REFERENCES

1. Gong Y, Li Y, Li Y, Liu M, Bai Y, Wu C. Metal selenides anode materials for sodium ion batteries: synthesis, modification, and application. Small 2023;19:e2206194.

2. Dunn B, Kamath H, Tarascon JM. Electrical energy storage for the grid: a battery of choices. Science 2011;334:928-35.

3. Palacín MR. Recent advances in rechargeable battery materials: a chemist’s perspective. Chem Soc Rev 2009;38:2565-75.

4. Armand M, Tarascon JM. Building better batteries. Nature 2008;451:652-7.

5. Feng X, Bai Y, Liu M, et al. Untangling the respective effects of heteroatom-doped carbon materials in batteries, supercapacitors and the ORR to design high performance materials. Energy Environ Sci 2021;14:2036-89.

6. Yang Z, Zhang J, Kintner-Meyer MC, et al. Electrochemical energy storage for green grid. Chem Rev 2011;111:3577-613.

7. Whittingham MS. Lithium batteries and cathode materials. Chem Rev 2004;104:4271-301.

8. Jeong G, Kim YU, Kim H, Kim YJ, Sohn HJ. Prospective materials and applications for Li secondary batteries. Energy Environ Sci 2011;4:1986-2002.

9. Wang Z, Yang H, Liu Y, et al. Analysis of the stable interphase responsible for the excellent electrochemical performance of graphite electrodes in sodium-ion batteries. Small 2020;16:e2003268.

10. Kim SW, Seo DH, Ma X, Ceder G, Kang K. Electrode materials for rechargeable sodium-ion batteries: potential alternatives to current lithium-ion batteries. Adv Energy Mater 2012;2:710-21.

11. Luo W, Shen F, Bommier C, Zhu H, Ji X, Hu L. Na-ion battery anodes: materials and electrochemistry. ACC Chem Res 2016;49:231-40.

12. Li Y, Wu F, Li Y, et al. Ether-based electrolytes for sodium ion batteries. Chem Soc Rev 2022;51:4484-536.

13. Jin T, Li H, Zhu K, Wang PF, Liu P, Jiao L. Polyanion-type cathode materials for sodium-ion batteries. Chem Soc Rev 2020;49:2342-77.

14. Ren H, Li Y, Ni Q, Bai Y, Zhao H, Wu C. Unraveling anionic redox for sodium layered oxide cathodes: breakthroughs and perspectives. Adv Mater 2022;34:e2106171.

15. Hwang JY, Myung ST, Sun YK. Sodium-ion batteries: present and future. Chem Soc Rev 2017;46:3529-614.

16. Bruce PG, Scrosati B, Tarascon JM. Nanomaterials for rechargeable lithium batteries. Angew Chem Int Ed 2008;47:2930-46.

17. Fang Y, Luan D, Gao S, Lou XWD. Rational design and engineering of one-dimensional hollow nanostructures for efficient electrochemical energy storage. Angew Chem Int Ed 2021;60:20102-18.

18. Hasa I, Hassoun J, Passerini S. Nanostructured Na-ion and Li-ion anodes for battery application: a comparative overview. Nano Res 2017;10:3942-69.

19. Zhou L, Zhang K, Hu Z, et al. Recent developments on and prospects for electrode materials with hierarchical structures for lithium-ion batteries. Adv Energy Mater 2018;8:1701415.

20. Tiwari JN, Tiwari RN, Kim KS. Zero-dimensional, one-dimensional, two-dimensional and three-dimensional nanostructured materials for advanced electrochemical energy devices. Prog Mater Sci 2012;57:724-803.

21. Cui H, Guo Y, Ma W, Zhou Z. 2D materials for electrochemical energy storage: design, preparation, and application. ChemSusChem 2020;13:1155-71.

22. Chen R, Zhao T, Zhang X, Li L, Wu F. Advanced cathode materials for lithium-ion batteries using nanoarchitectonics. Nanoscale Horiz 2016;1:423-44.

23. Liang J, Kou H, Ding S. Complex hollow bowl-like nanostructures: synthesis, application, and perspective. Adv Funct Mater 2021;31:2007801.

24. Mei J, Wang T, Qi D, et al. Three-dimensional fast Na-ion transport in sodium titanate nanoarchitectures via engineering of oxygen vacancies and bismuth substitution. ACS Nano 2021;15:13604-15.

25. Yu L, Hu H, Wu HB, Lou XW. Complex hollow nanostructures: synthesis and energy-related applications. Adv Mater 2017;29:1604563.

26. Jiang J, Nie G, Nie P, et al. Nanohollow carbon for rechargeable batteries: ongoing progresses and challenges. Nanomicro Lett 2020;12:183.

27. Xie F, Zhang L, Ye C, Jaroniec M, Qiao SZ. The application of hollow structured anodes for sodium-ion batteries: from simple to complex systems. Adv Mater 2019;31:e1800492.

28. Wu C, Tong X, Ai Y, et al. A review: enhanced anodes of Li/Na-ion batteries based on yolk-shell structured nanomaterials. Nanomicro Lett 2018;10:40.

29. Lu W, Guo X, Luo Y, Li Q, Zhu R, Pang H. Core-shell materials for advanced batteries. Chem Eng J 2019;355:208-37.

30. Su L, Jing Y, Zhou Z. Li ion battery materials with core-shell nanostructures. Nanoscale 2011;3:3967-83.

31. Wei Q, Xiong F, Tan S, et al. Porous one-dimensional nanomaterials: design, fabrication and applications in electrochemical energy storage. Adv Mater 2017;29:1602300.

32. Tian W, Zhang H, Duan X, Sun H, Shao G, Wang S. Porous carbons: structure-oriented design and versatile applications. Adv Funct Mater 2020;30:1909265.

33. Li J, Cao C, Xu X, Zhu Y, Yao R. LiNi_1/3Co_1/3Mn_1/3O₂ hollow nano-micro hierarchical microspheres with enhanced performances as cathodes for lithium-ion batteries. J Mater Chem A 2013;1:11848-52.

34. Zhu Z, Wang S, Du J, et al. Ultrasmall Sn nanoparticles embedded in nitrogen-doped porous carbon as high-performance anode for lithium-ion batteries. Nano Lett 2014;14:153-7.

35. Zhang M, Li Y, Wu F, Bai Y, Wu C. Boost sodium-ion batteries to commercialization: strategies to enhance initial coulombic efficiency of hard carbon anode. Nano Energy 2021;82:105738.

36. Liu Y, Merinov BV, Goddard WA 3rd. Origin of low sodium capacity in graphite and generally weak substrate binding of Na and Mg among alkali and alkaline earth metals. Proc Natl Acad Sci USA 2016;113:3735-9.

37. Dong R, Zheng L, Bai Y, et al. Elucidating the mechanism of fast Na storage kinetics in ether electrolytes for hard carbon anodes. Adv Mater 2021;33:e2008810.

38. Dong R, Wu F, Bai Y, et al. Tailoring defects in hard carbon anode towards enhanced Na storage performance. Energy Mater Adv 2022;2022:9896218.

39. Ge P, Fouletier M. Electrochemical intercalation of sodium in graphite. Solid State Ion 1988;28-30:1172-5.

40. Jache 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. Angew Chem Int Ed 2014;53:10169-73.

41. Stevens DA, Dahn JR. High capacity anode materials for rechargeable sodium-ion batteries. J Electrochem Soc 2000;147:1271-3.

42. Wu F, Liu L, Yuan Y, et al. Expanding interlayer spacing of hard carbon by natural K⁺ doping to boost Na-ion storage. ACS Appl Mater Interfaces 2018;10:27030-8.

43. Yu K, Zhao H, Wang X, et al. Hyperaccumulation route to Ca-rich hard carbon materials with cation self-incorporation and interlayer spacing optimization for high-performance sodium-ion batteries. ACS Appl Mater Interfaces 2020;12:10544-53.

44. Wu F, Zhang M, Bai Y, Wang X, Dong R, Wu C. Lotus seedpod-derived hard carbon with hierarchical porous structure as stable anode for sodium-ion batteries. ACS Appl Mater Interfaces 2019;11:12554-61.

45. Yu K, Wang X, Yang H, Bai Y, Wu C. Insight to defects regulation on sugarcane waste-derived hard carbon anode for sodium-ion batteries. J Energy Chem 2021;55:499-508.

46. Wang N, Chu C, Xu X, et al. Comprehensive new insights and perspectives into Ti-based anodes for next-generation alkaline metal (Na⁺, K⁺) ion batteries. Adv Energy Mater 2018;8:1801888.

47. Dong S, Lv N, Wu Y, Zhang Y, Zhu G, Dong X. Titanates for sodium-ion storage. Nano Today 2022;42:101349.

48. Ni Q, Dong R, Bai Y, et al. Superior sodium-storage behavior of flexible anatase TiO₂ promoted by oxygen vacancies. Energy Stor Mater 2020;25:903-11.

49. Li Y, Zhang R, Qian J, et al. Construct NiSe/NiO heterostructures on NiSe anode to induce fast kinetics for sodium-ion batteries. Energy Mater Adv 2023;4:0044.

50. Li Y, Wu F, Qian J, et al. Metal chalcogenides with heterostructures for high-performance rechargeable batteries. Small Science 2021;1:2100012.

51. Li Y, Xu Y, Wang Z, et al. Stable carbon-selenium bonds for enhanced performance in Tremella -like 2D chalcogenide battery anode. Adv Energy Mater 2018;8:1800927.

52. Li Y, Qian J, Zhang M, et al. Co-construction of sulfur vacancies and heterojunctions in tungsten disulfide to induce fast electronic/ionic diffusion kinetics for sodium-ion batteries. Adv Mater 2020;32:e2005802.

53. Xiao Y, Lee SH, Sun YK. The application of metal sulfides in sodium ion batteries. Adv Energy Mater 2017;7:1601329.

54. Klein F, Jache B, Bhide A, Adelhelm P. Conversion reactions for sodium-ion batteries. Phys Chem Chem Phys 2013;15:15876-87.

55. Tan H, Chen D, Rui X, Yu Y. Peering into alloy anodes for sodium-ion batteries: current trends, challenges, and opportunities. Adv Funct Mater 2019;29:1808745.

56. Li Y, Yuan Y, Bai Y, et al. Insights into the Na⁺ storage mechanism of phosphorus-functionalized hard carbon as ultrahigh capacity anodes. Adv Energy Mater 2018;8:1702781.

57. Fukunishi M, Yabuuchi N, Dahbi M, et al. Impact of the cut-off voltage on cyclability and passive interphase of Sn-polyacrylate composite electrodes for sodium-ion batteries. J Phys Chem C 2016;120:15017-26.

58. Xiao X, Li X, Zheng S, Shao J, Xue H, Pang H. Nanostructured germanium anode materials for advanced rechargeable batteries. Adv Mater Inter 2017;4:1600798.

59. Darwiche A, Marino C, Sougrati MT, Fraisse B, Stievano L, Monconduit L. Better cycling performances of bulk Sb in Na-ion batteries compared to Li-ion systems: an unexpected electrochemical mechanism. J Am Chem Soc 2012;134:20805-11.

60. Su D, Dou S, Wang G. Bismuth: a new anode for the Na-ion battery. Nano Energy 2015;12:88-95.

61. Marbella LE, Evans ML, Groh MF, et al. Sodiation and desodiation via helical phosphorus intermediates in high-capacity anodes for sodium-ion batteries. J Am Chem Soc 2018;140:7994-8004.

62. Jung SC, Jung DS, Choi JW, Han YK. Atom-level understanding of the sodiation process in silicon anode material. J Phys Chem Lett 2014;5:1283-8.

63. Zhu N, Zhang K, Wu F, Bai Y, Wu C. Ionic liquid-based electrolytes for aluminum/magnesium/sodium-ion batteries. Energy Mater Adv 2021;2021:9204217.

64. Baughman RH, Shacklette LW, Murthy NS, Miller GG, Elsenbaumer RL. The evolution of structure during the alkali metal doping of polyacetylene and poly(p-phenylene). Mol Cryst Liq Cryst 1985;118:253-61.

65. Desai AV, Morris RE, Armstrong AR. Advances in organic anode materials for Na-/K-ion rechargeable batteries. ChemSusChem 2020;13:4866-84.

66. Tang K, Fu L, White RJ, et al. Hollow carbon nanospheres with superior rate capability for sodium-based batteries. Adv Energy Mater 2012;2:873-7.

67. Gong Y, Yu C, Li Y, Qian J, Wu C, Bai Y. Constructing robust solid electrolyte interface via ZrO₂ coating layer for hard carbon anode in sodium-ion batteries. Batteries 2022;8:115.

68. Chen X, Fang Y, Lu H, et al. Microstructure-dependent charge/discharge behaviors of hollow carbon spheres and its implication for sodium storage mechanism on hard carbon anodes. Small 2021;17:e2102248.

69. Han H, Chen X, Qian J, et al. Hollow carbon nanofibers as high-performance anode materials for sodium-ion batteries. Nanoscale 2019;11:21999-2005.

70. Zhong S, Liu H, Wei D, et al. Long-aspect-ratio N-rich carbon nanotubes as anode material for sodium and lithium ion batteries. Chem Eng J 2020;395:125054.

71. Jia H, Dirican M, Sun N, et al. SnS hollow nanofibers as anode materials for sodium-ion batteries with high capacity and ultra-long cycling stability. Chem Commun 2019;55:505-8.

72. Hou Z, Zhang X, Chen J, Qian Y, Chen L, Lee PS. Towards high-performance aqueous sodium ion batteries: constructing hollow NaTi₂(PO₄)₃@C nanocube anode with Zn metal-induced pre-sodiation and deep eutectic electrolyte. Adv Energy Mater 2022;12:2104053.

73. Zhang Y, Wang P, Yin Y, et al. Heterostructured SnS-ZnS@C hollow nanoboxes embedded in graphene for high performance lithium and sodium ion batteries. Chem Eng J 2019;356:1042-51.

74. Liu Z, Yu XY, Lou XW, Paik U. Sb@C coaxial nanotubes as a superior long-life and high-rate anode for sodium ion batteries. Energy Environ Sci 2016;9:2314-8.

75. Bin DS, Li Y, Sun YG, et al. Structural engineering of multishelled hollow carbon nanostructures for high-performance Na-ion battery anode. Adv Energy Mater 2018;8:1800855.

76. Wang X, Chen Y, Fang Y, Zhang J, Gao S, Lou XWD. Synthesis of cobalt sulfide multi-shelled nanoboxes with precisely controlled two to five shells for sodium-ion batteries. Angew Chem Int Ed 2019;58:2675-9.

77. Yang D, Zhang S, Yu P, et al. Structure engineering of vanadium tetrasulfides for high-capacity and high-rate sodium storage. Small 2022;18:e2107058.

78. Xie F, Zhang L, Su D, Jaroniec M, Qiao SZ. Na₂Ti₃O₇@N-doped carbon hollow spheres for sodium-ion batteries with excellent rate performance. Adv Mater 2017;29:1700989.

79. Ru J, He T, Chen B, et al. Covalent assembly of MoS₂ nanosheets with SnS nanodots as linkages for lithium/sodium-ion batteries. Angew Chem Int Ed 2020;59:14621-7.

80. Osman S, Peng C, Shen J, et al. Boosting fast and stable symmetric sodium-ion storage by synergistic engineering and amorphous structure. Nano Energy 2022;100:107481.

81. Pan Q, Tong Z, Su Y, Qin S, Tang Y. Energy storage mechanism, challenge and design strategies of metal sulfides for rechargeable sodium/potassium-ion batteries. Adv Funct Mater 2021;31:2103912.

82. Zhu J, Wei P, Zeng Q, et al. MnS@N,S co-doped carbon core/shell nanocubes: sulfur-bridged bonds enhanced Na-storage properties revealed by in situ raman spectroscopy and transmission electron microscopy. Small 2020;16:e2003001.

83. Lim H, Yu S, Choi W, Kim SO. Hierarchically designed nitrogen-doped MoS₂/silicon oxycarbide nanoscale heterostructure as high-performance sodium-ion battery anode. ACS Nano 2021;15:7409-20.

84. Zhang S, Qiu L, Zheng Y, et al. Rational design of core-shell ZnTe@N-doped carbon nanowires for high gravimetric and volumetric alkali metal ion storage. Adv Funct Mater 2021;31:2006425.

85. Shen Y, Li Y, Deng S, et al. TiC/C core/shell nanowires arrays as advanced anode of sodium ion batteries. Chin Chem Lett 2020;31:846-50.

86. Liu Y, Xu Y, Zhu Y, et al. Tin-coated viral nanoforests as sodium-ion battery anodes. ACS Nano 2013;7:3627-34.

87. Li R, Zhang G, Zhang P, et al. Accelerating ion transport via in-situ formation of built-in electric field for fast charging sodium-ion batteries. Chem Eng J 2022;450:138019.

88. Yang H, Xu R, Yao Y, Ye S, Zhou X, Yu Y. Multicore-shell Bi@N-doped carbon nanospheres for high power density and long cycle life sodium- and potassium-ion anodes. Adv Funct Mater 2019;29:1809195.

89. Huang Y, Hu X, Li J, et al. Rational construction of heterostructured core-shell Bi₂S₃@Co₉S₈ complex hollow particles toward high-performance Li- and Na-ion storage. Energy Stor Mater 2020;29:121-30.

90. Xie X, Huang K, Wu X, et al. Binding hierarchical MoSe₂ on MOF-derived N-doped carbon dodecahedron for fast and durable sodium-ion storage. Carbon 2020;169:1-8.

91. Wang H, Xu D, Jia G, et al. Integration of flexibility, cyclability and high-capacity into one electrode for sodium-ion hybrid capacitors with low self-discharge rate. Energy Stor Mater 2020;25:114-23.

92. Wang YX, Yang J, Chou SL, et al. Uniform yolk-shell iron sulfide-carbon nanospheres for superior sodium-iron sulfide batteries. Nat Commun 2015;6:8689.

93. Sun Q, Li D, Dai L, Liang Z, Ci L. Structural engineering of SnS₂ encapsulated in carbon nanoboxes for high-performance sodium/potassium-ion batteries anodes. Small 2020;16:e2005023.

94. Xiao S, Li Z, Liu J, et al. Se-C bonding promoting fast and durable Na⁺ storage in yolk-shell SnSe₂@Se-C. Small 2020;16:e2002486.

95. Li Y, Zhang S, Wang S, et al. A multi-shelled V₂O₃/C composite with an overall coupled carbon scaffold enabling ultrafast and stable lithium/sodium storage. J Mater Chem A 2019;7:19234-40.

96. Liu J, Kopold P, Wu C, van Aken PA, Maier J, Yu Y. Uniform yolk-shell Sn₄P₃@C nanospheres as high-capacity and cycle-stable anode materials for sodium-ion batteries. Energy Environ Sci 2015;8:3531-8.

97. Qian J, Xiong Y, Cao Y, Ai X, Yang H. Synergistic Na-storage reactions in Sn₄P₃ as a high-capacity, cycle-stable anode of Na-ion batteries. Nano Lett 2014;14:1865-9.

98. Yang H, Chen LW, He F, et al. Optimizing the void size of yolk-shell Bi@Void@C nanospheres for high-power-density sodium-ion batteries. Nano Lett 2020;20:758-67.

99. Chen S, Huang S, Zhang YF, et al. Constructing stress-release layer on Fe₇Se₈-based composite for highly stable sodium-storage. Nano Energy 2020;69:104389.

100. Zou F, Chen YM, Liu K, et al. Metal organic frameworks derived hierarchical hollow NiO/Ni/graphene composites for lithium and sodium storage. ACS Nano 2016;10:377-86.

101. Liang H, Ni J, Li L. Bio-inspired engineering of Bi₂S₃-PPy yolk-shell composite for highly durable lithium and sodium storage. Nano Energy 2017;33:213-20.

102. Feng X, Li Y, Zhang M, et al. Sulfur encapsulation and sulfur doping synergistically enhance sodium ion storage in microporous carbon anodes. ACS Appl Mater Interfaces 2022;14:50992-1000.

103. Ni D, Sun W, Wang Z, et al. Heteroatom-doped mesoporous hollow carbon spheres for fast sodium storage with an ultralong cycle life. Adv Energy Mater 2019;9:1900036.

104. Yang C, Li W, Yang Z, Gu L, Yu Y. Nanoconfined antimony in sulfur and nitrogen co-doped three-dimensionally (3D) interconnected macroporous carbon for high-performance sodium-ion batteries. Nano Energy 2015;18:12-9.

105. Bai J, Zhang L, Li S, Ren H, Liu Y, Guo S. Self-assembled MoTe₂ hierarchical nanoflowers with carbon coating as anode material for excellent sodium storage performance. Chem Eng J 2023;452:139111.

106. Opra DP, Neumoin AI, Sinebryukhov SL, et al. Moss-like hierarchical architecture self-assembled by ultrathin Na₂Ti₃O₇ nanotubes: synthesis, electrical conductivity, and electrochemical performance in sodium-ion batteries. Nanomaterials 2022;12:1905.

107. Li S, Wang Z, Liu J, et al. Yolk-shell Sn@C eggette-like nanostructure: application in lithium-ion and sodium-ion batteries. ACS Appl Mater Interfaces 2016;8:19438-45.