[1] D. Xia, H. Gao, M. Li, F. Gong, and M. Li, "Transition Metal Vanadates Electrodes in Lithium-ion Batteries: A Holistic Review," Energy Storage Mater, 2020.
[2] W. Ren et al., "Prussian White Hierarchical Nanotubes with Surface‐Controlled Charge Storage for Sodium‐Ion Batteries," Advanced Functional Materials, vol. 29, no. 15, p. 1806405, 2019.
[3] X. Yao et al., "Defect‐rich soft carbon porous nanosheets for fast and high‐capacity sodium‐ion storage," Adv Energy Mater, vol. 9, no. 6, p. 1803260, 2019.
[4] Z.-H. Huang et al., "Zinc–nickel–cobalt ternary hydroxide nanoarrays for high-performance supercapacitors," J Mater Chem A, vol. 7, no. 19, pp. 11826-11835, 2019.
[5] W. T. Wei, S. Z. Cui, L. Y. Ding, L. W. Mi, W. H. Chen, and X. L. Hu, "Urchin-Like Ni1/3Co2/3(CO3)(1/2)(OH)center dot 0.11H(2)O for Ultrahigh-Rate Electrochemical Supercapacitors: Structural Evolution from Solid to Hollow," (in English), Acs Appl Mater Inter, vol. 9, no. 46, pp. 40655-40670, Nov 22 2017.
[6] Z. Li et al., "Reduced CoNi2S4 nanosheets with enhanced conductivity for high-performance supercapacitors," Electrochim Acta, vol. 278, pp. 33-41, 2018.
[7] B. Liang, Y. Ai, Y. Wang, C. Liu, S. Ouyang, and M. Liu, "Spinel-Type (FeCoCrMnZn) 3O4 High-Entropy Oxide: Facile Preparation and Supercapacitor Performance," Materials, vol. 13, no. 24, p. 5798, 2020.
[8] A. Akram et al., "Ultrahigh performance asymmetric supercapacitor devices with synergetic interaction between metal organic frameworks/graphene nano platelets and redox additive electrolyte," J Alloy Compd, vol. 891, p. 161961, 2022.
[9] W. Raza et al., "Recent advancements in supercapacitor technology," (in English), Nano Energy, vol. 52, pp. 441-473, Oct 2018.
[10] W. Qin et al., "Mini-Review on the Redox Additives in Aqueous Electrolyte for High Performance Supercapacitors," Acs Omega, vol. 5, no. 8, pp. 3801-3808, 2020.
[11] M. Zhang, Y. Li, and Z. Shen, "“Water-in-salt” electrolyte enhanced high voltage aqueous supercapacitor with all-pseudocapacitive metal-oxide electrodes," J Power Sources, vol. 414, pp. 479-485, 2019.
[12] S. Li et al., "High-Performance Flexible Asymmetric Supercapacitor Based on CoAl-LDH and rGO Electrodes," Nanomicro Lett, vol. 9, no. 3, p. 31, 2017.
[13] Y. Z. Wang et al., "Urchin-like Ni1/3Co2/3(CO3)(0.5)OH center dot 0.11H2O anchoring on polypyrrole nanotubes for supercapacitor electrodes," (in English), Electrochim Acta, vol. 295, pp. 989-996, Feb 1 2019.
[14] S. J. Zhu et al., "Structural Directed Growth of Ultrathin Parallel Birnessite on beta-MnO2 for High-Performance Asymmetric Supercapacitors," (in English), Acs Nano, vol. 12, no. 2, pp. 1033-1042, Feb 2018.
[15] L. Liu, Z. Niu, and J. Chen, "Unconventional supercapacitors from nanocarbon-based electrode materials to device configurations," Chemical Society Reviews, vol. 45, no. 15, pp. 4340-4363, 2016.
[16] G. Li et al., "One-pot synthesis of Cu-doped Ni3S2 nano-sheet/rod nanoarray for high performance supercapacitors," Chem. Eng. J., vol. 388, p. 124319, 2020/05/15/ 2020.
[17] Y. Liu, S. Jiang, and Z. Shao, "Intercalation pseudocapacitance in electrochemical energy storage: recent advances in fundamental understanding and materials development," Materials Today Advances, vol. 7, p. 100072, 2020.
[18] V. Augustyn, P. Simon, and B. Dunn, "Pseudocapacitive oxide materials for high-rate electrochemical energy storage," Energy & Environmental Science, vol. 7, no. 5, pp. 1597-1614, 2014.
[19] U. Uyor, A. Popoola, O. Popoola, V. Aigbodion, and C. Ujah, "Advancing Energy Storage Technology through Hybridization of Supercapacitors and Batteries: A Review on the Contribution of Carbon-Based Nanomaterials," in IOP Conference Series: Earth and Environmental Science, 2021, vol. 730, no. 1: IOP Publishing, p. 012006.
[20] H. Wang, H. S. Casalongue, Y. Liang, and H. Dai, "Ni (OH) 2 nanoplates grown on graphene as advanced electrochemical pseudocapacitor materials," Journal of the American Chemical Society, vol. 132, no. 21, pp. 7472-7477, 2010.
[21] L. Cao, F. Xu, Y. Y. Liang, and H. L. Li, "Preparation of the novel nanocomposite Co (OH) 2/ultra‐stable Y zeolite and its application as a supercapacitor with high energy density," Advanced materials, vol. 16, no. 20, pp. 1853-1857, 2004.
[22] C.-C. Hu and W.-C. Chen, "Effects of substrates on the capacitive performance of RuOx· nH2O and activated carbon–RuOx electrodes for supercapacitors," Electrochim Acta, vol. 49, no. 21, pp. 3469-3477, 2004.
[23] G.-W. Yang, C.-L. Xu, and H.-L. Li, "Electrodeposited nickel hydroxide on nickel foam with ultrahigh capacitance," Chem Commun, no. 48, pp. 6537-6539, 2008.
[24] C. Jing, B. Dong, and Y. Zhang, "Chemical modifications of layered double hydroxides in the supercapacitor," Energy & Environmental Materials, vol. 3, no. 3, pp. 346-379, 2020.
[25] G. Chen et al., "Microwave-assisted synthesis of hybrid CoxNi1− x (OH) 2 nanosheets: tuning the composition for high performance supercapacitor," J Power Sources, vol. 251, pp. 338-343, 2014.
[26] N. Poompiew, P. Pattananuwat, and P. Potiyaraj, "Controllable Morphology of Sea-Urchin-like Nickel–Cobalt Carbonate Hydroxide as a Supercapacitor Electrode with Battery-like Behavior," Acs Omega, vol. 6, no. 39, pp. 25138-25150, 2021.
[27] X. Sun, G. Wang, H. Sun, F. Lu, M. Yu, and J. Lian, "Morphology controlled high performance supercapacitor behaviour of the Ni–Co binary hydroxide system," J Power Sources, vol. 238, pp. 150-156, 2013.
[28] R. Li et al., "Large scale synthesis of NiCo layered double hydroxides for superior asymmetric electrochemical capacitor," Sci Rep-Uk, vol. 6, no. 1, pp. 1-9, 2016.
[29] I. Shakir, Z. Almutairi, and S. S. Shar, "Fabrication of binary transition metal hydroxides and their nanocomposite with CNTs for electrochemical capacitor applications," Ceram Int, vol. 47, no. 1, pp. 1191-1198, 2021.
[30] P. Sivakumar, M. Jana, M. G. Jung, A. Gedanken, and H. S. Park, "Hexagonal plate-like Ni–Co–Mn hydroxide nanostructures to achieve high energy density of hybrid supercapacitors," J Mater Chem A, vol. 7, no. 18, pp. 11362-11369, 2019.
[31] Y. Xiao et al., "Ultrahigh energy density and stable supercapacitor with 2D NiCoAl Layered double hydroxide," Electrochim Acta, vol. 253, pp. 324-332, 2017.
[32] H. Pourfarzad, M. Shabani-Nooshabadi, M. R. Ganjali, and H. Kashani, "Synthesis of Ni–Co-Fe layered double hydroxide and Fe2O3/Graphene nanocomposites as actively materials for high electrochemical performance supercapacitors," Electrochim Acta, vol. 317, pp. 83-92, 2019.
[33] F. Chen et al., "Synthesis of CuO@ CoNi LDH on Cu foam for high-performance supercapacitors," Chem Eng J, vol. 401, p. 126145, 2020.
[34] J. Laverock et al., "Electronic structure of the kagome staircase compounds Ni 3 V 2 O 8 and Co 3 V 2 O 8," Phys Rev B, vol. 87, no. 12, p. 125133, 2013.
[35] S. E. Arasi, P. Devendran, R. Ranjithkumar, S. Arunpandiyan, and A. Arivarasan, "Electrochemical property analysis of zinc vanadate nanostructure for efficient supercapacitors," Mat Sci Semicon Proc, vol. 106, p. 104785, 2020.
[36] K. K. Haldar, R. Biswas, A. Arya, I. Ahmed, S. Tanwar, and A. L. Sharma, "Construction of three‐dimensional marigold flower‐shaped Ni3V2O8 for efficient solid‐state supercapacitor applications," Energy Storage, p. e378, 2022.
[37] W. H. Low, C. W. Siong, C. H. Chia, S. S. Lim, and P. S. Khiew, "A facile synthesis of graphene/Co3V2O8 nanocomposites and their enhanced charge storage performance in electrochemical capacitors," Journal of Science: Advanced Materials and Devices, vol. 4, no. 4, pp. 515-523, 2019.
[38] B. Huang et al., "Rational design and facile synthesis of two-dimensional hierarchical porous M3V2O8 (M= Co, Ni and Co–Ni) thin sheets assembled by ultrathin nanosheets as positive electrode materials for high-performance hybrid supercapacitors," Chem Eng J, vol. 375, p. 121969, 2019.
[39] H. Sun et al., "3D porous hydrated cobalt pyrovanadate microflowers with excellent cycling stability as cathode materials for asymmetric supercapacitor," Appl Surf Sci, vol. 469, pp. 118-124, 2019.
[40] S. E. Arasi, R. Ranjithkumar, P. Devendran, M. Krishnakumar, and A. Arivarasan, "Investigation on electrochemical behaviour of manganese vanadate nanopebbles as potential electrode material for supercapacitors," J Alloy Compd, vol. 857, p. 157628, 2021.
[41] J. Zhang et al., "Facile synthesis of 3D porous Co 3 V 2 O 8 nanoroses and 2D NiCo 2 V 2 O 8 nanoplates for high performance supercapacitors and their electrocatalytic oxygen evolution reaction properties," Dalton T, vol. 46, no. 10, pp. 3295-3302, 2017.
[42] M. Amiri, S. S. H. Davarani, S. K. Kaverlavani, S. E. Moosavifard, and M. Shamsipur, "Construction of hierarchical nanoporous CuCo2V2O8 hollow spheres as a novel electrode material for high-performance asymmetric supercapacitors," Appl Surf Sci, vol. 527, p. 146855, 2020.
[43] Z. Fahimi, O. Moradlou, A. Sabbah, K.-H. Chen, L.-C. Chen, and M. Qorbani, "Co3V2O8 hollow spheres with mesoporous walls as high-capacitance electrode for hybrid supercapacitor device," Chem Eng J, vol. 436, p. 135225, 2022.
[44] H. Hosseini and S. Shahrokhian, "Advanced binder-free electrode based on core–shell nanostructures of mesoporous Co3V2O8-Ni3V2O8 thin layers@ porous carbon nanofibers for high-performance and flexible all-solid-state supercapacitors," Chemical Engineering Journal, vol. 341, pp. 10-26, 2018.
[45] R. Mishra, P. Panda, and S. Barman, "Synthesis of a Co 3 V 2 O 8/CN x hybrid nanocomposite as an efficient electrode material for supercapacitors," New J Chem, vol. 45, no. 13, pp. 5897-5906, 2021.
[46] Y.-M. Hu et al., "Design and synthesis of Ni2P/Co3V2O8 nanocomposite with enhanced electrochemical capacitive properties," Electrochim Acta, vol. 190, pp. 1041-1049, 2016.
[47] C. Liu et al., "Ternary MOF-on-MOF heterostructures with controllable architectural and compositional complexity via multiple selective assembly," Nature Communications, vol. 11, no. 1, p. 4971, 2020/10/02 2020.
[48] B. Xu, H. Zhang, H. Mei, and D. Sun, "Recent progress in metal-organic framework-based supercapacitor electrode materials," Coordination Chemistry Reviews, vol. 420, p. 213438, 2020/10/01/ 2020.
[49] W. Ahn et al., "Hollow Multivoid Nanocuboids Derived from Ternary Ni–Co–Fe Prussian Blue Analog for Dual-Electrocatalysis of Oxygen and Hydrogen Evolution Reactions," Advanced Functional Materials, vol. 28, no. 28, p. 1802129, 2018.
[50] N. L. Wulan Septiani et al., "Self-assembly of nickel phosphate-based nanotubes into two-dimensional crumpled sheet-like architectures for high-performance asymmetric supercapacitors," Nano Energy, vol. 67, p. 104270, 2020/01/01/ 2020.
[51] J. Chen et al., "Prussian blue, its analogues and their derived materials for electrochemical energy storage and conversion," Energy Storage Mater, vol. 25, pp. 585-612, 2020.
[52] Q. Wang, J. Li, H. Jin, S. Xin, and H. Gao, "Prussian‐blue materials: Revealing new opportunities for rechargeable batteries," InfoMat, p. e12311, 2022.
[53] Y. Kang et al., "[Fe (CN) 6] vacancy-boosting oxygen evolution activity of Co-based Prussian blue analogues for hybrid sodium-air battery," Materials Today Energy, vol. 20, p. 100572, 2021.
[54] B. Wang et al., "Prussian blue analogs for rechargeable batteries," Iscience, vol. 3, pp. 110-133, 2018.
[55] Y. J. Ma et al., "High-Entropy Metal-Organic Frameworks for Highly Reversible Sodium Storage," (in English), Advanced Materials, vol. 33, no. 34, Aug 2021.
[56] F. Zhao et al., "Cobalt hexacyanoferrate nanoparticles as a high-rate and ultra-stable supercapacitor electrode material," Acs Appl Mater Inter, vol. 6, no. 14, pp. 11007-11012, 2014.
[57] X. Zhang et al., "A novel cobalt hexacyanoferrate/multi-walled carbon nanotubes nanocomposite: spontaneous assembly synthesis and application as electrode materials with significantly improved capacitance for supercapacitors," Electrochim Acta, vol. 259, pp. 793-802, 2018.
[58] D. Xiong, S.-C. Wang, C. Chen, M. Gu, and F.-Y. Yi, "Rational design of multiple Prussian-blue analogues/NF composites for high-performance surpercapacitors," New J Chem, vol. 44, no. 25, pp. 10359-10366, 2020.
[59] X. Jiang, H. Liu, J. Song, C. Yin, and H. Xu, "Hierarchical mesoporous octahedral K 2 Mn 1− x Co x Fe (CN) 6 as a superior cathode material for sodium-ion batteries," J Mater Chem A, vol. 4, no. 41, pp. 16205-16212, 2016.
[60] H. Fu et al., "Enhanced storage of sodium ions in Prussian blue cathode material through nickel doping," J Mater Chem A, vol. 5, no. 20, pp. 9604-9610, 2017.
[61] A. Safavi, S. Kazemi, and H. Kazemi, "Electrochemically deposited hybrid nickel–cobalt hexacyanoferrate nanostructures for electrochemical supercapacitors," Electrochim Acta, vol. 56, no. 25, pp. 9191-9196, 2011.
[62] N. K. A. Venugopal and J. Joseph, "Electrochemically formed 3D hierarchical thin films of cobalt–manganese (Co–Mn) hexacyanoferrate hybrids for electrochemical applications," J Power Sources, vol. 305, pp. 249-258, 2016.
[63] J. T. Hou, Z. M. Tang, K. Y. Wei, Q. X. Lai, and Y. Y. Liang, "Surface reconstruction of Ni doped Co-Fe Prussian blue analogues for enhanced oxygen evolution," (in English), Catal Sci Technol, vol. 11, no. 3, pp. 1110-1115, Feb 7 2021.
[64] H. J. Zou et al., "Constructing highly active Co sites in Prussian blue analogues for boosting electrocatalytic water oxidation," (in English), Chem Commun, vol. 57, no. 65, pp. 8011-8014, Aug 21 2021.
[65] N. Qiu, H. Chen, Z. Yang, S. Sun, Y. Wang, and Y. Cui, "A high entropy oxide (Mg0. 2Co0. 2Ni0. 2Cu0. 2Zn0. 2O) with superior lithium storage performance," J Alloy Compd, vol. 777, pp. 767-774, 2019.
[66] T. X. Nguyen, Y. H. Su, C. C. Lin, J. Ruan, and J. M. Ting, "A new high entropy glycerate for high performance oxygen evolution reaction," Advanced Science, vol. 8, no. 6, p. 2002446, 2021.
[67] Q. Wang et al., "High entropy oxides as anode material for Li-ion battery applications: A practical approach," Electrochemistry Communications, vol. 100, pp. 121-125, 2019.
[68] T. X. Nguyen, J. Patra, J.-K. Chang, and J.-M. Ting, "High entropy spinel oxide nanoparticles for superior lithiation–delithiation performance," J Mater Chem A, vol. 8, no. 36, pp. 18963-18973, 2020.
[69] C.-Y. Huang et al., "Atomic-scale investigation of Lithiation/Delithiation mechanism in High-entropy spinel oxide with superior electrochemical performance," Chem Eng J, vol. 420, p. 129838, 2021.
[70] T. X. Nguyen, Y. C. Liao, C. C. Lin, Y. H. Su, and J. M. Ting, "Advanced High Entropy Perovskite Oxide Electrocatalyst for Oxygen Evolution Reaction," Advanced Functional Materials, p. 2101632, 2021.
[71] Z. Jin et al., "Nanoporous Al‐Ni‐Co‐Ir‐Mo High‐Entropy Alloy for Record‐High Water Splitting Activity in Acidic Environments," Small, vol. 15, no. 47, p. 1904180, 2019.
[72] S. Nellaiappan et al., "High-entropy alloys as catalysts for the CO2 and CO reduction reactions: Experimental realization," ACS Catalysis, vol. 10, no. 6, pp. 3658-3663, 2020.
[73] S. Nellaiappan et al., "Nobel metal based high entropy alloy for conversion of carbon dioxide (CO2) to hydrocarbon," 2019.
[74] H.-X. Guo, C.-Y. He, X.-L. Qiu, Y.-Q. Shen, G. Liu, and X.-H. Gao, "A novel multilayer high temperature colored solar absorber coating based on high-entropy alloy MoNbHfZrTi: Optimized preparation and chromaticity investigation," Solar Energy Materials and Solar Cells, vol. 209, p. 110444, 2020.
[75] W. Jiang et al., "Room temperature synthesis of high-entropy Prussian blue analogues," Nano Energy, vol. 79, p. 105464, 2021.
[76] W. Zhang et al., "Core–Shell Prussian Blue Analogs with Compositional Heterogeneity and Open Cages for Oxygen Evolution Reaction," Adv. Sci., vol. 6, no. 7, p. 1801901, 2019.
[77] J. Hou, Z. Tang, K. Wei, Q. Lai, and Y. Liang, "Surface reconstruction of Ni doped Co–Fe Prussian blue analogues for enhanced oxygen evolution," Catal Sci Technol, vol. 11, no. 3, pp. 1110-1115, 2021.
[78] B. Pal, S. Yang, S. Ramesh, V. Thangadurai, and R. Jose, "Electrolyte selection for supercapacitive devices: A critical review," Nanoscale Adv, vol. 1, no. 10, pp. 3807-3835, 2019.
[79] S.-E. Chun et al., "Design of aqueous redox-enhanced electrochemical capacitors with high specific energies and slow self-discharge," Nature communications, vol. 6, no. 1, pp. 1-10, 2015.
[80] A. G. Tamirat, X. Guan, J. Liu, J. Luo, and Y. Xia, "Redox mediators as charge agents for changing electrochemical reactions," Chemical Society Reviews, 10.1039/D0CS00489H vol. 49, no. 20, pp. 7454-7478, 2020.
[81] I. Tanahashi, "Capacitance enhancement of activated carbon fiber cloth electrodes in electrochemical capacitors with a mixed aqueous solution of H2SO4 and AgNO3," Electrochemical and Solid-State Letters, vol. 8, no. 12, p. A627, 2005.
[82] D. Xu, W. Hu, X. N. Sun, P. Cui, and X. Y. Chen, "Redox additives of Na2MoO4 and KI: Synergistic effect and the improved capacitive performances for carbon-based supercapacitors," (in English), J Power Sources, vol. 341, pp. 448-456, Feb 15 2017.
[83] L.-H. Su, X.-G. Zhang, C.-H. Mi, B. Gao, and Y. Liu, "Improvement of the capacitive performances for Co–Al layered double hydroxide by adding hexacyanoferrate into the electrolyte," Physical Chemistry Chemical Physics, vol. 11, no. 13, pp. 2195-2202, 2009.
[84] V. Sharma, U. Narayan Pan, T. Ibomcha Singh, A. Kumar Das, N. Hoon Kim, and J. Hee Lee, "Pragmatically designed tetragonal copper ferrite super-architectures as advanced multifunctional electrodes for solid-state supercapacitors and overall water splitting," Chemical Engineering Journal, p. 127779, 2020/11/30/ 2020.
[85] Y. Du et al., "Hollow nickel-cobalt-manganese hydroxide polyhedra via MOF templates for high-performance quasi-solid-state supercapacitor," Chemical Engineering Journal, vol. 378, p. 122210, 2019/12/15/ 2019.
[86] Y. Gai et al., "A self-template synthesis of porous ZnCo2O4 microspheres for high-performance quasi-solid-state asymmetric supercapacitors," RSC Advances, 10.1039/C6RA25950B vol. 7, no. 2, pp. 1038-1044, 2017.
[87] P. Yang et al., "Fractal (NixCo1−x)9Se8 Nanodendrite Arrays with Highly Exposed () Surface for Wearable, All-Solid-State Supercapacitor," Advanced Energy Materials, vol. 8, no. 26, p. 1801392, 2018.
[88] J.-A. Wang, C.-C. M. Ma, and C.-C. Hu, "Constructing a high-performance quasi-solid-state asymmetric supercapacitor: NaxMnO2@CNT/WPU-PAAK-Na2SO4/AC-CNT," Electrochimica Acta, vol. 334, p. 135576, 2020/02/20/ 2020.
[89] X. Y. He et al., "High-performance all-solid-state asymmetrical supercapacitors based on petal-like NiCo2S4/Polyaniline nanosheets," (in English), Chem Eng J, vol. 325, pp. 134-143, Oct 1 2017.
[90] J. Zhao et al., "A high‐energy density asymmetric supercapacitor based on Fe2O3 nanoneedle arrays and NiCo2O4/Ni (OH) 2 hybrid nanosheet arrays grown on SiC nanowire networks as free‐standing advanced electrodes," Adv Energy Mater, vol. 8, no. 12, p. 1702787, 2018.
[91] X. M. Feng et al., "Synthesis of shape-controlled NiO-graphene nanocomposites with enhanced supercapacitive properties," (in English), New J Chem, vol. 39, no. 5, pp. 4026-4034, 2015.
[92] M. H. Chunyan Zhang, Xiaoyi Cai, Jianjian Lin, Xiang Liu, Ruirui Wang,a Lijun Zhou, Jingchang Gao, Baosheng Li and Linfei Lai, "One-step coaxial electrodeposition of Co0.85Se on CoNi2S4 nanotube arrays for flexible solid-state asymmetric supercapacitors," J. Mater. Chem. A,, vol. 6, p. 15630, 2018.
[93] J. Hao et al., "A low crystallinity oxygen-vacancy-rich Co 3 O 4 cathode for high-performance flexible asymmetric supercapacitors," J Mater Chem A, vol. 6, no. 33, pp. 16094-16100, 2018.
[94] S. S. Liu, Y. S. Wang, and Z. L. Ma, "Bi2O3 with Reduced Graphene Oxide Composite as a Supercapacitor Electrode," (in English), Int J Electrochem Sc, vol. 13, no. 12, pp. 12256-12265, Dec 2018.
[95] T. H. Lee, D. T. Pham, R. Sahoo, J. Seok, T. H. T. Luu, and Y. H. Lee, "High energy density and enhanced stability of asymmetric supercapacitors with mesoporous MnO2@CNT and nanodot MoO3@CNT free-standing films," (in English), Energy Storage Mater, vol. 12, pp. 223-231, May 2018.
[96] S. Sheng et al., "Fe3O4 nanospheres in situ decorated graphene as high-performance anode for asymmetric supercapacitor with impressive energy density," (in English), J Colloid Interf Sci, vol. 536, pp. 235-244, Feb 15 2019.
[97] Z. Sun et al., "Rapid microwave-assisted synthesis of high-rate FeS 2 nanoparticles anchored on graphene for hybrid supercapacitors with ultrahigh energy density," J Mater Chem A, vol. 6, no. 30, pp. 14956-14966, 2018.
[98] L. Chen, D. B. Liu, and P. Yang, "Preparation of alpha-Fe2O3/rGO composites toward supercapacitor applications," (in English), Rsc Adv, vol. 9, no. 23, pp. 12793-12800, 2019.
[99] Y. Gao et al., "One-step solvothermal synthesis of quasi-hexagonal Fe2O3 nanoplates/graphene composite as high performance electrode material for supercapacitor," Electrochim Acta, vol. 191, pp. 275-283, 2016.
[100] Y. Y. Zhu et al., "Construction and Performance Characterization of alpha-Fe2O3/rGO Composite for Long-Cycling-Life Supercapacitor Anode," (in English), Acs Sustain Chem Eng, vol. 5, no. 6, pp. 5067-5074, Jun 2017.
[101] X. X. Liu et al., "Ultrahigh-rate-capability of a layered double hydroxide supercapacitor based on a self-generated electrolyte resentoir," (in English), J Mater Chem A, vol. 4, no. 21, pp. 8421-8427, Jun 7 2016.
[102] L. Y. Hou et al., "Ni-Co layered double hydroxide with self-assembled urchin like morphology for asymmetric supercapacitors," (in English), Mater Lett, vol. 237, pp. 262-265, Feb 15 2019.
[103] D. Lee, Q. X. Xia, J. M. Yun, and K. H. Kim, "High-performance cobalt carbonate hydroxide nano-dot/NiCo(CO3)(OH)(2) electrode for asymmetric supercapacitors," (in English), Appl Surf Sci, vol. 433, pp. 16-26, Mar 1 2018.
[104] B. Yang et al., "Fabrication of urchin-like NiCo2(CO3)(1.5)(OH)(3)@NiCo2S4 on Ni foam by an ion-exchange route and application to asymmetrical supercapacitors," (in English), J Mater Chem A, vol. 3, no. 25, pp. 13308-13316, 2015.
[105] A. Tyagi, M. C. Joshi, K. Agarwal, B. Balasubramaniam, and R. K. Gupta, "Three-dimensional nickel vanadium layered double hydroxide nanostructures grown on carbon cloth for high-performance flexible supercapacitor applications," (in English), Nanoscale Adv, vol. 1, no. 6, pp. 2400-2407, Jun 1 2019.
[106] S. Sundriyal, V. Shrivastav, M. Sharma, S. Mishra, and A. Deep, "Significantly enhanced performance of rGO/TiO2 nanosheet composite electrodes based 1.8 V symmetrical supercapacitor with use of redox additive electrolyte," (in English), J Alloy Compd, vol. 790, pp. 377-387, Jun 25 2019.
[107] K. V. Sankar and R. K. Selvan, "Improved electrochemical performances of reduced graphene oxide based supercapacitor using redox additive electrolyte," (in English), Carbon, vol. 90, pp. 260-273, Aug 2015.
[108] P. A. Shinde, V. C. Lokhande, N. R. Chodankar, T. Ji, J. H. Kim, and C. D. Lokhande, "Enhanced electrochemical performance of monoclinic WO3 thin film with redox additive aqueous electrolyte," (in English), J Colloid Interf Sci, vol. 483, pp. 261-267, Dec 1 2016.
[109] B. Ye et al., "Improved performance of a CoTe//AC asymmetric supercapacitor using a redox additive aqueous electrolyte," Rsc Adv, vol. 8, no. 15, pp. 7997-8006, 2018.
[110] J. Y. Myeongjin Kim , Jooheon Kim, "Quasi-solid-state flexible asymmetric supercapacitor based on ferroferric oxide nanoparticles on porous silicon carbide with redox-active p-nitroaniline gel electrolyte," Chem Eng J, vol. 324, pp. 93-103, 2017.
[111] A. M. Patil et al., "Redox-ambitious route to boost energy and capacity retention of pouch type asymmetric solid-state supercapacitor fabricated with graphene oxide-based battery-type electrodes," Applied Materials Today, vol. 19, pp. 100563 - 100578, 2020.
[112] K.-H. Lin, L.-Y. Lin, and W.-L. Hong, "Incorporating redox additives in sodium hydroxide electrolyte for energy storage device with the nickel cobalt molybdenum oxide active material," J Energy Storage, vol. 25, pp. 100823-100830, 2019.
[113] K. F. Chen, F. Liu, D. F. Xue, and S. Komarneni, "Carbon with ultrahigh capacitance when graphene paper meets K3Fe(CN)(6)," (in English), Nanoscale, vol. 7, no. 2, pp. 432-439, 2015.
[114] R. L. Meng Tian Jiawen Wu, Youlin Chen, Donghui Long, "Fabricating a high-energy-density supercapacitor with asymmetric aqueousredox additive electrolytes and free-standing activated-carbon-feltelectrodes," Chem Eng J, vol. 369, pp. 183-191, 2019.
[115] N. R. Chodankar, D. P. Dubal, A. C. Lokhande, A. M. Patil, J. H. Kim, and C. D. Lokhande, "An innovative concept of use of redox-active electrolyte in asymmetric capacitor based on MWCNTs/MnO 2 and Fe 2 O 3 thin films," Sci Rep-Uk, vol. 6, no. 1, pp. 1-14, 2016.
[116] C. Zhao, W. Zheng, X. Wang, H. Zhang, X. Cui, and H. Wang, "Ultrahigh capacitive performance from both Co (OH) 2/graphene electrode and K 3 Fe (CN) 6 electrolyte," Sci Rep-Uk, vol. 3, p. 2986, 2013.
[117] X. H. Guan, M. Huang, L. Yang, G. S. Wang, and X. Guan, "Facial design and synthesis of CoSx/Ni-Co LDH nanocages with rhombic dodecahedral structure for high-performance asymmetric supercapacitors," (in English), Chem Eng J, vol. 372, pp. 151-162, Sep 15 2019.
[118] X. Gao, Y. Zhao, K. Dai, J. Wang, B. Zhang, and X. Shen, "NiCoP nanowire@ NiCo-layered double hydroxides nanosheet heterostructure for flexible asymmetric supercapacitors," Chem Eng J, vol. 384, p. 123373, 2020.
[119] S. Wang et al., "Hierarchical cobalt oxide@ Nickel-vanadium layer double hydroxide core/shell nanowire arrays with enhanced areal specific capacity for nickel–zinc batteries," J Power Sources, vol. 436, pp. 226867-226875, 2019.
[120] S. Wang et al., "Intercalation and elimination of carbonate ions of NiCo layered double hydroxide for enhanced oxygen evolution catalysis," International Journal of Hydrogen Energy, vol. 45, no. 23, pp. 12629-12640, 2020.
[121] W. T. Fengren Cao, Liang Li, "Ternary non-noble metal zinc-nickel-cobalt carbonate hydroxide cocatalysts toward highly efficient photoelectrochemical water splitting," Journal of Materials Science & Technology, vol. 34, pp. 899–904, 2018.
[122] C. S. Lim, C. K. Chua, Z. Sofer, K. Klímová, C. Boothroyd, and M. Pumera, "Layered transition metal oxyhydroxides as tri-functional electrocatalysts," J Mater Chem A, vol. 3, no. 22, pp. 11920-11929, 2015.
[123] J. Yang, H. Liu, W. N. Martens, and R. L. Frost, "Synthesis and characterization of cobalt hydroxide, cobalt oxyhydroxide, and cobalt oxide nanodiscs," The Journal of Physical Chemistry C, vol. 114, no. 1, pp. 111-119, 2010.
[124] L. Liu et al., "Synthesis of self-templated urchin-like Ni2Co (CO3) 2 (OH) 2 hollow microspheres for high-performance hybrid supercapacitor electrodes," Electrochim Acta, vol. 327, p. 134970, 2019.
[125] Y. H. Xuansheng Feng, Chao Li, Xuefang Chen, Suhua Zhou, Xiaogang Gao, Chen Chen, "Controllable synthesis of porous NiCo2O4/NiO/Co3O4 nanoflowers for asymmetric all-solid-state supercapacitors," Chem Eng J, vol. 368, pp. 51-61, 2019.
[126] K. Fan et al., "Direct observation of structural evolution of metal chalcogenide in electrocatalytic water oxidation," Acs Nano, vol. 12, no. 12, pp. 12369-12379, 2018.
[127] M. Cui et al., "Promotion of the Electrocatalytic Oxygen Evolution Reaction by Chemical Coupling of CoOOH Particles to 3D Branched γ-MnOOH Rods," Acs Sustain Chem Eng, vol. 7, no. 15, pp. 13015-13022, 2019.
[128] S. P. Chen et al., "A Tubular Sandwich-Structured CNT@Ni@Ni2(CO3)(OH)(2) with High Stability and Superior Capacity as Hybrid Supercapacitor," (in English), J Phys Chem C, vol. 121, no. 18, pp. 9719-9728, May 11 2017.
[129] S. Arshadi Rastabi, R. Sarraf Mamoory, F. Dabir, N. Blomquist, M. Phadatare, and H. Olin, "Synthesis of NiMoO4/3D-rGO nanocomposite in alkaline environments for supercapacitor electrodes," Crystals, vol. 9, no. 1, p. 31, 2019.
[130] C. Meng et al., "Laser synthesis of oxygen vacancy-modified CoOOH for highly efficient oxygen evolution," Chem Commun, vol. 55, no. 20, pp. 2904-2907, 2019.
[131] B. W. Veal, S. K. Kim, P. Zapol, H. Iddir, P. M. Baldo, and J. A. Eastman, "Interfacial control of oxygen vacancy doping and electrical conduction in thin film oxide heterostructures," Nature communications, vol. 7, no. 1, pp. 1-8, 2016.
[132] P. Biswas et al., "Tuning of oxygen vacancy-induced electrical conductivity in Ti-doped hematite films and its impact on photoelectrochemical water splitting," Sci Rep-Uk, vol. 10, no. 1, pp. 1-9, 2020.
[133] T. Wang, H. C. Chen, F. Yu, X. Zhao, and H. Wang, "Boosting the cycling stability of transition metal compounds-based supercapacitors," Energy Storage Mater, vol. 16, pp. 545-573, 2019.
[134] Y. Zhou, P. Jin, Y. Zhou, and Y. Zhu, "High-performance symmetric supercapacitors based on carbon nanotube/graphite nanofiber nanocomposites," Sci Rep-Uk, vol. 8, no. 1, pp. 1-7, 2018.
[135] S. Sundriyal, V. Shrivastav, H. Kaur, S. Mishra, and A. Deep, "High-Performance Symmetrical Supercapacitor with a Combination of a ZIF-67/rGO Composite Electrode and a Redox Additive Electrolyte," (in English), Acs Omega, vol. 3, no. 12, pp. 17348-17358, Dec 2018.
[136] R. K. S. S.T.Senthilkumar, M.Ulaganathan, J.S.Melo, "Fabrication of Bi2O3||AC asymmetric supercapacitor with redoxadditive aqueous electrolyte and its improved electrochemicalperformances," Electrochim Acta, no. 115, pp. 518– 524, 20144.
[137] L. Wan et al., "In situ grown NiFeP@ NiCo2S4 nanosheet arrays on carbon cloth for asymmetric supercapacitors," Chem Eng J, vol. 399, pp. 125778 (1-12), 2020.
[138] H. F. Nan Zhao, Mingchang Zhang, Jiangwei Ma, Zhinan Du, Benben Yan, Hua Li, Xinbiao Jiang, "Simple electrodeposition of MoO3 film on carbon cloth for high-performance aqueous symmetric supercapacitors," Chem Eng J, vol. 390, pp. 124477 (1-9), 2020.
[139] S. Q. Yulin Jiang Chengen He, Jinlong Zhang, Xianggang Wang, Yingkui Yang, "Scalable mechanochemical coupling of homogeneous Co3O4nanocrystalsontoin-situexfoliated graphene sheets for asymmetric supercapacitors," Chem Eng J, vol. 397, pp. 125503 (1-9), 2020.
[140] C. Lamiel, Y. R. Lee, M. H. Cho, D. Tuma, and J. J. Shim, "Enhanced electrochemical performance of nickel-cobalt-oxide@reduced graphene oxide//activated carbon asymmetric supercapacitors by the addition of a redox-active electrolyte," J Colloid Interface Sci, vol. 507, pp. 300-309, Dec 1 2017.
[141] Z. W. Tongkuan Xu, Guoxiang Wang, Lu Lu, Sa Liu, Shiping Gao, Hongfeng Xu, Zhihui Yu, "One-pot synthesis of a CoS-AC electrode in a redox electrolyte for high-performance supercapacitors," Journal of Applied Electrochemistry, vol. 49, no. 11, pp. 1069–1077, 2019.
[142] L. Yan et al., "Confining Redox Electrolytes in Functionalized Porous Carbon with Improved Energy Density for Supercapacitors," ACS Appl Mater Interfaces, vol. 10, no. 49, pp. 42494-42502, Dec 12 2018.
[143] J. Zheng et al., "Integrated MXene-based Aerogel Composite: Componential and Structural Engineering towards Enhanced Performance Stability of Hybrid Supercapacitor," Chem Eng J, p. 125197, 2020.
[144] L. Wan et al., "Construction of FeNiP@CoNi-layered double hydroxide hybrid nanosheets on carbon cloth for high energy asymmetric supercapacitors," J Power Sources, vol. 465, p. 228293, 2020.
[145] X. Wang, F. Huang, F. Rong, P. He, and R. Que, "Unique MOF-derived hierarchical MnO 2 nanotubes@ NiCo-LDH/CoS 2 nanocage materials as high performance supercapacitors," J Mater Chem A, vol. 7, no. 19, pp. 12018-12028, 2019.
[146] J. Cao et al., "Mn-Doped Ni/Co LDH Nanosheets Grown on the Natural N-Dispersed PANI-Derived Porous Carbon Template for a Flexible Asymmetric Supercapacitor," Acs Sustain Chem Eng, vol. 7, no. 12, pp. 10699-10707, 2019.
[147] C. Yu et al., "Enhanced Energy Storage Performance of 3D Hybrid Metal Sulfides via Synergistic Engineering of Architecture and Composition," Acs Sustain Chem Eng, vol. 8, no. 31, pp. 11491-11500, 2020.
[148] J. Acharya, T. H. Ko, M.-K. Seo, M.-S. Khil, H.-Y. Kim, and B.-S. Kim, "Engineering the Hierarchical Heterostructures of Zn–Ni–Co Nanoneedles Arrays@ Co–Ni-LDH Nanosheets Core–Sheath Electrodes for a Hybrid Asymmetric Supercapacitor with High Energy Density and Excellent Cyclic Stability," ACS Applied Energy Materials, vol. 3, p. 7383−7396, 2020.
[149] L. Zhu, C. Hao, X. Wang, and Y. Guo, "Fluffy Cotton-Like GO/Zn–Co–Ni Layered Double Hydroxides Form from a Sacrificed Template GO/ZIF-8 for High Performance Asymmetric Supercapacitors," Acs Sustain Chem Eng, vol. 8, no. 31, pp. 11618-11629, 2020.
[150] R. Chen et al., "Solution‐Processable Design of Fiber‐Shaped Wearable Zn//Ni (OH) 2 Battery," Energy Technology, vol. 6, no. 12, pp. 2326-2332, 2018.
[151] R. Chen et al., "Jahn–Teller distortions boost the ultrahigh areal capacity and cycling robustness of holey NiMn-hydroxide nanosheets for flexible energy storage devices," Nanoscale, vol. 12, no. 43, pp. 22075-22081, 2020.
[152] H. Xu et al., "Mechanistic insight in site-selective and anisotropic etching of prussian blue analogues toward designable complex architectures for efficient energy storage," Nanoscale, vol. 12, no. 20, pp. 11112-11118, 2020.
[153] G. R. Wang, Z. L. Jin, and W. X. Zhang, "A phosphatized NiCo LDH 1D dendritic electrode for high energy asymmetric supercapacitors," (in English), Dalton T, vol. 48, no. 39, pp. 14853-14863, Oct 21 2019.
[154] M. Khalid, P. Bhardwaj, and H. Varela, "Carbon-based composites for supercapacitor," in Science, Technology and Advanced Application of Supercapacitors: IntechOpen, 2018.
[155] L. Hua et al., "General metal-ion mediated method for functionalization of graphene fiber," Acs Appl Mater Inter, vol. 9, no. 42, pp. 37022-37030, 2017.
[156] X. Lv, W. Huang, Q. Shi, L. Tang, and J. Tang, "Synthesis of amorphous NiCozVxOy nanosphere as a positive electrode materials via a facile route for asymmetric supercapacitors," J Power Sources, vol. 492, p. 229623, 2021.
[157] L. Li et al., "Assembling laminated films via the synchronous reduction of graphene oxide and formation of copper-based metal organic frameworks," J Mater Chem A, vol. 7, no. 1, pp. 107-111, 2019.
[158] Y. Gong et al., "Hierarchically tubular architectures composed of vertical carbon nanosheets embedded with oxygen-vacancy enriched hollow Co3O4 nanoparticles for improved energy storage," Electrochim Acta, vol. 356, p. 136843, 2020.
[159] Y. Teng et al., "The Microwave‐Assisted Hydrothermal Synthesis of CoV2O6 and Co3V2O8 with Morphology Tuning by pH Adjustments for Supercapacitor Applications," ChemistrySelect, vol. 4, no. 3, pp. 956-962, 2019.
[160] Z. Khan, B. Senthilkumar, S. Lim, R. Shanker, Y. Kim, and H. Ko, "Redox‐additive‐enhanced high capacitance supercapacitors based on Co2P2O7 nanosheets," Advanced Materials Interfaces, vol. 4, no. 12, p. 1700059, 2017.
[161] M.-C. Liu et al., "Synthesis and characterization of M3V2O8 (M= Ni or Co) based nanostructures: a new family of high performance pseudocapacitive materials," Journal of Materials Chemistry A, vol. 2, no. 14, pp. 4919-4926, 2014.
[162] W.-B. Zhang, L.-B. Kong, X.-J. Ma, Y.-C. Luo, and L. Kang, "Design, synthesis and evaluation of three-dimensional Co3O4/Co3(VO4)2 hybrid nanorods on nickel foam as self-supported electrodes for asymmetric supercapacitors," Journal of Power Sources, vol. 269, pp. 61-68, 2014.
[163] W.-B. Zhang, L.-B. Kong, X.-J. Ma, Y.-C. Luo, and L. Kang, "Three-dimensional nanostructured NiO–Co3(VO4)2 compound on nickel foam as pseudocapacitive electrodes for electrochemical capacitors," Journal of Alloys and Compounds, vol. 627, pp. 313-319, 2015.
[164] H. Hosseini and S. Shahrokhian, "Advanced binder-free electrode based on core–shell nanostructures of mesoporous Co3V2O8-Ni3V2O8 thin layers@porous carbon nanofibers for high-performance and flexible all-solid-state supercapacitors," Chem. Eng. J., vol. 341, pp. 10-26, 2018/06/01/ 2018.
[165] P. Samanta, S. Ghosh, N. C. Murmu, and T. Kuila, "Effect of redox additive in aqueous electrolyte on the high specific capacitance of cation incorporated MnCo2O4@Ni(OH)2 electrode materials for flexible symmetric supercapacitor," Composites Part B: Engineering, vol. 215, p. 108755, 2021.
[166] Y. Zhao et al., "Boosting the energy density of iron-cobalt oxide based hybrid supercapacitors by redox-additive electrolytes," J Alloy Compd, vol. 885, p. 160886, 2021.
[167] G. Dhakal, D. Mohapatra, T. L. Tamang, M. Lee, Y. R. Lee, and J.-J. Shim, "Redox-additive electrolyte–driven enhancement of the electrochemical energy storage performance of asymmetric Co3O4//carbon nano-onions supercapacitors," Energy, p. 119436, 2020.
[168] D. B. Bailmare, P. Tripathi, A. D. Deshmukh, and B. K. Gupta, "Designing of two dimensional lanthanum cobalt hydroxide engineered high performance supercapacitor for longer stability under redox active electrolyte," Sci Rep-Uk, vol. 12, no. 1, pp. 1-10, 2022.
[169] Y. Li, L. Kong, M. Liu, W. Zhang, and L. Kang, "The design and fabrication of Co3O4/Co3V2O8/Ni nanocomposites as high-performance anodes for Li-ion batteries," J Energy Chem, vol. 26, no. 3, pp. 494-500, 2017.
[170] T. Zhai et al., "Phosphate ion functionalized Co3O4 ultrathin nanosheets with greatly improved surface reactivity for high performance pseudocapacitors," Advanced Materials, vol. 29, no. 7, p. 1604167, 2017.
[171] Y. Chen, J. Huang, X. Zhang, and H. Xu, "Fabrication of hybrid supercapacitor of RGO//PPyNTs/Co (OH 2 based on K3Fe(CN)6 redox-active electrolyte," Journal of Electroanalytical Chemistry, vol. 884, p. 115069, 2021.
[172] C. Zhao, W. Zheng, X. Wang, H. Zhang, X. Cui, and H. Wang, "Ultrahigh capacitive performance from both Co(OH)2/graphene electrode and K3Fe(CN)6 electrolyte," Scientific reports, vol. 3, p. 2986, 2013.
[173] J. Pokharel et al., "MOF-derived hierarchical carbon network as an extremely-high-performance supercapacitor electrode," Electrochim Acta, vol. 394, p. 139058, 2021.
[174] R. Mohanty, G. Swain, K. Parida, and K. Parida, "Enhanced electrochemical performance of flexible asymmetric supercapacitor based on novel nanostructured activated fullerene anchored zinc cobaltite," J Alloy Compd, p. 165753, 2022.
[175] V. T. Nguyen and J.-M. Ting, "A Redox-Additive Electrolyte and Nanostructured Electrode for Enhanced Supercapacitor Energy Density," ACS Sustainable Chemistry & Engineering, vol. 8, no. 49, pp. 18023-18033, 2020.
[176] P. Samanta, S. Ghosh, N. C. Murmu, and T. Kuila, "Effect of redox additive in aqueous electrolyte on the high specific capacitance of cation incorporated MnCo2O4@ Ni (OH) 2 electrode materials for flexible symmetric supercapacitor," Composites Part B: Engineering, vol. 215, p. 108755, 2021.
[177] N. R. Chodankar, D. P. Dubal, A. C. Lokhande, A. M. Patil, J. H. Kim, and C. D. Lokhande, "An innovative concept of use of redox-active electrolyte in asymmetric capacitor based on MWCNTs/MnO2 and Fe2O3 thin films," Sci Rep-Uk, vol. 6, no. 1, pp. 1-14, 2016.
[178] J. Fu, L. Li, D. Lee, J. M. Yun, B. K. Ryu, and K. H. Kim, "Enhanced electrochemical performance of Ti3C2Tx MXene film based supercapacitors in H2SO4/KI redox additive electrolyte," Appl Surf Sci, vol. 504, p. 144250, 2020.
[179] M. He, K. Fic, E. Fra, P. Novák, and E. J. Berg, "Ageing phenomena in high-voltage aqueous supercapacitors investigated by in situ gas analysis," Energy & Environmental Science, vol. 9, no. 2, pp. 623-633, 2016.
[180] X. Liu et al., "Investigation of functionalization effect of carbon nanotubes as supercapacitor electrode material on hydrogen evolution side-reaction by scanning electrochemical microscopy," Electrochim Acta, vol. 429, p. 141056, 2022.
[181] Y. Zhou et al., "Ti3C2T x MXene-Reduced Graphene Oxide Composite Electrodes for Stretchable Supercapacitors," Acs Nano, vol. 14, no. 3, pp. 3576-3586, 2020.
[182] Y. Chen, Y. Jiang, Z. Liu, L. Yang, Q. Du, and K. Zhuo, "Hierarchical porous N-doped graphene aerogel with good wettability for high-performance ionic liquid-based supercapacitors," Electrochim Acta, vol. 366, p. 137414, 2021.
[183] X. Zhang, C. Jiang, J. Liang, and W. Wu, "Electrode materials and device architecture strategies for flexible supercapacitors in wearable energy storage," J Mater Chem A, vol. 9, no. 13, pp. 8099-8128, 2021.
[184] Y. Z. Song, X. J. Zhao, and Z. H. Liu, "Surface selenium doped hollow heterostructure/defects Co-Fe sulfide nanoboxes for enhancing oxygen evolution reaction and supercapacitors," (in English), Electrochim Acta, vol. 374, Apr 1 2021.
[185] Y. Wang et al., "Enhancing stability of Co9S8 by iron incorporation for oxygen evolution reaction and supercapacitor electrodes," Chem Eng J, vol. 431, p. 133980, 2022.
[186] S. K. Shinde et al., "Bifunctional nanoparticles decorated Ni1‐xMnxCo2O4 ultrathin nanoflakes‐like electrodes for supercapacitor and overall water splitting," International Journal of Energy Research, 2022.
[187] K. Xiang et al., "Enhancing bifunctional electrodes of oxygen vacancy abundant ZnCo2O4 nanosheets for supercapacitor and oxygen evolution," Chem Eng J, vol. 425, p. 130583, 2021.
[188] R. Liu et al., "Defect-engineered NiCo-S composite as a bifunctional electrode for high-performance supercapacitor and electrocatalysis," Acs Appl Mater Inter, vol. 13, no. 40, pp. 47717-47727, 2021.
[189] G. Cheng, T. Kou, J. Zhang, C. Si, H. Gao, and Z. Zhang, "O22-/O- functionalized oxygen-deficient Co3O4 nanorods as high performance supercapacitor electrodes and electrocatalysts towards water splitting," Nano Energy, vol. 38, pp. 155-166, 2017/08/01/ 2017.
[190] K. Xiang et al., "Enhancing bifunctional electrodes of oxygen vacancy abundant ZnCo2O4 nanosheets for supercapacitor and oxygen evolution," Chem. Eng. J., vol. 425, p. 130583, 2021/12/01/ 2021.
[191] K. Qin et al., "Designed synthesis of NiCo-LDH and derived sulfide on heteroatom-doped edge-enriched 3D rivet graphene films for high-performance asymmetric supercapacitor and efficient OER," J. Mater. Chem. A, 10.1039/C8TA01832D vol. 6, no. 17, pp. 8109-8119, 2018.
[192] S. Kumar, P. H. Weng, and Y. P. Fu, "Core-shell-structured CuO@Ni-MOF: bifunctional electrode toward battery-type supercapacitors and oxygen evolution reaction," Mater. Today Chem., vol. 26, p. 101159, 2022/12/01/ 2022.
[193] X. Y. Zhang and J. Dutta, "X-Fe (X = Mn, Co, Cu) Prussian Blue Analogue-Modified Carbon Cloth Electrodes for Capacitive Deionization," (in English), Acs Applied Energy Materials, vol. 4, no. 8, pp. 8275-8284, Aug 23 2021.
[194] P. Xiong, G. Zeng, L. Zeng, and M. Wei, "Prussian blue analogues Mn [Fe (CN) 6] 0.6667· n H 2 O cubes as an anode material for lithium-ion batteries," Dalton T, vol. 44, no. 38, pp. 16746-16751, 2015.
[195] X. Zhang, E. A. Toledo-Carrillo, D. Yu, and J. Dutta, "Effect of Surface Charge on the Fabrication of Hierarchical Mn-Based Prussian Blue Analogue for Capacitive Desalination," Acs Appl Mater Inter, vol. 14, no. 35, pp. 40371-40381, 2022.
[196] P. reddy Bommireddy, M. Kumar, Y.-W. Lee, R. Manne, Y. Suh, and S.-H. Park, "Prussian blue analogue Co3 (Co (CN) 6) 2 cuboids as an electrode material for high-performance supercapacitor," J Power Sources, vol. 513, p. 230521, 2021.
[197] J. H. Lee et al., "Prussian blue analogues as platform materials for understanding and developing oxygen evolution reaction electrocatalysts," J Catal, vol. 393, pp. 390-398, 2021.
[198] Y. Feng et al., "Boosting the activity of Prussian-blue analogue as efficient electrocatalyst for water and urea oxidation," Sci Rep-Uk, vol. 9, no. 1, pp. 1-11, 2019.
[199] Y. M. Shi et al., "Hollow Prussian blue analogue/g-C 3 N 4 nanobox for all-solid-state asymmetric supercapacitor," (in English), Chem Eng J, vol. 404, Jan 15 2021.
[200] Y. Ma et al., "High‐Entropy Metal–Organic Frameworks for Highly Reversible Sodium Storage," Advanced Materials, vol. 33, no. 34, p. 2101342, 2021.
[201] J. Xing, Y. Zhang, Y. Jin, and Q. Jin, "Active cation-integration high-entropy Prussian blue analogues cathodes for efficient Zn storage," Nano Research, 2022.
[202] M. Du et al., "High‐Entropy Prussian Blue Analogues and Their Oxide Family as Sulfur Hosts for Lithium‐Sulfur Batteries," Angewandte Chemie, 2022.
[203] C. Zhang et al., "Potassium Prussian blue nanoparticles: a low‐cost cathode material for potassium‐ion batteries," Advanced Functional Materials, vol. 27, no. 4, p. 1604307, 2017.
[204] C. Yan et al., "A low-defect and Na-enriched Prussian blue lattice with ultralong cycle life for sodium-ion battery cathode," Electrochim Acta, vol. 332, p. 135533, 2020.
[205] Z.-Y. Chen, X.-Y. Fu, L.-L. Zhang, B. Yan, and X.-L. Yang, "High-Performance Fe-Based Prussian Blue Cathode Material for Enhancing the Activity of Low-Spin Fe by Cu Doping," Acs Appl Mater Inter, 2022.
[206] P. Zhu, X. Li, H. Yao, and H. Pang, "Hollow cobalt-iron prussian blue analogue nanocubes for high-performance supercapacitors," J Energy Storage, vol. 31, p. 101544, 2020.
[207] X. Shi et al., "A “MOFs plus MOFs” strategy toward Co–Mo 2 N tubes for efficient electrocatalytic overall water splitting," J Mater Chem A, vol. 6, no. 41, pp. 20100-20109, 2018.
[208] Y. Zeng, X. F. Lu, S. L. Zhang, D. Luan, S. Li, and X. W. Lou, "Construction of Co–Mn Prussian Blue Analog Hollow Spheres for Efficient Aqueous Zn‐ion Batteries," Angewandte Chemie International Edition, vol. 60, no. 41, pp. 22189-22194, 2021.
[209] C. Gu et al., "A bimetallic (Cu-Co) Prussian Blue analogue loaded with gold nanoparticles for impedimetric aptasensing of ochratoxin a," Microchimica Acta, vol. 186, no. 6, pp. 1-10, 2019.
[210] Y.-S. Cheng et al., "Synthesis of Cu2O@ Cu-Fe-K Prussian Blue analogue core–shell nanocube for enhanced electroreduction of CO2 to multi-carbon products," Mater Lett, vol. 260, p. 126868, 2020.
[211] L. Ma et al., "Achieving high‐voltage and high‐capacity aqueous rechargeable zinc ion battery by incorporating two‐species redox reaction," Adv Energy Mater, vol. 9, no. 45, p. 1902446, 2019.
[212] Y. Feng et al., "Honeycomb-like ZnO mesoporous nanowall arrays modified with Ag nanoparticles for highly efficient photocatalytic activity," Sci Rep-Uk, vol. 7, no. 1, pp. 1-11, 2017.
[213] S.-C. Wang, M. Gu, L. Pan, J. Xu, L. Han, and F.-Y. Yi, "The interlocked in situ fabrication of graphene@ prussian blue nanocomposite as high-performance supercapacitor," Dalton T, vol. 47, no. 37, pp. 13126-13134, 2018.
[214] Z. Zhang, Y. Cheng, H. Li, Z. Xu, S. Sun, and S. Yin, "Construction of Cu-Doped Ni–Co-Based Electrodes for High-Performance Supercapacitor Applications," ACS Applied Energy Materials, 2022.
[215] N. O. Laschuk, E. B. Easton, and O. V. Zenkina, "Reducing the resistance for the use of electrochemical impedance spectroscopy analysis in materials chemistry," Rsc Adv, vol. 11, no. 45, pp. 27925-27936, 2021.
[216] P. Si, S. Ding, X.-W. D. Lou, and D.-H. Kim, "An electrochemically formed three-dimensional structure of polypyrrole/graphene nanoplatelets for high-performance supercapacitors," Rsc Adv, vol. 1, no. 7, pp. 1271-1278, 2011.
[217] H. Xu, H. Y. Shang, L. J. Jin, C. Y. Chen, C. Wang, and Y. K. Du, "Boosting electrocatalytic oxygen evolution over Prussian blue analog/transition metal dichalcogenide nanoboxes by photo-induced electron transfer," (in English), J Mater Chem A, vol. 7, no. 47, pp. 26905-26910, Dec 21 2019.
[218] M. M. Jiang, X. M. Fan, S. Cao, Z. H. Wang, Z. H. Yang, and W. X. Zhang, "Thermally activated carbon-nitrogen vacancies in double-shelled NiFe Prussian blue analogue nanocages for enhanced electrocatalytic oxygen evolution," (in English), J Mater Chem A, vol. 9, no. 21, pp. 12734-12745, Jun 7 2021.
[219] J. L. Wang, M. L. Zhang, J. H. Li, F. X. Jiao, Y. Lin, and Y. Q. Gong, "A highly efficient electrochemical oxygen evolution reaction catalyst constructed from a S-treated two-dimensional Prussian blue analogue," (in English), Dalton T, vol. 49, no. 40, pp. 14290-14296, Oct 28 2020.
[220] Z. G. Neale, C. Liu, and G. Cao, "Effect of synthesis pH and EDTA on iron hexacyanoferrate for sodium-ion batteries," Sustainable Energy & Fuels, vol. 4, no. 6, pp. 2884-2891, 2020.
[221] J. Liu et al., "Zinc-modulated Fe–Co Prussian blue analogues with well-controlled morphologies for the efficient sorption of cesium," J Mater Chem A, vol. 5, no. 7, pp. 3284-3292, 2017.
[222] J. Kim, S.-H. Yi, L. Li, and S.-E. Chun, "Enhanced stability and rate performance of zinc-doped cobalt hexacyanoferrate (CoZnHCF) by the limited crystal growth and reduced distortion," J Energy Chem, vol. 69, pp. 649-658, 2022.
[223] A. Peeters, P. Valvekens, R. Ameloot, G. Sankar, C. E. A. Kirschhock, and D. E. De Vos, "Zn–Co Double Metal Cyanides as Heterogeneous Catalysts for Hydroamination: A Structure–Activity Relationship," ACS Catal., vol. 3, no. 4, pp. 597-607, 2013/04/05 2013.
[224] S. Jo et al., "Engineering [Fe (CN) 6] 3− vacancy via free-chelating agents in Prussian blue analogues on reduced graphene oxide for efficient oxygen evolution reaction," Appl Surf Sci, vol. 574, p. 151620, 2022.
[225] H. Yang et al., "Unconventional bi-vacancies activating inert Prussian blue analogues nanocubes for efficient hydrogen evolution," Chem Eng J, vol. 420, p. 127671, 2021.
[226] X. Han, D. Zhang, Y. Qin, X. Kong, F. Zhang, and X. Lei, "Construction of Ta-Cu7S4 negative electrode for high-performance all-solid-state asymmetric supercapacitor," Chem Eng J, vol. 403, p. 126471, 2021.
[227] L. Kang et al., "Effect of fluorine doping and sulfur vacancies of CuCo2S4 on its electrochemical performance in supercapacitors," Chem Eng J, vol. 390, p. 124643, 2020.
[228] L. Zhou, C. Zhang, Y. Zhang, Z. Li, and M. Shao, "Host Modification of Layered Double Hydroxide Electrocatalyst to Boost the Thermodynamic and Kinetic Activity of Oxygen Evolution Reaction," Adv. Funct. Mater., vol. 31, no. 15, p. 2009743, 2021.
[229] X. Chu et al., "Cu-Doped Layered Double Hydroxide Constructs the Performance-Enhanced Supercapacitor Via Band Gap Reduction and Defect Triggering," ACS Appl. Energy Mater., vol. 5, no. 2, pp. 2192-2201, 2022/02/28 2022.
[230] W. Liu et al., "Interior and Exterior Decoration of Transition Metal Oxide Through Cu0/Cu+ Co-Doping Strategy for High-Performance Supercapacitor," Nano-Micro Lett., vol. 13, no. 1, p. 61, 2021/01/25 2021.
[231] Z. Wang et al., "Ion-exchange synthesis of high-energy-density prussian blue analogues for sodium ion battery cathodes with fast kinetics and long durability," Journal of Power Sources, vol. 436, p. 226868, 2019.
[232] Y. Kang et al., "[Fe(CN)6] vacancy-boosting oxygen evolution activity of Co-based Prussian blue analogues for hybrid sodium-air battery," Mater. Today Energy, vol. 20, p. 100572, 2021/06/01/ 2021.