Page 74 - 机械工程材料2025年第三期

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雷云平，等：钠离子电池负极用立方体ZnSe/SnSe@C复合材料的制备及电化学性能

［3］ HU X J，WANG G，WANG B B，et al. Co 3 Sn 2 / ［12］ ZHANG T，QIU D P，HOU Y L. Free-standing and
SnO 2 heterostructures building double shell micro- consecutive ZnSe@carbon nanofibers architectures
cubes wrapped in three-dimensional graphene matrix as as ultra-long lifespan anode for flexible lithium-ion
promising anode materials for lithium-ion and sodium- batteries［J］. Nano Energy，2022，94：106909.
ion batteries［J］. Chemical Engineering Journal，2019，［13］ YU L T，KIM K S，SAEED G，et al. Hybrid ZnSe-

355：986-998. SnSe 2 nanoparticles embedded in N-doped carbon

［4］ ZHANG Z A，ZHAO X X，LI J. SnSe/carbon nanocube heterostructures with enhanced and ultra-stable
nanocomposite synthesized by high energy ball milling lithium-storage performance［J］. ChemElectroChem，
as an anode material for sodium-ion and lithium-ion 2021，8（24）：4732-4744.
batteries［J］. Electrochimica Acta，2015，176：1296- ［14］ TANG C J，WEI X J，CAI X Y，et al. ZnSe

1301. microsphere/multiwalled carbon nanotube composites
［5］ ZHU H Y，LI Z Y，XU F，et al. Ni 3 Se 4 @CoSe 2 hetero- as high-rate and long-life anodes for sodium-ion

nanocrystals encapsulated into CNT-porous carbon batteries［J］. ACS Applied Materials & Interfaces，
interpenetrating frameworks for high-performance 2018，10（23）：19626-19632.

sodium ion battery［J］. Journal of Colloid and Interface ［15］ LIU P，HAN J，ZHU K J，et al. Heterostructure SnSe 2 /
Science，2022，611：718-725. ZnSe@PDA nanobox for stable and highly efficient
［6］ LI J J，ZHANG W，ZHENG W T. Metal selenides sodium-ion storage［J］. Advanced Energy Materials，

find plenty of space in architecting advanced sodium/ 2020，10（24）：2000741.
potassium ion batteries［J］. Small，2024，20（4）：［16］ LIANG Z X，LI Q H，ZHANG W，et al. Pomegranate-

e2305021. inspired porous SnSe/ZnSe@C anode：A stress-

［7］ LI H，HE Y Y，WANG Q，et al. SnSe 2 /NiSe 2 @N-doped buffer nanostructure for fast and ultrastable sodium-
carbon yolk-shell heterostructure construction and ion storage［J］. Journal of Energy Chemistry，2022，75：
selenium vacancies engineering for ultrastable sodium- 369-377.

ion storage［J］. Advanced Energy Materials，2023，13 ［17］ QIAN Z B，WANG X J，LIU T，et al. Nickel-cobalt
（47）：2302901. selenide@N-doped carbon towards high-performance
［8］ GONG Y T，LI Y，LI Y，et al. Metal selenides anode materials for sodium-ion batteries［J］. Journal of

anode materials for sodium ion batteries：Synthesis， Energy Storage，2022，51：104522.
modification，and application［J］. Small，2023，19（4）：［18］ ZHANG Y，WANG P X，YIN Y Y，et al.

e2206194. Heterostructured SnS-ZnS@C hollow nanoboxes

［9］ ZHENG H，XU H S，HU J P，et al. Construction of embedded in graphene for high performance lithium and
hierarchical MnSe@SnSe 2 @N-C nanorods for high- sodium ion batteries［J］. Chemical Engineering Journal，
performance lithium-ion batteries［J］. ACS Applied 2019，356：1042-1051.

Energy Materials，2022，5（6）：6586-6596. ［19］ ZHOU Q P，WANG D W，LIAN Y，et al. Rechargeable
［10］ HUANG D，WU D X，ZHU J X，et al. One- aluminum-ion battery with sheet-like MoSe 2 @C

dimensional ZnSe@N-doped carbon nanofibers with nanocomposites cathode［J］. Electrochimica Acta，2020，
simple electrospinning route for superior Na/K-ion 354：136677.
storage［J］. Chinese Chemical Letters，2023，34（2）：［20］ HUANG Z X，LIU B，KONG D Z，et al. SnSe 2

107416. quantum dot/rGO composite as high performing lithium

［11］ WANG J W，YANG X F，YANG C N，et al. anode［J］. Energy Storage Materials，2018，10：92-101.
Three-dimensional （3D） ordered macroporous ［21］ LI J，LUO W B，ZHANG Z，et al. ZnSe/SnSe 2 hollow

bimetallic （Mn，Fe） selenide/carbon composite with microcubes as cathode for high performance aluminum
heterojunction interface for high-performance sodium ion batteries［J］. Journal of Colloid and Interface
ion batteries［J］. ACS Applied Materials & Interfaces， Science，2023，639：124-132.
2023，15（33）：40100-40114.

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