[1] N CHEN L, Y YAN M, W MEI Z et al. Research progress and prospect of aqueous zinc ion battery. Journal of Inorganic Materials, 32, 225-234(2017).
[2] J WEI X, B LI Y, Y GAO S. Biomass-derived interconnected carbon nanoring electrochemical capacitors with high performance in both strongly acidic and alkaline electrolytes. Journal of Materials Chemistry A, 5, 181-188(2017).
[3] J WEI X, L ZOU H, Y GAO S. Chemical crosslinking engineered nitrogen-doped carbon aerogels from polyaniline-boric acid- polyvinyl alcohol gels for high-performance electrochemical capacitors. Carbon, 123, 471-480(2017).
[4] J WEI X, S WEI J, B LI Y et al. Robust hierarchically interconnected porous carbons derived from discarded Rhus typhina fruits for ultrahigh capacitive performance supercapacitors. Journal of Power Sources, 414, 13-23(2019).
[5] Q MA G, M JIANG Z, C CHEN H et al. Research process on novel electrolyte of lithium-ion battery based on lithium salts. Journal of Inorganic Materials, 33, 699-710(2018).
[6] Y TAN, B XUE. Research progress on lithium titanate as anode material in lithium-ion battery. Journal of Inorganic Materials, 33, 475-482(2018).
[7] Y OUYANG, P GUO Y, D LI et al. Single additive with dual functional- ions for stabilizing lithium anodes. ACS Applied Materials & Interfaces, 11, 11360-11368(2019).
[8] P LIU J, C GUAN, C ZHOU et al. A flexible quasi-solid-state nickel-zinc battery with high energy and power densities based on 3D electrode design. Advanced Materials, 28, 8732-8739(2016).
[9] H HUANG J, H YANG Z, B YANG et al. Ultrasound assisted polymerization for synthesis of ZnO/polypyrrole composites for zinc/nickel rechargeable battery. Journal of Power Sources, 271, 143-151(2014).
[10] J WEN R, H YANG Z, M FAN X et al. Electrochemical performances of ZnO with different morphology as anodic materials for Ni/Zn secondary batteries. Electrochimica Acta, 83, 376-382(2012).
[11] J LI, H ZHAO T, B SHANGGUAN E et al. Enhancing the rate and cycling performance of spherical ZnO anode material for advanced zinc-nickel secondary batteries by combined
[12] J ZHAO Z, K YANG, K PENG et al. Synergistic effect of ZnO@Bi/C sphere for rechargeable Zn-Ni battery with high specific capacity. Journal of Power Sources, 410, 10-14(2019).
[13] H YANG, H YANG Z, X WEN et al. The
[14] B LAI S, I JAMESH M, C WU X et al. A promising energy storage system: rechargeable Ni-Zn battery. Rare Metals, 36, 381-396(2017).
[15] S XIE Q, F LIU P, Q ZENG D et al. Dual electrostatic assembly of graphene encapsulated nanosheet-assembled ZnO-Mn-C hollow microspheres as a lithium ion battery anode. Advanced Functional Materials, 28, 1707433(2018).
[16] Y HUANG G, Y YANG, Y SUN H et al. Defective ZnCo2O4 with Zn vacancies: synthesis, property and electrochemical application. Journal of Alloys and Compounds, 724, 1149-1156(2017).
[17] Y SHEN X, B MU D, S CHEN et al. Enhanced electrochemical performance of ZnO-loaded/porous carbon composite as anode materials for lithium ion batteries. ACS Applied Materials & Interfaces, 5, 3118-3125(2013).
[18] J KIM, Y IM, S PARK K et al. Improved cell performances in Ni/Zn redox batteries fabricated by ZnO materials with various morphologies synthesized using amine chelates. Journal of Industrial and Engineering Chemistry, 56, 463-471(2017).
[19] Y WU P, J PIKE, F ZHANG et al. Low-temperature synthesis of zinc oxide nanoparticles. International Journal of Applied Ceramic Technology, 3, 272-278(2006).
[20] H NOEI, S QIU H, M WANG Y et al. The identification of hydroxyl groups on ZnO nanoparticles by infrared spectroscopy. Physical Chemistry Chemical Physics, 10, 7092-7097(2008).
[21] K N’KONOU, M HARIS, Y LARE et al. Effect of barium doping on the physical properties of zinc oxide nanoparticles elaborated
[22] G KIM J, H LEE S, Y KIM et al. Fabrication of free-standing ZnMn2O4 mesoscale tubular arrays for lithium-ion anodes with highly reversible lithium storage properties. ACS Applied Materials & Interfaces, 5, 11321-11328(2013).
[23] P LIU J, Y LI Y, M DING R et al. Carbon/ZnO nanorod array electrode with significantly improved lithium storage capability. Journal of Physical Chemistry C, 113, 5336-5339(2009).
[24] A KAMBLE, B SINHA, K CHUNG et al. Facile linker free growth of CdS nanoshell on 1-D ZnO: solar cell application. Electronic Materials Letters, 11, 171-179(2015).
[25] X ZENG Y, Z LAI Z, Y HAN et al. Oxygen-vacancy and surface modulation of ultrathin nickel cobaltite nanosheets as a high-energy cathode for advanced Zn-ion batteries. Advanced Materials, 30, 1802396(2018).
[26] P NANDI, D DAS. Photocatalytic degradation of rhodamine-B dye by stable ZnO nanostructures with different calcination temperature induced defects. Applied Surface Science, 465, 546-556(2019).
[27] T XIA, P WALLENMEYER, A ANDERSON et al. Hydrogenated black ZnO nanoparticles with enhanced photocatalytic performance. RSC Advances, 4, 41654-41658(2014).
[28] J DENG S, Y ZHANG, D XIE et al. Oxygen vacancy modulated Ti2Nb10O29-
[29] M CARBONE. Zn defective ZnCo2O4 nanorods as high capacity anode for lithium ion batteries. Journal of Electroanalytical Chemistry, 815, 151-157(2018).
[30] Y YAN X, X CHEN Z, Y WANG et al.
[31] S SUN L, Z YI, J LIN et al. Fast and energy efficient synthesis of ZnO@RGO and its application in Ni-Zn secondary battery. Journal of Physical Chemistry C, 120, 12337-12343(2016).
[32] C GUO W, L TIAN Z, C YANG et al. ZIF-8 derived nano-SnO2@ZnO as anode for Zn/Ni secondary batteries. Electrochemistry Communications, 82, 159-162(2017).
[33] H ZHAO T, B SHANGGUAN E, Y LI et al. Facile synthesis of high tap density ZnO microspheres as advanced anode material for alkaline nickel-zinc rechargeable batteries. Electrochimica Acta, 182, 173-182(2015).
[34] H HUANG J, H YANG Z, T WANG T. Evaluation of tetraphenylporphyrin modified ZnO as anode material for Ni-Zn rechargeable battery. Electrochimica Acta, 123, 278-284(2014).