[1] [1] LV Z, YUE M, LING M, et al. Controllable design coupled with finite element analysis of low-tortuosity electrode architecture for advanced sodium-ion batteries with ultra-high mass loading[J]. Adv Energy Mater, 2021, 11(17): 2003725.

[2] [2] LV Z, LING M, YUE M, et al. Vanadium-based polyanionic compounds as cathode materials for sodium-ion batteries: Toward high-energy and high-power applications[J]. J Energy Chem, 2021, 55:361–390.

[3] [3] WANG J W, LIU X H, MAO S X, et al. Microstructural evolution of tin nanoparticles during in situ sodium insertion and extraction[J].Nano Lett, 2012, 12(11): 5897–5902.

[4] [4] LIU Y, ZHANG N, JIAO L, et al. Ultrasmall Sn nanoparticles embedded in carbon as high-performance anode for sodium-ion batteries[J]. Adv Functi Mater, 2015, 25(2): 214–220.

[5] [5] FU Y, WEI Q, WANG X, et al. Porous hollow α-Fe2O3@TiO2 core–shell nanospheres for superior lithium/sodium storage capability[J].J Mater Chem A, 2015, 3(26): 13807–13818.

[6] [6] CHANDRA R P, PATRA J, SAIKIA D, et al. Highly enhanced electrochemical performance of ultrafine CuO nanoparticles confined in ordered mesoporous carbons as anode materials for sodium-ion batteries[J]. J Mater Chem A, 2016, 4(37): 14222–14233.

[7] [7] WU Y, LIU Z, ZHONG X, et al. Amorphous red phosphorus embedded in sandwiched porous carbon enabling superior sodium storage performances[J]. Small, 2018, 14(12): e1703472.

[8] [8] ZHOU L, ZHANG K, SHENG J, et al. Structural and chemical synergistic effect of CoS nanoparticles and porous carbon nanorods for high-performance sodium storage[J]. Nano Energy, 2017, 35: 281–289.

[9] [9] FAN L, LI X, YAN B, et al. Controlled SnO2crystallinity effectively dominating sodium storage performance[J]. Adv Energy Mater, 2016,6(10): 1502057.

[10] [10] LI Y, LU Y, MENG Q, et al. Regulating pore structure of hierarchical porous waste cork-derived hard carbon anode for enhanced na storage performance[J]. Adv Energy Mater, 2019, 9(48): 1902852.

[11] [11] MENG Q, LU Y, DING F, et al. Tuning the closed pore structure of hard carbons with the highest na storage capacity[J]. ACS Energy Lett,2019, 4(11): 2608–2612.

[12] [12] WAN Y, QIU Y, WANG C, et al. Enabling superior rate capability and reliable sodium ion batteries by employing galvanostatic-potentiostatic operation mode[J]. J Power Sources, 2021, 496: 229834.

[13] [13] ZHENG X, CAO X, LI X, et al. Biomass lysine-derived nitrogen-doped carbon hollow cubes via a NaCl crystal template: an efficient bifunctional electrocatalyst for oxygen reduction and evolution reactions[J]. Nanoscale, 2017, 9(3): 1059–1067.

[14] [14] SHI R, HAN C, LI H, et al. NaCl-templated synthesis of hierarchical porous carbon with extremely large specific surface area and improved graphitization degree for high energy density lithium ion capacitors[J].J Mater Chem A, 2018, 6(35): 17057–17066.

[15] [15] HE Q, JIANG J, ZHU J, et al. A facile and cost effective synthesis of nitrogen and fluorine Co-doped porous carbon for high performance Sodium ion battery anode material[J]. J Power Sources, 2020, 448:227568.

[16] [16] PEI Z, MENG Q, WEI L, et al. Toward efficient and high rate sodium-ion storage: A new insight from dopant-defect interplay in textured carbon anode materials[J]. Energy Stor Mater, 2020, 28:55–63.

[17] [17] YAN R, LEUS K, HOFMANN J P, et al. Porous nitrogen-doped carbon/carbon nanocomposite electrodes enable sodium ion capacitors with high capacity and rate capability[J]. Nano Energy, 2020, 67:104240.

[18] [18] QIAO Y, HAN R, PANG Y, et al. 3D well-ordered porous phosphorus doped carbon as an anode for sodium storage: Structure design,experimental and computational insights[J]. J Mater Chem A, 2019,7(18): 11400–11407.

[19] [19] LI W, HU S, LUO X, et al. Confined amorphous red phosphorus in MOF-derived N-doped microporous carbon as a superior anode for sodium-ion battery[J]. Adv Mater, 2017, 29(16): 05820.

[20] [20] MAHMOOD A, LI S, ALI Z, et al. Ultrafast sodium/potassium-ion intercalation into hierarchically porous thin carbon shells[J]. Adv Mater, 2019, 31(2): e1805430.

[21] [21] KONG L, ZHU J, SHUANG W, et al. Nitrogen-doped wrinkled carbon foils derived from MOF nanosheets for superior sodium storage[J].Adv Energy Mater, 2018, 8(25): 1801515.

[22] [22] WANG Z, WANG X, BAI Y, et al. Developing an interpenetrated porous and ultrasuperior hard-carbon anode via a promising molten-salt evaporation method[J]. ACS Appl Mater Interf, 2020,12(2): 2481–2489.

[23] [23] CHA W, KIM I Y, LEE J M, et al. Sulfur-doped mesoporous carbon nitride with an ordered porous structure for sodium-ion batteries[J].ACS Appl Mater Interf, 2019, 11(30): 27192–27199.

[24] [24] XIAO F, YANG X, WANG H, et al. Covalent encapsulation of sulfur in a MOF-derived S, N-doped porous carbon host realized via the vapor-infiltration method results in enhanced sodium–sulfur battery performance[J]. Adv Energy Mater, 2020, 10(23): 2000931.

[25] [25] ZOU G, HOU H, GE P, et al. Metal-organic framework-derived materials for sodium energy storage[J]. Small, 2018, 14(3): 1702648.

[26] [26] LU G, WANG H, ZHENG Y, et al. Metal-organic framework derived N-doped CNT@ porous carbon for high-performance sodium- and potassium-ion storage[J]. Electrochimica Acta, 2019, 319: 541–551.

[27] [27] ZHOU X, CHEN L, ZHANG W, et al. Three-Dimensional ordered macroporous metal-organic framework single crystal-derived nitrogen-doped hierarchical porous carbon for high-performance potassium-ion batteries[J]. Nano Lett, 2019, 19(8): 4965–4973.

[28] [28] ATANGANA E C, HUANG H, HONG H, et al. Metal–organicframeworks- engaged formation of Co0.85Se@C nanoboxes embedded in carbon nanofibers film for enhanced potassium-ion storage[J].Energy Stor Mater, 2020, 24: 167–176.

[29] [29] WANG K, XU Y, LI Y, et al. Sodium storage in hard carbon with curved graphene platelets as the basic structural units[J]. J Mater Chem A, 2019, 7(7): 3327–3335.

[30] [30] SUN N, GUAN Z, LIU Y, et al. Extended “Adsorption–insertion”model: A new insight into the sodium storage mechanism of hard carbons[J]. Adv Energy Mater, 2019, 9(32): 1901351.

[31] [31] LI Y, HU Y-S, TITIRICI M-M, et al. Hard carbon microtubes made from renewable cotton as high-performance anode material for sodium-ion batteries[J]. Adv Energy Mater, 2016, 6(18): 1600659.

[32] [32] LV Z, LING M, YI H, et al. Electrode design for high-performance sodium-ion batteries: Coupling nanorod- assembled Na3V2(PO4)3@C microspheres with a 3D conductive charge transport network[J]. ACS Appl Mater Interf, 2020, 12(12): 13869–13877.

[33] [33] ZHENG Y, LU Y, QI X, et al. Superior electrochemical performance of sodium-ion full-cell using poplar wood derived hard carbon anode[J]. Energy Stor Mater, 2019, 18: 269–279.

[34] [34] WANG J, YAN L, REN Q, et al. Facile hydrothermal treatment route of reed straw-derived hard carbon for high performance sodium ion battery[J]. Electrochimica Acta, 2018, 291: 188–196.

[35] [35] ZHENG Y, WANG Y, LU Y. A high-performance sodium-ion battery enhanced by macadamia shell derived hard carbon anode[J]. Nano Energy, 2017, 39: 489–498.

[36] [36] WANG Q, ZHU X, LIU Y, et al. Rice husk-derived hard carbons as high-performance anode materials for sodium-ion batteries[J]. Carbon,2018, 127: 658–666.

[37] [37] ZHANG Y, LI X, DONG P, et al. Honeycomb-like hard carbon derived from pine pollen as high-performance anode material for sodium-ion batteries[J]. ACS Appl Mater Interf, 2018, 10(49):42796–42803.

[38] [38] SHAN C, FENG X, YANG J, et al. Hierarchical porous carbon pellicles: Electrospinning synthesis and applications as anodes for sodium-ion batteries with an outstanding performance[J]. Carbon, 2020,157: 308–315.

[39] [39] WU F, ZHANG M, BAI Y, et al. Lotus seedpod-derived hard carbon with hierarchical porous structure as stable anode for sodium-ion batteries[J]. ACS Appl Mater Interfaces, 2019, 11(13): 12554–12561.

[40] [40] WANG Z, WANG X, BAI Y, et al. Developing an interpenetrated porous and ultrasuperior hard-carbon anode via a promising molten-salt evaporation method[J]. ACS Appl Mater Interfaces, 2020,12(2): 2481–2489.

[41] [41] JIN Q, WANG K, FENG P, et al. Surface-dominated storage of heteroatoms-doping hard carbon for sodium-ion batteries[J]. Energy Storage Mater, 2020, 27: 43–50.

[42] [42] ZHU Z, CHENG F, HU Z, et al. Highly stable and ultrafast electrode reaction of graphite for sodium ion batteries[J]. J Power Sources, 2015,293: 626–634.

[43] [43] KIM H, HONG J, PARK Y-U, et al. Sodium storage behavior in natural graphite using ether-based electrolyte systems[J]. Adv Funct Mater, 2015, 25(4): 534–541.

[44] [44] JAHE B, ADELHELM P. Use of graphite as a highly reversible electrode with superior cycle life for sodium-ion batteries by making use of co-intercalation phenomena[J]. Angew Chem Int Ed Engl, 2014,53(38): 10169–10173.

[45] [45] XIA J L, YANG D, GUO L P, et al. Hard carbon nanosheets with uniform ultramicropores and accessible functional groups showing high realistic capacity and superior rate performance for sodium-ion storage[J]. Adv Mater, 2020, 32(21): e2000447.