A Quasi-gel SiO2/Sodium Alginate (SA) Composite Electrolyte for Long-life Zinc-manganese Aqueous Batteries

doi:10.15541/jim20190473

Abstract

Abstract:

Zinc-manganese (Zn/MnO₂) batteries with outstanding advantages of high operation safety, high environmental benignity and high cost performance, is suitable for the application of large-scale energy storage battery. However, the uncontrolled growth of zinc dendrites on the metal zinc anode during charge-discharge cycling causes serious problems such as quick capacity decrease and short circuit failure. In this study, the aqueous electrolyte was converted into a composite quasi-gel electrolyte by adding hydrophilic nano-silica (SiO₂) and sodium alginate (SA), which effectively inhibits the dendrite growth of the surface of the zinc negative electrode and the capacity degradation of the Zn-MnO₂ battery. Galvanostatic charge-discharge tests showed that the Zn/MnO₂ battery with composite gel electrolyte achieves a capacity retention of 78% after 1800 cycles, while the capacity of Zn/MnO₂ battery using ordinary electrolyte almost fails after 1000 cycles. The three-dimensional network structure of the gel electrolyte can improve the distribution uniformity of zinc ion in electrolyte, reduce the capacity decay rate and failure risk of the batteries.

Key words: zinc-manganese battery, zinc dendrite, quasi-gel electrolyte, sodium alginate, silica

CLC Number:

TM911

LI Xueyuan,WANG Honggang,TIAN Zhu,ZHU Jianhui,LIU Ying,JIA Lan,YOU Dongjiang,LI Xiangming,KANG Litao. A Quasi-gel SiO₂/Sodium Alginate (SA) Composite Electrolyte for Long-life Zinc-manganese Aqueous Batteries[J]. Journal of Inorganic Materials, 2020, 35(8): 909-915.

Figures/Tables 14

Fig. 1 Optical photographs of different electrolytes (a-c) and SEM images of freeze-dried additives from their aqueous dispersions (d-f)

Fig. 2 FT-IR spectra (a) and TGA curves (b) of different electrolytes

Fig. 3 Galvanostatic charge/discharge curves of Zn-Zn symmetric cells in different electrolytes (a-b), and SEM images of Zn electrodes after 50 cycles at 1 mA?cm-2 (c-f)

Fig. 4 CV (a) and galvanostatic charge/discharge curves (b) of Zn-MnO2 batteries with different electrolytes

Fig. 5 Cycling performance of Zn-MnO2 batteries using different electrolytes at 0.5 (a) and 1 A?g-1 (b); Cross sectional SEM images of zinc electrodes after 100 cycles at 1 A?g-1 (c-f)

Fig. 6 Rate performance of Zn-MnO2 batteries with different electrolytes

Fig. 7 EIS plots of Zn-MnO2 battery with different electrolytes (a) and XRD patterns of Zn anode after 100 cycles (b)

Fig. 8 Schematic illustration showing the Zn dendrite depressing mechanism of the SA/SiO2 quasi-gel electrolyte

Fig. S1 Optical image of sodium alginate powder pressed between two pieces of nickel foams before and after cyclic voltammetry test

Fig. S2 Cyclic voltammetry curves of SiO2 and SA electrodes

Fig. S3 SEM images of zinc electrodes for Zn-MnO2 batteries after 100 charge/discharge cycles in different electrolytes

Fig. S4 Capacity evolution of Zn-MnO2 batteries with a filter paper or glass fiber separator

Fig. S5 Charge and discharge curves of Zn-MnO2 batteries with different electrolytes

Fig. S6 Overpotential measurement of electrodeposited zinc in different electrolytes

References 40

[1]	PANG Q, SUN C, YUY, et al. H₂V₃O₈ nanowire/graphene electrodes for aqueous rechargeable zinc ion batteries with high rate capability and large capacity. Advanced Energy Materials, 2018,8(19):1800144. DOI URL
[2]	HILDER M, WINTHER-JENSEN B, CLARK N B. The effect of binder and electrolyte on the performance of thin zinc-air battery. Electrochimica Acta, 2012,69(3):8-14.
[3]	DAI X, WAN F, ZHANG L, et al. Freestanding graphene/VO₂ composite films for highly stable aqueous Zn-ion batteries with superior rate performance. Energy Storage Materials, 2019,17(1):43-50.
[4]	ZHANG X, WU S, DENG S, et al. 3D CNTs networks enable MnO₂ cathodes with high capacity and superior rate capability for flexible rechargeable Zn-MnO₂ batteries. Small Methods, 2019,3(12):1900525. DOI URL
[5]	ZHANG H, LIU Q, FANG Y, et al. Boosting Zn-ion energy storage capability of hierarchically porous carbon by promoting chemical adsorption. Advanced Materials, 2019,31(44):1904948. DOI URL
[6]	GALLAWAY J W, DESAI D, GAIKWAD A, et al. A lateral microfluidic cell for imaging electrodeposited zinc near the shorting condition. Journal of The Electrochemical Society, 2010,157(12):A1279-A1286. DOI URL
[7]	CHENG X B, HOU T Z, ZHANG R, et al. Dendrite-free lithium deposition induced by uniformly distributed lithium ions for efficient lithium metal batteries. Advanced Materials, 2016,28(15):2888-2895. DOI URL PMID
[8]	HIGASHI S, LEE S W, LEE J S, et al. Avoiding short circuits from zinc metal dendrites in anode by backside-plating configuration. Nature Communications, 2016,7:11801. DOI URL PMID
[9]	PARKER J F, CHERVIN C N, PALA I R, et al. Rechargeable nickel-3D zinc batteries: an energy-dense, safer alternative to lithium- ion. Science, 2017,356(6336):415. DOI URL PMID
[10]	ZENG Y, ZHANG X, QIN R, et al. Dendrite-free zinc deposition induced by multifunctional CNT frameworks for stable flexible Zn-ion batteries. Advanced Materials, 2019,31(36):1903675. DOI URL
[11]	WOOD K N, KAZYAK E, CHADWICK A F, et al. Dendrites and pits: untangling the complex behavior of lithium metal anodes through operando video microscopy. ACS Central Science, 2016,2(11):790-801. DOI URL PMID
[12]	SLATER M D, KIM D, LEE E, et al. Sodium-ion batteries. Advanced Functional Materials, 2013,23(8):947-58. DOI URL
[13]	XUE L, GAO H, ZHOU W, et al. Liquid K-Na alloy anode enables dendrite-free potassium batteries. Advanced Materials, 2016,28(43):9608-9612. DOI URL PMID
[14]	KANG L, CUI M, JIANG F, et al. Nanoporous CaCO₃ coatings enabled uniform Zn stripping/plating for long-life zinc rechargeable aqueous batteries. Advanced Energy Materials, 2018,8(25):1801090. DOI URL
[15]	CHEN N, DAI Y, XING Y, et al. Biomimetic ant-nest ionogel electrolyte boosts the performance of dendrite-free lithium batteries. Energy & Environmental Science, 2017,10(7):1660-1667.
[16]	ZHANG R, CHEN X R, CHEN X, et al. Lithiophilic sites in doped graphene guide uniform lithium nucleation for dendrite-free lithium metal anodes. Angewandte Chemie International Edition, 2017,56(27):7764-7768. DOI URL PMID
[17]	CUI M, XIAO Y, KANG L, et al. Quasi-isolated Au particles as heterogeneous seeds to guide uniform Zn deposition for aqueous zinc-ion batteries. ACS Applied Energy Materials, 2019,2(9):6490-6496. DOI URL
[18]	DING F, XU W, GRAFF G L, et al. Dendrite-free lithium deposition via self-healing electrostatic shield mechanism. Journal of the American Chemical Society, 2013,135(11):4450-4456. DOI URL PMID
[19]	WANG F, BORODIN O, GAO T, et al. Highly reversible zinc metal anode for aqueous batteries. Nature Materials, 2018,17(6):543-549. DOI URL PMID
[20]	XU W, ZHAO K, HUO W, et al. Diethyl ether as self-healing electrolyte additive enabled long-life rechargeable aqueous zinc ion batteries. Nano Energy, 2019,62:275-281. DOI URL
[21]	HUANG J, CHI X, HAN Q, et al. Thickening and homogenizing aqueous electrolyte towards highly efficient and stable Zn metal batteries. Journal of The Electrochemical Society, 2019,166(6):A1211-A1216. DOI URL
[22]	MARTHA S K, HARIPRAKASH B, GAFFOOR S A, et al. Performance characteristics of a gelled-electrolyte valve-regulated lead- acid battery. Bulletin of Materials Science, 2003,26(5):465-469. DOI URL
[23]	HOU X, XUE Z, XIA Y, et al. Effect of SiO₂ nanoparticle on the physical and chemical properties of eco-friendly agar/sodium alginate nanocomposite film. International Journal of Biological Macromolecules, 2019,125:1289-1298. DOI URL PMID
[24]	YADAV M, RHEE K Y, PARK S J. Synthesis and characterization of graphene oxide/carboxymethylcellulose/alginate composite blend films. Carbohydrate Polymers, 2014,110:18-25. DOI URL
[25]	GÓMEZ-ORD EZ E, RUP REZ P. FTIR-ATR spectroscopy as a tool for polysaccharide identification in edible brown and red seaweeds. Food Hydrocolloids, 2011,25(6):1514-1520. DOI URL
[26]	DAEMI H, BARIKANI M. Synthesis and characterization of calcium alginate nanoparticles, sodium homopolymannuronate salt and its calcium nanoparticles. Scientia Iranica, 2012,19(6):2023-2028. DOI URL
[27]	SUN J Y, ZHAO X, ILLEPERUMA W R, et al. Highly stretchable and tough hydrogels. Nature, 2012,489(7414):133-136. DOI URL
[28]	YANG M, XIA Y, WANG Y, et al. Preparation and property investigation of crosslinked alginate/silicon dioxide nanocomposite films. Journal of Applied Polymer Science, 2016,133(22):15-27.
[29]	YAN J, WANG J, LIU H, et al. Rechargeable hybrid aqueous batteries. Journal of Power Sources, 2012,216:222-226. DOI URL
[30]	WEI X, DESAI D, YADAV G G, et al. Impact of anode substrates on electrodeposited zinc over cycling in zinc-anode rechargeable alkaline batteries. Electrochimica Acta, 2016,212:603-613. DOI URL
[31]	WANG Z, HUANG J, GUO Z, et al. A metal-organic framework host for highly reversible dendrite-free zinc metal anodes. Joule, 2019,3(5):1289-1300. DOI URL
[32]	SUN W, WANG F, HOU S, et al. Zn/MnO₂ Battery Chemistry with H + and Zn ²⁺ coinsertion . Journal of the American Chemical Society, 2017,139(29):9775-9778. DOI URL PMID
[33]	HUANG J, WANG Z, HOU M, et al. Polyaniline-intercalated manganese dioxide nanolayers as a high-performance cathode material for an aqueous zinc-ion battery. Nature Communications, 2018,9(1):2906. DOI URL PMID
[34]	HOANG TUAN K A, DOAN. T N L, LU C Y, et al. Performance of thixotropic gel electrolytes in the rechargeable aqueous Zn/ LiMn₂O₄ battery. ACS Sustainable Chemistry & Engineering, 2016,5(2):1804-1811.
[35]	ZHANG N, CHENG F, LIU J, et al. Rechargeable aqueous zinc- manganese dioxide batteries with high energy and power densities. Nature Communications, 2017,8(1):405. DOI URL PMID
[36]	ZENG K, LI X H, WANG Z, et al. Cave-embedded porous Mn₂O₃ hollow microsphere as anode material for lithium ion batteries. Electrochimica Acta, 2017, ( Supplement C):795-802.
[37]	CHEN W C, WEN T C. Electrochemical and capacitive properties of polyaniline-implanted porous carbon electrode for supercapacitors. Journal of Power Sources, 2003,117(1/2):273-282. DOI URL
[38]	SUN K E K, HOANG T K A, DOAN T N L, et al. Highly sustainable zinc anodes for a rechargeable hybrid aqueous battery. Chemistry - A European Journal, 2018,24(7):1667-1673.
[39]	LI N, WEI W, XIE K, et al. Suppressing dendritic lithium formation using porous media in lithium metal-based batteries. Nano Letters, 2018,18(3):2067-2073. DOI URL PMID
[40]	LIU W, LI W, ZHUO D, et al. Core-shell nanoparticle coating as an interfacial layer for dendrite-free lithium metal anodes. ACS Cent. Sci., 2017,3(2):135-140. DOI URL PMID

A Quasi-gel SiO₂/Sodium Alginate (SA) Composite Electrolyte for Long-life Zinc-manganese Aqueous Batteries

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