[1]	Sun X, Gao J, Wang C, et al. A hybrid ZnO/Si/porous-carbon anode for high performance lithium ion battery. Chem Eng J. 2020;383:123198.

[2]	Dai Y, Liao X, Yu R, et al. Quicker and more Zn2+ storage predominantly from the interface. Adv Mater. 2021;33(26):2100359.

[3]	Zhu J, Xia L, Yu R, et al. Ultrahigh stable methanol oxidation enabled by a high hydroxyl concentration on Pt clusters/MXene interfaces. J Am Chem Soc. 2022;144(34):15529-15538.

[4]	Zhang W, Li H, Zhang Z, Xu M, Lai Y, Chou SL. Full activation of Mn4+/Mn3+ redox in Na4MnCr (PO4)3 as a high-voltage and high-rate cathode material for sodium-ion batteries. Small. 2020;16(25):2001524.

[5]	Chen S, Zhang Z, Jiang W, et al. Engineering water molecules activation center on multisite electrocatalysts for enhanced CO2 methanation. J Am Chem Soc. 2022;144(28):12807-12815.

[6]	Zhuang Z, Xia L, Huang J, et al. Continuous modulation of electrocatalytic oxygen reduction activities of single-atom catalysts through p-n junction rectification. Angew Chem. 2023;135(5):e202212335.

[7]	Zhang Z, Zhu J, Chen S, Sun W, Wang D. Liquid fluxional Ga single atom catalysts for efficient electrochemical CO2 reduction. Angew Chem. 2023;135(3):e202215136.

[8]	Zong W, Rao D, Guo H, et al. Gradient phosphorus-doping engineering and superficial amorphous reconstruction in NiFe2O4 nanoarrays to enhance the oxygen evolution electrocatalysis. Nanoscale. 2020;12(20):10977-10986.

[9]	Hopkins BJ, Sassin MB, Chervin CN, et al. Fabricating architected zinc electrodes with unprecedented volumetric capacity in rechargeable alkaline cells. Energy Storage Mater. 2020;27:370-376.

[10]	Dong H, Li J, Guo J, et al. Insights on flexible zinc-ion batteries from lab research to commercialization. Adv Mater. 2021;33(20):2007548.

[11]	Zong W, Yang C, Mo L, et al. Elucidating dual-defect mechanism in rhenium disulfide nanosheets with multi-dimensional ion transport channels for ultrafast sodium storage. Nano Energy. 2020;77:105189.

[12]	Zhang W, Dai Y, Chen R, et al. Highly reversible zinc metal anode in a dilute aqueous electrolyte enabled by a pH buffer additive. Angew Chem Int Ed. 2023;62(5):e202212695.

[13]	Gao X, Sun X, Liu J, Gao N, Li H. A carbon-based anode combining with SiO and nanodiamond for high performance lithium ion battery. J Energy Storage. 2019;25:100901.

[14]	Chen R, Li X, Huang Q, Ling H, Yang Y, Wang X. Self-assembled porous biomass carbon/RGO/nanocellulose hybrid aerogels for self-supporting supercapacitor electrodes. Chem Eng J. 2021;412:128755.

[15]	Chen R, Tang H, Dai Y, et al. Robust bioinspired MXene–hemicellulose composite films with excellent electrical conductivity for multifunctional electrode applications. ACS Nano. 2022;16(11):19124-19132.

[16]	Yu K, Zhang H, Qi H, Gao X, Liang J, Liang C. Rice husk as the source of silicon/carbon anode material and stable electrochemical performance. ChemistrySelect. 2018;3(19):5439-5444.

[17]	Zhu C, Schorr NB, Qi Z, et al. Direct ink writing of 3D Zn structures as high-capacity anodes for rechargeable alkaline batteries. Small Struct. 2022:2200323.

[18]	Zhang W, Wu Y, Xu Z, et al. Rationally designed sodium chromium vanadium phosphate cathodes with multi-electron reaction for fast-charging sodium-ion batteries. Adv Energy Mater. 2022;12(25):2201065.

[19]	Zhang W, Xu Z, Li H, et al. All-climate and air-stable NASICON-Na2TiV(PO4)3 cathode with three-electron reaction toward high-performance sodium-ion batteries. Chem Eng J. 2022;433:133542.

[20]	Ouyang Y, Zong W, Zhu X, et al. A universal spinning-coordinating strategy to construct continuous metal-nitrogen-carbon heterointerface with boosted lithium polysulfides immobilization for 3D-printed Li-S batteries. Adv Sci. 2022;9(26):2203181.

[21]	Gao X, Sun X, Jiang Z, et al. Introducing nanodiamond into TiO2-based anode for improving the performance of lithium-ion batteries. New J Chem. 2019;43(9):3907-3912.

[22]	Zhu J, Tang C, Zhuang Z, et al. Porous and low-crystalline manganese silicate hollow spheres wired by graphene oxide for high-performance lithium and sodium storage. ACS Appl Mater Interfaces. 2017;9(29):24584-24590.

[23]	Dong H, Li J, Zhao S, et al. Investigation of a biomass hydrogel electrolyte naturally stabilizing cathodes for zinc-ion batteries. ACS Appl Mater Interfaces. 2021;13(1):745-754.

[24]	Dong H, Li J, Zhao S, et al. An anti-aging polymer electrolyte for flexible rechargeable zinc-ion batteries. J Mater Chem A. 2020;8(43):22637-22644.

[25]	Liu Y, Lu X, Lai F, et al. Rechargeable aqueous Zn-based energy storage devices. Joule. 2021;5(11):2845-2903.

[26]	Liu Y, He G, Jiang H, Parkin IP, Shearing PR, Brett DJL. Cathode design for aqueous rechargeable multivalent ion batteries: challenges and opportunities. Adv Funct Mater. 2021;31(13):2010445.

[27]	Zhang Q, Ma C, Song N-J, Zhao Y, Li Y. A facile ball milling-catalytic pyrolysis preparation of Si-Nss@C/Ng composite for lithium storage. Ng Composite for Lithium Storage.

[28]	Chao D, Zhou W, Ye C, et al. An electrolytic Zn–MnO2 battery for high-voltage and scalable energy storage. Angew Chem. 2019;131(23):7905-7910.

[29]	Alfaruqi MH, Mathew V, Song J, et al. Electrochemical zinc intercalation in lithium vanadium oxide: a high-capacity zinc-ion battery cathode. Chem Mater. 2017;29(4):1684-1694.

[30]	Dai Y, Li J, Chen L, et al. Generating H+ in catholyte and OH– in anolyte: an approach to improve the stability of aqueous zinc-ion batteries. ACS Energy Lett. 2021;6(2):684-686.

[31]	Zhu S, Dai Y, Li J, et al. Cathodic Zn underpotential deposition: an evitable degradation mechanism in aqueous zinc-ion batteries. Sci Bull. 2022;67(18):1882-1889.

[32]	He H, Tong H, Song X, Song X, Liu J. Highly stable Zn metal anodes enabled by atomic layer deposited Al2O3 coating for aqueous zinc-ion batteries. J Mater Chem A. 2020;8(16):7836-7846.

[33]	Ruan P, Liang S, Lu B, Fan HJ, Zhou J. Design strategies for high-energy-density aqueous zinc batteries. Angew Chem Int Ed. 2022;61(17):e202200598.

[34]	Zhang W, He G. Solid-electrolyte interphase chemistries towards high-performance aqueous zinc metal batteries. Angew Chem Int Ed. 2023:e202218466.

[35]	Yang Q, Liu Q, Ling W, et al. Porous electrode materials for Zn-ion batteries: from fabrication and electrochemical application. Batteries. 2022;8(11):223.

[36]	Gao X, Zhang C, Dai Y, et al. Three-dimensional manganese oxide@ carbon networks as free-standing, high-loading cathodes for high-performance zinc-ion batteries. Small Struct. 2023;4(5):2200316.

[37]	Yan W, Cai X, Tan F, Liang J, Zhao J, Tan C. 3D printing flexible zinc-ion microbatteries with ultrahigh areal capacity and energy density for wearable electronics. Chem Commun. 2023;59:1661-1664.

[38]	Liu P, Liu W, Liu K. Rational modulation of emerging MXene materials for zinc-ion storage. Carbon Energy. 2022;4(1):60-76.

[39]	Gao W, Michalička J, Pumera M. Hierarchical atomic layer deposited V2O5 on 3D printed nanocarbon electrodes for high-performance aqueous zinc-ion batteries. Small. 2022;18(1):2105572.

[40]	Zeng L, He H, Chen H, Luo D, He J, Zhang C. 3D printing architecting reservoir-integrated anode for dendrite-free, safe, and durable Zn batteries. Adv Energy Mater. 2022;12(12):2103708.

[41]	Liu Y, Zheng S, Ma J, et al. All 3D printing shape-conformable zinc ion hybrid capacitors with ultrahigh areal capacitance and improved cycle life. Adv Energy Mater. 2022;12(27):2200341.

[42]	Gan H, Wu J, Zhang F, Li R, Liu H. Uniform Zn2+ distribution and deposition regulated by ultrathin hydroxyl-rich silica ion sieve in zinc metal anodes. Energy Storage Mater. 2023;55:264-271.

[43]	He H, Luo D, Zeng L, et al. 3D printing of fast kinetics reconciled ultra-thick cathodes for high areal energy density aqueous Li–Zn hybrid battery. Sci Bull. 2022;67(12):1253-1263.

[44]	Dong H, Liu R, Hu X, et al. Cathode–electrolyte interface modification by binder engineering for high-performance aqueous zinc-ion batteries. Adv Sci. 2022;10(4):2205084.

[45]	Wang Y, Li L, Wang Y, Shi H, Wang L, Huang Q. Electrooxidation of perfluorooctanesulfonic acid on porous Magnéli phase titanium suboxide anodes: impact of porous structure and composition. Chem Eng J. 2022;431:133929.

[46]	Zong W, Ouyang Y, Miao Y-E, Liu T, Lai F. Recent advances and perspectives of 3D printed micro-supercapacitors: from design to smart integrated devices. Chem Commun. 2022;58(13):2075-2095.

[47]	Wang L, Feng J, Jiang Y, et al. Ultraviolet-assisted direct-write printing strategy towards polyorganosiloxane-based aerogels with freeform geometry and outstanding thermal insulation performance. Chem Eng J. 2022;455:140818.

[48]	Lu B, Li D, Tian X. Development trends in additive manufacturing and 3D printing. Engineering. 2015;1(1):85-89.

[49]	Egorov V, Gulzar U, Zhang Y, Breen S, O'Dwyer C. Evolution of 3D printing methods and materials for electrochemical energy storage. Adv Mater. 2020;32(29):2000556.

[50]	Lai F, Yang C, Lian R, et al. Three-phase boundary in cross-coupled micro-mesoporous networks enabling 3D-printed and ionogel-based quasi-solid-state micro-supercapacitors. Adv Mater. 2020;32(40):2002474.

[51]	Al Ahbabi KJA, Alrashdi MMS, Ahmed WK. The capabilities of 3D printing technology in the production of battery energy storage system. 6th International Conference on Renewable Energy: Generation and Applications (ICREGA), 2021:211-216.

[52]	Wang Z, Winslow R, Madan D, et al. Development of MnO2 cathode inks for flexographically printed rechargeable zinc-based battery. J Power Sources. 2014;268:246-254.

[53]	Hung J-L, Zhang K. Examining mobile learning trends 2003–2008: a categorical meta-trend analysis using text mining techniques. J Comput High Educ. 2012;24(1):1-17.

[54]	Donthu N, Kumar S, Mukherjee D, Pandey N, Lim WM. How to conduct a bibliometric analysis: an overview and guidelines. J Bus Res. 2021;133:285-296.

[55]	Zyoud SH, Al-Jabi SW, Sweileh WM, Awang R. A bibliometric analysis of toxicology research productivity in Middle Eastern Arab countries during a 10-year period (2003–2012). Health Res Policy Syst. 2014;12(1):1-13.

[56]	Li CZ, Hong J, Xue F, Shen GQ, Xu X, Mok MK. Schedule risks in prefabrication housing production in Hong Kong: a social network analysis. J Clean Prod. 2016;134:482-494.

[57]	Ye Q, Song H, Li T. Cross-institutional collaboration networks in tourism and hospitality research. Tour Manag Perspect. 2012;2-3:55-64.

[58]	Diamond HJ, Karl TR, Palecki MA, et al. US climate reference network after one decade of operations: status and assessment. Bull Am Meteorol Soc. 2013;94(4):485-498.

[59]	Chu T, Park S, Fu K. 3D printing-enabled advanced electrode architecture design. Carbon Energy. 2021;3(3):424-439.

[60]	Jha S, Velhal M, Stewart W, Amin V, Wang E, Liang H. Additively manufactured electrodes for supercapacitors: a review. Appl Mater Today. 2021;26:101220.

[61]	Chen R, Chen Y, Xu L, et al. 3D-printed interdigital electrodes for electrochemical energy storage devices. J Mater Res. 2021;36(22):4489-4507.

[62]	Cheng M, Jiang Y. 3D-printed solid-state electrolytes for electrochemical energy storage devices. J Mater Res. 2021;36:4547-4564.

[63]	Tian X, Xu B. 3D printing for solid-state energy storage. Small Methods. 2021;5(12):2100877.

[64]	Zhu Y, Qin J, Shi G, et al. A focus review on 3D printing of wearable energy storage devices. Carbon Energy. 2022;4(6):1242-1261.

[65]	Kumar S, Kumar S, Goswami M, et al. 3D printing for energy storage devices and applications. In: Muralidhara HB, Banerjee S, eds. 3D Printing Technology and Its Diverse Applications. CRC Press; 2021:117-140.

[66]	Xiao J, Ji G, Zhang Y, et al. Large-scale 3D printing concrete technology: current status and future opportunities. Cem Concr Compos. 2021;122:104115.

[67]	Goh GL, Zhang H, Chong TH, Yeong WY. 3D printing of multilayered and multimaterial electronics: a review. Adv Electron Mater. 2021;7(10):2100445.

[68]	Elbadawi M, McCoubrey LE, Gavins FKH, et al. Disrupting 3D printing of medicines with machine learning. Trends Pharmacol Sci. 2021;42(9):745-757.

[69]	Wang X, Zhang M, Zhang L, Xu J, Xiao X, Zhang X. Inkjet-printed flexible sensors: from function materials, manufacture process, and applications perspective. Mater Today Commun. 2022;31:103263.

[70]	Tan HW, Choong YYC, Kuo CN, Low HY, Chua CK. 3D printed electronics: processes, materials and future trends. Prog Mater Sci. 2022;127:100945.

[71]	Lanaro M, Desselle MR, Woodruff MA. 3D printing chocolate: properties of formulations for extrusion, sintering, binding and ink jetting. In: Godoi FC, Bhandari BR, Prakash S, Zhang M, eds. Fundamentals of 3D Food Printing and Applications. Elsevier; 2019:151-173.

[72]	Le Néel TA, Mognol P, Hascoët J-Y. A review on additive manufacturing of sand molds by binder jetting and selective laser sintering. Rapid Prototyp J. 2018;24(8):1325-1336.

[73]	Li M, Du W, Elwany A, Pei Z, Ma C. Metal binder jetting additive manufacturing: a literature review. J Manuf Sci Eng. 2020;142(9):090801.

[74]	Lewis JA. Direct ink writing of 3D functional materials. Adv Funct Mater. 2006;16(17):2193-2204.

[75]	Shahzad A, Lazoglu I. Direct ink writing (DIW) of structural and functional ceramics: recent achievements and future challenges. Compos B Eng. 2021;225:109249.

[76]	Awasthi P, Banerjee SS. Fused deposition modeling of thermoplastic elastomeric materials: challenges and opportunities. Addit Manuf. 2021;46:102177.

[77]	Deckard CR. Selective Laser Sintering. The University of Texas at Austin; 1988.

[78]	Gibson I, Rosen D, Stucker B. Directed energy deposition processes. In: Stampfl J, Hatzenbichler M, eds. Additive Manufacturing Technologies. Springer; 2015:245-268.

[79]	Melchels FPW, Feijen J, Grijpma DW. A review on stereolithography and its applications in biomedical engineering. Biomaterials. 2010;31(24):6121-6130.

[80]	Rubio CD, Weber W, Klotzsch E. Maasi: a 3D printed spin coater with touchscreen. HardwareX. 2022;11:e00316.

[81]	Chi Q-Z, Mu L-Z, He Y, Luan Y, Jing Y-C. A brush–spin–coating method for fabricating in vitro patient-specific vascular models by coupling 3D-printing. Cardiovasc Eng Technol. 2021;12:200-214.

[82]	Sun K, Wei TS, Ahn BY, Seo JY, Dillon SJ, Lewis JA. 3D printing of interdigitated Li-ion microbattery architectures. Adv Mater. 2013;25(33):4539-4543.

[83]	Zong W, Guo H, Ouyang Y, et al. Topochemistry-driven synthesis of transition-metal selenides with weakened van der Waals force to enable 3D-printed Na-ion hybrid capacitors. Adv Funct Mater. 2022;32(13):2110016.

[84]	Zong W, Chui N, Tian Z, et al. Ultrafine MoP nanoparticle splotched nitrogen-doped carbon nanosheets enabling high-performance 3D-printed potassium-ion hybrid capacitors. Adv Sci. 2021;8(7):2004142.

[85]	Chen J, Ding Y, Yan D, Huang J, Peng S. Synthesis of MXene and its application for zinc-ion storage. SusMat. 2022;2(3):293-318.

[86]	Zhang X, Wang L, Fu H. Recent advances in rechargeable Zn-based batteries. J Power Sources. 2021;493:229677.

[87]	Ponnada S, Gorle DB, Bose RSC, et al. Current insight into 3D printing in solid-state lithium-ion batteries: a perspective. Batteries Supercaps. 2022;5(8):e202200223.

[88]	Zhu K, Wu T, Sun S, Wen Y, Huang K. Electrode materials for practical rechargeable aqueous Zn-ion batteries: challenges and opportunities. ChemElectroChem. 2020;7(13):2714-2734.

[89]	Bi J, Zhang J, Giannakou P, et al. A highly integrated flexible photo-rechargeable system based on stable ultrahigh-rate quasi-solid-state zinc-ion micro-batteries and perovskite solar cells. Energy Storage Mater. 2022;51:239-248.

[90]	Lin D, Li Y. Recent advances of aqueous rechargeable zinc-iodine batteries: challenges, solutions, and prospects. Adv Mater. 2022;34(23):2108856.

[91]	Tang H, Yao J, Zhu Y. Recent developments and future prospects for zinc-ion hybrid capacitors: a review. Adv Energy Mater. 2021;11(14):2003994.

[92]	Fan Z, Jin J, Li C, et al. 3D-printed Zn-ion hybrid capacitor enabled by universal divalent cation-gelated additive-free Ti3C2 MXene ink. ACS Nano. 2021;15(2):3098-3107.

[93]	Bogue R. 3D printing: the dawn of a new era in manufacturing? Assembly Automation. 2013;33(4):307-311.

[94]	Praveena B, Lokesh N, Buradi A, Santhosh N, Praveena B, Vignesh R. A comprehensive review of emerging additive manufacturing (3D printing technology): methods, materials, applications, challenges, trends and future potential. Mater Today Proc. 2022;52:1309-1313.

[95]	Bozkurt Y, Karayel E. 3D printing technology; methods, biomedical applications, future opportunities and trends. J Mater Res Technol. 2021;14:1430-1450.

[96]	Mo F, Guo B, Ling W, et al. Recent progress and challenges of flexible Zn-based batteries with polymer electrolyte. Batteries. 2022;8(6):59.

[97]	Campos AR, Vila MN, Haddad M, et al. Facile electrodeposition and aging to generate 3-dimensional α-MnO2 battery cathodes. J Electrochem Soc. 2022;169(10):100516.

[98]	Yao B, Chandrasekaran S, Zhang J, et al. Efficient 3D printed pseudocapacitive electrodes with ultrahigh MnO2 loading. Joule. 2019;3(2):459-470.

[99]	Hertzberg BJ, Huang A, Hsieh A, et al. Effect of multiple cation electrolyte mixtures on rechargeable Zn–MnO2 alkaline battery. Chem Mater. 2016;28(13):4536-4545.

[100]

Huang J, Xie X, Liu K, Liang S, Fang G. Perspectives in electrochemically in-situ structural reconstruction of cathode materials for multivalent-ion storage. Energy Environ Mater. 2023;6(1):e12309.

[101]

Costa CM, Gonçalves R, Lanceros-Méndez S. Recent advances and future challenges in printed batteries. Energy Storage Mater. 2020;28:216-234.

[102]

Percin K, Rommerskirchen A, Sengpiel R, Gendel Y, Wessling M. 3D-printed conductive static mixers enable all-vanadium redox flow battery using slurry electrodes. J Power Sources. 2018;379:228-233.

[103]

Ambrosi A, Webster RD. 3D printing for aqueous and non-aqueous redox flow batteries. Curr Opin Electrochem. 2020;20:28-35.

[104]

Li Q, Dong Q, Wang J, et al. Direct ink writing (DIW) of graphene aerogel composite electrode for vanadium redox flow battery. J Power Sources. 2022;542:231810.

[105]

Katic V, Dos Santos PL, Dos Santos MF, et al. 3D printed graphene electrodes modified with prussian blue: emerging electrochemical sensing platform for peroxide detection. ACS Appl Mater Interfaces. 2019;11(38):35068-35078.

[106]

Bishop GW, Satterwhite JE, Bhakta S, et al. 3D-printed fluidic devices for nanoparticle preparation and flow-injection amperometry using integrated Prussian blue nanoparticle-modified electrodes. Anal Chem. 2015;87(10):5437-5443.

[107]

Zambiazi P, de Moraes A, Kogachi R, Aparecido G, Formiga A, Bonacin J. Performance of water oxidation by 3D printed electrodes modified by Prussian blue analogues. J Braz Chem Soc. 2020;31(11):2307-2318.

[108]

Zhang N, Chen X, Yu M, Niu Z, Cheng F, Chen J. Materials chemistry for rechargeable zinc-ion batteries. Chem Soc Rev. 2020;49(13):4203-4219.

[109]

Agiorgousis ML, Sun Y-Y, West D, Zhang S. Intercalated Chevrel phase Mo6S8 as a Janus material for energy generation and storage. ACS Appl Energy Mater. 2018;1(2):440-446.

[110]

Sharma S, Adalati R, Sharma M, et al. Single-step fabrication of di-titanium nitride thin-film flexible and biocompatible supercapacitor. Ceram Int. 2022;48(23):34678-34687.

[111]

Thong PT, Sadhasivam T, Kim N-I, Kim YA, Roh S-H, Jung H-Y. Highly conductive current collector for enhancing conductivity and power supply of flexible thin-film Zn–MnO2 battery. Energy. 2021;221:119856.

[112]

Zhou J, Xie M, Wu F, et al. Ultrathin surface coating of nitrogen-doped graphene enables stable zinc anodes for aqueous zinc-ion batteries. Adv Mater. 2021;33(33):2101649.

[113]

Feng J, Fang D, Yang Z, et al. A novel P2/O3 composite cathode toward synergistic electrochemical optimization for sodium ion batteries. J Power Sources. 2023;553:232292.

[114]

Yadav P, Kumari N, Rai AK. A review on solutions to overcome the structural transformation of manganese dioxide-based cathodes for aqueous rechargeable zinc ion batteries. J Power Sources. 2023;555:232385.

[115]

Wang X, Zheng S, Zhou F, et al. Scalable fabrication of printed Zn//MnO2 planar micro-batteries with high volumetric energy density and exceptional safety. Natl Sci Rev. 2020;7(1):64-72.

[116]

Fegade U, Jethave G, Khan F, et al. Recent development of aqueous zinc-ion battery cathodes and future challenges. Int J Energy Res. 2022;46(10):13152-13177.

[117]

Yang J, Yin B, Sun Y, et al. Zinc anode for mild aqueous zinc-ion batteries: challenges, strategies, and perspectives. Nano Micro Lett. 2022;14(1):42.

[118]

Mohajerani S, Wang G. “Touch-aware” contact model for peridynamics modeling of granular systems. Int J Numer Meth Eng. 2022;123(17):3850-3878.

[119]

Ayoola OM, Buldum A, Farhad S, Ojo SA. A review on the molecular modeling of argyrodite electrolytes for all-solid-state lithium batteries. Energies. 2022;15(19):7288.

[120]

Li M, Zhou S, Cheng L, et al. 3D printed supercapacitor: techniques, materials, designs, and applications. Adv Funct Mater. 2022;33(1):2208034.

[121]

Zhang S, Liu Y, Hao J, Wallace GG, Beirne S, Chen J. 3D-printed wearable electrochemical energy devices. Adv Funct Mater. 2022;32(3):2103092.

[122]

Lyu Z, Lim GJH, Koh JJ, et al. Design and manufacture of 3D-printed batteries. Joule. 2021;5(1):89-114.

[123]

Guo B, Liang G, Yu S, Wang Y, Zhi C, Bai J. 3D printing of reduced graphene oxide aerogels for energy storage devices: a paradigm from materials and technologies to applications. Energy Storage Mater. 2021;39:146-165.

[124]

Ren Y, Meng F, Zhang S, et al. CNT@ MnO2 composite ink toward a flexible 3D printed micro-zinc-ion battery. Carbon Energy. 2022;4(3):446-457.

[125]

Parker JF, Chervin CN, Pala IR, et al. Rechargeable nickel–3D zinc batteries: an energy-dense, safer alternative to lithium-ion. Science. 2017;356(6336):415-418.

[126]

Zhang G, Zhang X, Liu H, Li J, Chen Y, Duan H. 3D-printed multi-channel metal lattices enabling localized electric-field redistribution for dendrite-free aqueous Zn ion batteries. Adv Energy Mater. 2021;11(19):2003927.