Xie, Peng Gao, Chunman Zheng, Peitao Xiao. Review of regulating Zn2+ solvation structures in aqueous zinc-ion batteries[J]. Materials Futures, 2023, 2(4): 042102. doi: 10.1088/2752-5724/ace3de |
[1] |
Xu K 2004 Nonaqueous liquid electrolytes for lithium-based rechargeable batteries Chem. Rev. 104 4303–418
|
[2] |
Xu K 2014 Electrolytes and interphases in Li-ion batteries and beyond Chem. Rev. 114 11503–618
|
[3] |
Xiao P, Yun X, Chen Y, Guo X, Gao P, Zhou G and Zheng C 2023 Insights into the solvation chemistry in liquid electrolytes for lithium-based rechargeable batteries Chem. Soc. Rev. (https://doi.org/10.1039/D3CS00151B)
|
[4] |
Blanc L E, Kundu D and Nazar L F 2020 Scientific challenges for the implementation of Zn-ion batteries Joule 4 771–99
|
[5] |
Liu S, Zhang R, Mao J, Zhao Y, Cai Q and Guo Z 2022 From room temperature to harsh temperature applications: fundamentals and perspectives on electrolytes in zinc metal batteries Sci. Adv. 8 eabn5097
|
[6] |
Zhong X et al 2023 Flexible zinc-air batteries with ampere-hour capacities and wide-temperature adaptabilities Adv. Mater. 35 2209980
|
[7] |
Huang Q, Zhong X, Zhang Q, Wu X, Jiao M, Chen B, Sheng J and Zhou G 2022 Co3O4/Mn3O4 hybrid catalysts with heterointerfaces as bifunctional catalysts for Zn-air batteries J. Energy Chem. 68 679–87
|
[8] |
Zhou L, Wang F, Yang F, Liu X, Yu Y, Zheng D and Lu X 2022 Unshared pair electrons of zincophilic lewis base enable long-life Zn anodes under “three high” conditions Angew. Chem., Int. Ed. 61 202208051
|
[9] |
Jiao M, Zhang Q, Ye C, Zhong X, Wang J, Li C, Dai L, Zhou G and Cheng H M 2022 Recycling spent LiNi1-x-yMnxCoyO2 cathodes to bifunctional NiMnCo catalysts for zinc-air batteries Proc. Natl Acad. Sci. USA 119 e2202202119
|
[10] |
Yun X, Chen Y, Xiao P and Zheng C 2022 Review on oxygen-free vanadium-based cathodes for aqueous zinc-ion batteries J. Electrochem. 28 2219004
|
[11] |
Qiu H, Du X, Zhao J, Wang Y, Ju J, Chen Z, Hu Z, Yan D, Zhou X and Cui G 2019 Zinc anode-compatible in-situ solid electrolyte interphase via cation solvation modulation Nat. Commun. 10 5374
|
[12] |
Zhong C et al 2020 Decoupling electrolytes towards stable and high-energy rechargeable aqueous zinc–manganese dioxide batteries Nat. Energy 5 440–9
|
[13] |
Xiao P, Luo R, Piao Z, Li C, Wang J, Yu K, Zhou G and Cheng H-M 2021 High-performance lithium metal batteries with a wide operating temperature range in carbonate electrolyte by manipulating interfacial chemistry ACS Energy Lett. 6 3170–9
|
[14] |
Chen Y et al 2022 Engineering an insoluble cathode electrolyte interphase enabling high performance NCM811//graphite pouch cell at 60 ◦C Adv. Energy Mater. 12 2201631
|
[15] |
Li Z, Chen Y, Yun X, Gao P, Zheng C and Xiao P 2023 Critical review of fluorinated electrolytes for high-performance lithium metal batteries Adv. Funct. Mater. 2300502
|
[16] |
Lv Y, Xiao Y, Ma L, Zhi C and Chen S 2022 Recent advances in electrolytes for “beyond aqueous” zinc-ion batteries Adv. Mater. 34 2106409
|
[17] |
Li X, Wang X, Ma L and Huang W 2022 Solvation structures in aqueous metal-ion batteries Adv. Energy Mater. 12 2202068
|
[18] |
Wang D, Li Q, Zhao Y, Hong H, Li H, Huang Z, Liang G, Yang Q and Zhi C 2022 Insight on organic molecules in aqueous Zn-ion batteries with an emphasis on the Zn anode regulation Adv. Energy Mater. 12 2102707
|
[19] |
Wu K, Huang J, Yi J, Liu X, Liu Y, Wang Y, Zhang J and Xia Y 2020 Recent advances in polymer electrolytes for zinc ion batteries: mechanisms, properties, and perspectives Adv. Energy Mater. 10 1903977
|
[20] |
Cao J, Zhang D, Zhang X, Zeng Z, Qin J and Huang Y 2022 Strategies of regulating Zn2+ solvation structures for dendrite-free and side reaction-suppressed zinc-ion batteries Energy Environ. Sci. 15 499–528
|
[21] |
Zhang L, Rodríguez-Pérez I A, Jiang H, Zhang C, Leonard D P, Guo Q, Wang W, Han S, Wang L and Ji X 2019 ZnCl2 “water-in-salt” electrolyte transforms the performance of vanadium oxide as a Zn battery cathode Adv. Funct. Mater. 29 1902653
|
[22] |
Du Y, Li Y, Xu B B, Liu T X, Liu X, Ma F, Gu X and Lai C 2022 Electrolyte salts and additives regulation enables high performance aqueous zinc ion batteries: a mini review Small 18 e2104640
|
[23] |
Zhang N, Cheng F, Liu Y, Zhao Q, Lei K, Chen C, Liu X and Chen J 2016 Cation-deficient spinel ZnMn2O4 cathode in Zn(CF3SO3)2 electrolyte for rechargeable aqueous Zn-ion battery J. Am. Chem. Soc. 138 12894–901
|
[24] |
Peng Z, Wei Q, Tan S, He P, Luo W, An Q and Mai L 2018 Novel layered iron vanadate cathode for high-capacity aqueous rechargeable zinc batteries Chem. Commun. 54 4041–4
|
[25] |
Wang L, Zhang Y, Hu H, Shi H Y, Song Y, Guo D, Liu X X and Sun X 2019 A Zn(ClO4)2 electrolyte enabling long-life zinc metal electrodes for rechargeable aqueous zinc batteries ACS Appl. Mater. Interfaces 11 42000–5
|
[26] |
Zhu Y, Yin J, Zheng X, Emwas A-H, Lei Y, Mohammed O F, Cui Y and Alshareef H N 2021 Concentrated dual-cation electrolyte strategy for aqueous zinc-ion batteries Energy Environ. Sci. 14 4463–73
|
[27] |
Wang J, Yang Y, Wang Y, Dong S, Cheng L, Li Y, Wang Z, Trabzon L and Wang H 2022 Working aqueous Zn metal batteries at 100 degrees C ACS Nano 16 15770–8
|
[28] |
Qin R et al 2021 Tuning Zn2+ coordination environment to suppress dendrite formation for high-performance Zn-ion batteries Nano Energy 80 105478
|
[29] |
Yan M, Dong N, Zhao X, Sun Y and Pan H 2021 Tailoring the stability and kinetics of Zn anodes through trace organic polymer additives in dilute aqueous electrolyte ACS Energy Lett. 6 3236–43
|
[30] |
Geng L et al 2022 Eutectic electrolyte with unique solvation structure for high-performance zinc-ion batteries Angew. Chem., Int. Ed. 61 e202206717
|
[31] |
Tang X, Wang P, Bai M, Wang Z, Wang H, Zhang M and Ma Y 2021 Unveiling the reversibility and stability origin of the aqueous V2 O5 -Zn batteries with a ZnCl2 “water-in-salt” electrolyte Adv. Sci. 8 e2102053
|
[32] |
Wang F, Borodin O, Gao T, Fan X, Sun W, Han F, Faraone A, Dura J A, Xu K and Wang C 2018 Highly reversible zinc metal anode for aqueous batteries Nat. Mater. 17 543–9
|
[33] |
Wan F, Zhang Y, Zhang L, Liu D, Wang C, Song L, Niu Z and Chen J 2019 Reversible oxygen redox chemistry in aqueous zinc-ion batteries Angew. Chem., Int. Ed. 58 7062–7
|
[34] |
Li C, Yuan W, Li C, Wang H, Wang L, Liu Y and Zhang N 2021 Boosting Li3V2(PO4)3 cathode stability using a concentrated aqueous electrolyte for high-voltage zinc batteries Chem. Commun. 57 4319–22
|
[35] |
Zhao J, Zhang J, Yang W, Chen B, Zhao Z, Qiu H, Dong S, Zhou X, Cui G and Chen L 2019 “Water-in-deep eutectic solvent” electrolytes enable zinc metal anodes for rechargeable aqueous batteries Nano Energy 57 625–34
|
[36] |
Lin X, Zhou G, Robson M J, Yu J, Kwok S C T and Ciucci F 2021 Hydrated deep eutectic electrolytes for high-performance Zn-ion batteries capable of low-temperature operation Adv. Funct. Mater. 32 2109322
|
[37] |
Yang M, Zhu J, Bi S, Wang R and Niu Z 2022 A binary hydrate-melt electrolyte with acetate-oriented cross-linking solvation shells for stable zinc anodes Adv. Mater. 34 e2201744
|
[38] |
Ma L et al 2021 Functionalized phosphonium cations enable zinc metal reversibility in aqueous electrolytes Angew. Chem., Int. Ed. 60 12438–45
|
[39] |
Yang H, Chang Z, Qiao Y, Deng H, Mu X, He P and Zhou H 2020 Constructing a super-saturated electrolyte front surface for stable rechargeable aqueous zinc batteries Angew. Chem., Int. Ed. 59 9377–81
|
[40] |
Yang H, Qiao Y, Chang Z, Deng H, Zhu X, Zhu R, Xiong Z, He P and Zhou H 2021 Reducing water activity by zeolite molecular sieve membrane for long-life rechargeable zinc battery Adv. Mater. 33 e2102415
|
[41] |
Zhang Q, Ma Y, Lu Y, Li L, Wan F, Zhang K and Chen J 2020 Modulating electrolyte structure for ultralow temperature aqueous zinc batteries Nat. Commun. 11 4463
|
[42] |
Sun T, Yuan X, Wang K, Zheng S, Shi J, Zhang Q, Cai W, Liang J and Tao Z 2021 An ultralow-temperature aqueous zinc-ion battery J. Mater. Chem. A 9 7042–7
|
[43] |
Wang R, Yao M, Yang M, Zhu J, Chen J and Niu Z 2023 Synergetic modulation on ionic association and solvation structure by electron-withdrawing effect for aqueous zinc-ion batteries Proc. Natl Acad. Sci. USA 120 e2221980120
|
[44] |
Kundu D, Hosseini Vajargah S, Wan L, Adams B, Prendergast D and Nazar L F 2018 Aqueous vs. nonaqueous Zn-ion batteries: consequences of the desolvation penalty at the interface Energy Environ. Sci. 11 881–92
|
[45] |
Segler M H S, Preuss M and Waller M P 2018 Planning chemical syntheses with deep neural networks and symbolic AI Nature 555 604–10
|
[46] |
Yang W et al 2020 Hydrated eutectic electrolytes with ligand-oriented solvation shells for long-cycling zinc-organic batteries Joule 4 1557–74
|
[47] |
Han D et al 2021 A non-flammable hydrous organic electrolyte for sustainable zinc batteries Nat. Sustain. 5 205–13
|
[48] |
Ming F, Zhu Y, Huang G, Emwas A H, Liang H, Cui Y and Alshareef H N 2022 Co-solvent electrolyte engineering for stable anode-free zinc metal batteries J. Am. Chem. Soc. 144 7160–70
|
[49] |
Liu S, Mao J, Pang W K, Vongsvivut J, Zeng X, Thomsen L, Wang Y, Liu J, Li D and Guo Z 2021 Tuning the electrolyte solvation structure to suppress cathode dissolution, water reactivity, and Zn dendrite growth in zinc-ion batteries Adv. Funct. Mater. 31 2104281
|
[50] |
Miao L et al 2022 Aqueous electrolytes with hydrophobic organic cosolvents for stabilizing zinc metal anodes ACS Nano 16 9667–78
|
[51] |
Liu D S et al 2022 Regulating the electrolyte solvation structure enables ultralong lifespan vanadium-based cathodes with excellent low-temperature performance Adv. Funct. Mater. 32 2111714
|
[52] |
Qiu B, Xie L, Zhang G, Cheng K, Lin Z, Liu W, He C, Zhang P and Mi H 2022 Toward reversible wide-temperature Zn storage by regulating the electrolyte solvation structure via trimethyl phosphate Chem. Eng. J. 449 137843
|
[53] |
Dong Y, Miao L, Ma G, Di S, Wang Y, Wang L, Xu J and Zhang N 2021 Non-concentrated aqueous electrolytes with organic solvent additives for stable zinc batteries Chem. Sci. 12 5843–52
|
[54] |
Ma G, Miao L, Dong Y, Yuan W, Nie X, Di S, Wang Y, Wang L and Zhang N 2022 Reshaping the electrolyte structure and interface chemistry for stable aqueous zinc batteries Energy Storage Mater. 47 203–10
|
[55] |
Hao J, Yuan L, Ye C, Chao D, Davey K, Guo Z and Qiao S Z 2021 Boosting zinc electrode reversibility in aqueous electrolytes by using low-cost antisolvents Angew. Chem., Int. Ed. 60 7366–75
|
[56] |
Cao L, Li D, Hu E, Xu J, Deng T, Ma L, Wang Y, Yang X Q and Wang C 2020 Solvation structure design for aqueous Zn metal batteries J. Am. Chem. Soc. 142 21404–9
|
[57] |
Li T C, Lim Y, Li X L, Luo S, Lin C, Fang D, Xia S, Wang Y and Yang H Y 2022 A universal additive strategy to reshape electrolyte solvation structure toward reversible Zn storage Adv. Energy Mater. 12 2103231
|
[58] |
Du H, Wang K, Sun T, Shi J, Zhou X, Cai W and Tao Z 2022 Improving zinc anode reversibility by hydrogen bond in hybrid aqueous electrolyte Chem. Eng. J. 427 131705
|
[59] |
Li C, Kingsbury R, Zhou L, Shyamsunder A, Persson K A and Nazar L F 2022 Tuning the solvation structure in aqueous zinc batteries to maximize Zn-ion intercalation and optimize dendrite-free zinc plating ACS Energy Lett. 7 533–40
|
[60] |
Wu Y, Zhu Z, Shen D, Chen L, Song T, Kang T, Tong Z, Tang Y, Wang H and Lee C S 2022 Electrolyte engineering enables stable Zn-Ion deposition for long-cycling life aqueous Zn-ion batteries Energy Storage Mater. 45 1084–91
|
[61] |
Sun Y et al 2022 Low-cost and long-life Zn/Prussian blue battery using a water-in-ethanol electrolyte with a normal salt concentration Energy Storage Mater. 48 192–204
|
[62] |
Zhang Y, Zhu M, Wu K, Yu F, Wang G, Xu G, Wu M, Liu H-K, Dou S-X and Wu C 2021 An in-depth insight of a highly reversible and dendrite-free Zn metal anode in an hybrid electrolyte J. Mater. Chem. A 9 4253–61
|
[63] |
Chang N, Li T, Li R, Wang S, Yin Y, Zhang H and Li X 2020 An aqueous hybrid electrolyte for low-temperature zinc-based energy storage devices Energy Environ. Sci. 13 3527–35
|
[64] |
Yang J et al 2022 Three birds with one stone: tetramethylurea as electrolyte additive for highly reversible Zn-metal anode Adv. Funct. Mater. 32 2209642
|
[65] |
Li Z, Liao Y, Wang Y, Cong J, Ji H, Huang Z and Huang Y 2023 A co-solvent in aqueous electrolyte towards ultralong-life rechargeable zinc-ion batteries Energy Storage Mater. 56 174–82
|
[66] |
Deng W, Xu Z and Wang X 2022 High-donor electrolyte additive enabling stable aqueous zinc-ion batteries Energy Storage Mater. 52 52–60
|
[67] |
Wu F, Chen Y, Chen Y, Yin R, Feng Y, Zheng D, Xu X, Shi W, Liu W and Cao X 2022 Achieving highly reversible zinc anodes via N, N-dimethylacetamide enabled Zn-ion solvation regulation Small 18 e2202363
|
[68] |
Ma L et al 2018 Initiating a mild aqueous electrolyte Co3O4/Zn battery with 2.2 V-high voltage and 5000-cycle lifespan by a Co(iii) rich-electrode Energy Environ. Sci. 11 2521–30
|
[69] |
Pan H et al 2016 Reversible aqueous zinc/manganese oxide energy storage from conversion reactions Nat. Energy 1 16039
|
[70] |
Feng R, Chi X, Qiu Q, Wu J, Huang J, Liu J and Liu Y 2021 Cyclic ether-water hybrid electrolyte-guided dendrite-free lamellar zinc deposition by tuning the solvation structure for high-performance aqueous zinc-ion batteries ACS Appl. Mater. Interfaces 13 40638–47
|
[71] |
Zhao K, Liu F, Fan G, Liu J, Yu M, Yan Z, Zhang N and Cheng F 2021 Stabilizing zinc electrodes with a vanillin additive in mild aqueous electrolytes ACS Appl. Mater. Interfaces 13 47650–8
|
[72] |
Feng X, Li P, Yin J, Gan Z, Gao Y, Li M, Cheng Y, Xu X, Su Y and Ding S 2023 Enabling highly reversible Zn anode by multifunctional synergistic effects of hybrid solute additives ACS Energy Lett. 8 1192–200
|
[73] |
Meng R, Li H, Lu Z, Zhang C, Wang Z, Liu Y, Wang W, Ling G, Kang F and Yang Q H 2022 Tuning Zn-ion solvation chemistry with chelating ligands toward stable aqueous Zn anodes Adv. Mater. 34 e2200677
|
[74] |
Zhang H, Zhong Y, Li J, Liao Y, Zeng J, Shen Y, Yuan L, Li Z and Huang Y 2022 Inducing the preferential growth of Zn (002) plane for long cycle aqueous Zn-ion batteries Adv. Energy Mater. 13 2203254
|
[75] |
Qin H, Kuang W, Hu N, Zhong X, Huang D, Shen F, Wei Z, Huang Y, Xu J and He H 2022 Building metal-molecule interface towards stable and reversible Zn metal anodes for aqueous rechargeable zinc batteries Adv. Funct. Mater. 32 2206695
|
[76] |
Luo J et al 2023 Regulating the inner helmholtz plane with a high donor additive for efficient anode reversibility in aqueous Zn-ion batteries Angew. Chem., Int. Ed. 62 e202302302
|
[77] |
Sun P, Ma L, Zhou W, Qiu M, Wang Z, Chao D and Mai W 2021 Simultaneous regulation on solvation shell and electrode interface for dendrite-free Zn ion batteries achieved by a low-cost glucose additive Angew. Chem., Int. Ed. 60 18247–55
|
[78] |
Xie D, Sang Y, Wang D H, Diao W Y, Tao F Y, Liu C, Wang J W, Sun H Z, Zhang J P and Wu X L 2023 ZnF2 -riched inorganic/organic hybrid SEI: in situ-chemical construction and performance-improving mechanism for aqueous zinc-ion batteries Angew. Chem., Int. Ed. 62 e202216934
|
[79] |
Wei T, Zhang X, Ren Y, Wang Y, Li Z, Zhang H and Hu L 2023 Reconstructing anode/electrolyte interface and solvation structure towards high stable zinc anode Chem. Eng. J. 457 141272
|
[80] |
Xin T, Zhou R, Xu Q, Yuan X, Zheng Z, Li Y, Zhang Q and Liu J 2023 15-Crown-5 ether as efficient electrolyte additive for performance enhancement of aqueous Zn-ion batteries Chem. Eng. J. 452 139572
|
[81] |
Chen Y, Gong F, Deng W, Zhang H and Wang X 2023 Dual-function electrolyte additive enabling simultaneous electrode interface and coordination environment regulation for zinc-ion batteries Energy Storage Mater. 58 20–29
|
[82] |
Hu Q, Hu J, Li L, Ran Q, Ji Y, Liu X, Zhao J and Xu B 2023 In-depth study on the regulation of electrode interface and solvation structure by hydroxyl chemistry Energy Storage Mater. 54 374–81
|
[83] |
Li R, Li M, Chao Y, Guo J, Xu G, Li B, Liu Z and Yang C 2022 Hexaoxacyclooctadecane induced interfacial engineering to achieve dendrite-free Zn ion batteries Energy Storage Mater. 46 605–12
|
[84] |
Yin J et al 2023 Integrated electrolyte regulation strategy: trace trifunctional tranexamic acid additive for highly reversible Zn metal anode and stable aqueous zinc ion battery Energy Storage Mater. 59 102800
|
[85] |
Wu X et al 2015 The electrochemical performance improvement of LiMn2O4/Zn based on zinc foil as the current collector and thiourea as an electrolyte additive J. Power Sources 300 453–9
|
[86] |
Cui J, Liu X, Xie Y, Wu K, Wang Y, Liu Y, Zhang J, Yi J and Xia Y 2020 Improved electrochemical reversibility of Zn plating/stripping: a promising approach to suppress water-induced issues through the formation of H-bonding Mater. Today Energy 18 100563
|
[87] |
Miao Z et al 2022 Unveiling unique steric effect of threonine additive for highly reversible Zn anode Nano Energy 97 107145
|
[88] |
Xu W, Zhao K, Huo W, Wang Y, Yao G, Gu X, Cheng H, Mai L, Hu C and Wang X 2019 Diethyl ether as self-healing electrolyte additive enabled long-life rechargeable aqueous zinc ion batteries Nano Energy 62 275–81
|
[89] |
Wang M, Cheng Y, Zhao H, Gao J, Li J, Wang Y, Qiu J, Zhang H, Chen X and Wei Y 2023 A multifunctional organic electrolyte additive for aqueous zinc ion batteries based on polyaniline cathode Small 19 2302105
|
[90] |
Shi X, Wang J, Yang F, Liu X, Yu Y and Lu X 2022 Metallic zinc anode working at 50 and 50 mAh cm−2 with high depth of discharge via electrical double layer reconstruction Adv. Funct. Mater. 33 2211917
|
[91] |
Jin Y, Han K S, Shao Y, Sushko M L, Xiao J, Pan H and Liu J 2020 Stabilizing zinc anode reactions by polyethylene oxide polymer in mild aqueous electrolytes Adv. Funct. Mater. 30 2003932
|
[92] |
Yan M, Xu C, Sun Y, Pan H and Li H 2021 Manipulating Zn anode reactions through salt anion involving hydrogen bonding network in aqueous electrolytes with PEO additive Nano Energy 82 105739
|
[93] |
Xu J et al 2022 In situ construction of protective films on Zn metal anodes via natural protein additives enabling high-performance zinc ion batteries ACS Nano 16 11392–404
|
[94] |
Wang B, Zheng R, Yang W, Han X, Hou C, Zhang Q, Li Y, Li K and Wang H 2022 Synergistic solvation and interface regulations of eco-friendly silk peptide additive enabling stable aqueous zinc-ion batteries Adv. Funct. Mater. 32 2112693
|
[95] |
Bayaguud A, Luo X, Fu Y and Zhu C 2020 Cationic surfactant-type electrolyte additive enables three-dimensional dendrite-free zinc anode for stable zinc-ion batteries ACS Energy Lett. 5 3012–20
|
[96] |
Wan J et al 2023 A double-functional additive containing nucleophilic groups for high-performance Zn-ion batteries ACS Nano 17 1610–21
|
[97] |
Zeng X et al 2021 Electrolyte design for in situ construction of highly Zn2+ -conductive solid electrolyte interphase to enable high-performance aqueous Zn-ion batteries under practical conditions Adv. Mater. 33 e2007416
|
[98] |
Wang P, Xie X, Xing Z, Chen X, Fang G, Lu B, Zhou J, Liang S and Fan H J 2021 Mechanistic insights of Mg2+ -electrolyte additive for high-energy and long-life zinc-ion hybrid capacitors Adv. Energy Mater. 11 2101158
|
[99] |
Cao L et al 2021 Highly reversible aqueous zinc batteries enabled by zincophilic-zincophobic interfacial layers and interrupted hydrogen-bond electrolytes Angew. Chem., Int. Ed. 60 18845–51
|
[100] |
Kim M, Shin S J, Lee J, Park Y, Kim Y, Kim H and Choi J W 2022 Cationic additive with a rigid solvation shell for high-performance zinc ion batteries Angew. Chem., Int. Ed. 61 e202211589
|
[101] |
Lv Y, Zhao M, Du Y, Kang Y, Xiao Y and Chen S 2022 Engineering a self-adaptive electric double layer on both electrodes for high-performance zinc metal batteries Energy Environ. Sci. 15 4748–60
|
[102] |
Hao R et al 2023 Reconstructing the solvation structure and solid-liquid interface enables dendrite-free zinc-ion batteries Mater. Today Energy 33 101279
|
[103] |
Chen S et al 2019 Critical parameters for evaluating coin cells and pouch cells of rechargeable li-metal batteries Joule 3 1094–105
|
[104] |
Cao Y, Li M, Lu J, Liu J and Amine K 2019 Bridging the academic and industrial metrics for next-generation practical batteries Nat. Nanotechnol. 14 200–7
|
[105] |
Niu C, Lee H, Chen S, Li Q, Du J, Xu W, Zhang J-G, Whittingham M S, Xiao J and Liu J 2019 High-energy lithium metal pouch cells with limited anode swelling and long stable cycles Nat. Energy 4 551–9
|
[106] |
Jain R, Lakhnot A S, Bhimani K, Sharma S, Mahajani V, Panchal R A, Kamble M, Han F, Wang C and Koratkar N 2022 Nanostructuring versus microstructuring in battery electrodes Nat. Rev. Mater. 7 736–46
|
[107] |
Xiao P, Bu F, Zhao R, Aly Aboud M F, Shakir I and Xu Y 2018 Sub-5 nm ultrasmall metal-organic framework nanocrystals for highly efficient electrochemical energy storage ACS Nano 12 3947–53
|
[108] |
Xiao P, Li S, Yu C, Wang Y and Xu Y 2020 Interface engineering between the metal-organic framework nanocrystal and graphene toward ultrahigh potassium-ion storage performance ACS Nano 14 10210–8
|
[109] |
Piao Z, Xiao P, Luo R, Ma J, Gao R, Li C, Tan J, Yu K, Zhou G and Cheng H M 2022 Constructing a stable interface layer by tailoring solvation chemistry in carbonate electrolytes for high-performance lithium-metal batteries Adv. Mater. 34 e2108400
|
[110] |
Xiao P, Bu F, Yang G, Zhang Y and Xu Y 2017 Integration of graphene, nano sulfur, and conducting polymer into compact, flexible lithium-sulfur battery cathodes with ultrahigh volumetric capacity and superior cycling stability for foldable devices Adv. Mater. 29 1703324
|
[111] |
Xiao P, Zhao Y, Piao Z, Li B, Zhou G and Cheng H-M 2022 A nonflammable electrolyte for ultrahigh-voltage (4.8 V-class) Li||NCM811 cells with a wide temperature range of 100 ◦C Energy Environ. Sci. 15 2435–44
|
[112] |
Xiao P and Xu Y 2018 Recent progress in two-dimensional polymers for energy storage and conversion: design, synthesis, and applications J. Mater. Chem. A 6 21676–95
|
[113] |
Wu Y and Liu N 2018 Visualizing battery reactions and processes by using in situ and in operando microscopies Chem 4 438–65
|
[114] |
Ji Y et al 2021 From bulk to interface: electrochemical phenomena and mechanism studies in batteries via electrochemical quartz crystal microbalance Chem. Soc. Rev. 50 10743–63
|
[115] |
Tripathi A M, Su W N and Hwang B J 2018 In situ analytical techniques for battery interface analysis Chem. Soc. Rev. 47 736–851
|
[116] |
Zhang L, Qian T, Zhu X, Hu Z, Wang M, Zhang L, Jiang T, Tian J H and Yan C 2019 In situ optical spectroscopy characterization for optimal design of lithium-sulfur batteries Chem. Soc. Rev. 48 5432–53
|
[117] |
Yang H, Tang P, Piao N, Li J, Shan X, Tai K, Tan J, Cheng H-M and Li F 2022 In-situ imaging techniques for advanced battery development Mater. Today 57 279–94
|
[118] |
Yousaf M et al 2022 Visualization of battery materials and their interfaces/interphases using cryogenic electron microscopy Mater. Today 58 238–74
|
[119] |
Wang Y, Liu Y, Song S, Yang Z, Qi X, Wang K, Liu Y, Zhang Q and Tian Y 2018 Accelerating the discovery of insensitive high-energy-density materials by a materials genome approach Nat. Commun. 9 2444
|
[120] |
Liu Y, Guo B, Zou X, Li Y and Shi S 2020 Machine learning assisted materials design and discovery for rechargeable batteries Energy Storage Mater. 31 434–50
|
[121] |
Burger B et al 2020 A mobile robotic chemist Nature 583 237–41
|
[122] |
Deringer V L, Bernstein N, Csanyi G, Ben Mahmoud C, Ceriotti M, Wilson M, Drabold D A and Elliott S R 2021 Origins of structural and electronic transitions in disordered silicon Nature 589 59–64
|
[123] |
Raccuglia P, Elbert K C, Adler P D, Falk C, Wenny M B, Mollo A, Zeller M, Friedler S A, Schrier J and Norquist A J 2016 Machine-learning-assisted materials discovery using failed experiments Nature 533 73–76
|
[124] |
Correa-Baena J-P, Hippalgaonkar K, van Duren J, Jaffer S, Chandrasekhar V R, Stevanovic V, Wadia C, Guha S and Buonassisi T 2018 Accelerating materials development via automation, machine learning, and high-performance computing Joule 2 1410–20
|
[125] |
Nolan A M, Zhu Y, He X, Bai Q and Mo Y 2018 Computation-accelerated design of materials and interfaces for all-solid-state lithium-ion batteries Joule 2 2016–46
|
[126] |
Xiao Y, Miara L J, Wang Y and Ceder G 2019 Computational screening of cathode coatings for solid-state batteries Joule 3 1252–75
|
[127] |
Butler K T, Davies D W, Cartwright H, Isayev O and Walsh A 2018 Machine learning for molecular and materials science Nature 559 547–55
|