Abundant Cu3P/Co2P/CoP@NC Heterostructures Boost Charge Transfer Toward Fast and Durable Sodium Storage

Yuzhang Zhou , Yunxiu Wang , Yifan Zhang , Zhongchao Bai , Ming Yue Wang , Yanjun Zhai , Wei Du , Zhenhua Yan , Shi Xue Dou , Nana Wang , Fuyi Jiang , Caifu Dong

Carbon Energy ›› 2025, Vol. 7 ›› Issue (6) : e721

PDF
Carbon Energy ›› 2025, Vol. 7 ›› Issue (6) : e721 DOI: 10.1002/cey2.721
RESEARCH ARTICLE

Abundant Cu3P/Co2P/CoP@NC Heterostructures Boost Charge Transfer Toward Fast and Durable Sodium Storage

Author information +
History +
PDF

Abstract

Heterogeneous structure and carbon coating are important ways to enhance the reaction kinetics and cycling stability of metal phosphides as anode materials for sodium-ion batteries. Therefore, nitrogen-doped carbon-capped triphasic heterostructure Cu3P/Co2P/CoP@NC stands for nitrogen doped carbon nanorods were designed and synthesized through a combination of phosphide and carbonization. Kinetic analyses (cyclic voltammetry, electrochemical impedance spectroscopy, and galvanostatic intermittent titration technique) and density functional theory calculations show that the three-phase heterostructure and carbon layer effectively improve Na adsorption and migration as well as the electrochemical reactivity of the electrode. Based on this, Cu3P/Co2P/CoP@NC demonstrated excellent rate performance (305.9 mAh g−1 at 0.3 A g−1 and 202.8 mAh g−1 even at 10 A g−1) and cycling stability (the capacity decay rate is only 0.12% from the 5th to 300th cycle) when it is used for sodium-ion battery anodes. The in situ X-ray diffraction, ex situ X-ray photoelectron spectroscopy, and high-resolution transmission electron microscopy tests showed that Cu3P/Co2P/CoP@NC is based on a conversion reaction mechanism for sodium-ion storage. In addition, the NVP@reduced graphene oxide (rGO)//Cu3P/Co2P/CoP@NC full-cell delivers a high capacity of 210.2 mAh g−1 after 50 cycles at 0.3 A g−1. This work can provide a reference for the design of high-performance sodium electrode anode materials.

Keywords

Cu3P/Co2P/CoP@NC / nanorods / reaction kinetics / sodium-ion batteries / triphasic heterostructures

Cite this article

Download citation ▾
Yuzhang Zhou, Yunxiu Wang, Yifan Zhang, Zhongchao Bai, Ming Yue Wang, Yanjun Zhai, Wei Du, Zhenhua Yan, Shi Xue Dou, Nana Wang, Fuyi Jiang, Caifu Dong. Abundant Cu3P/Co2P/CoP@NC Heterostructures Boost Charge Transfer Toward Fast and Durable Sodium Storage. Carbon Energy, 2025, 7(6): e721 DOI:10.1002/cey2.721

登录浏览全文

4963

注册一个新账户 忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

J. E. Zhou, R. C. K. Reddy, A. Zhong, et al., “Metal-Organic Framework-Based Materials for Advanced Sodium Storage: Development and Anticipation,” Advanced Materials 36, no. 16 (2024): 2312471.
[2]

S. Gao, Y. He, H. Li, et al., “MoS2@CoS2 Heterostructured Tube-in-Tube Hollow Nanofibers With Enhanced Reaction Reversibility and Kinetics for Sodium-Ion Storage,” Energy Storage Materials 65 (2024): 103170.
[3]

X. Jin, Y. Huang, M. Zhang, et al., “A Flower-Like VO2(B)/V2CTX Heterojunction as High Kinetic Rechargeable Anode for Sodium-Ion Batteries,” Battery Energy 2, no. 6 (2023): 20230029.
[4]

C. Chu, C. Wang, W. Meng, et al., “Interfacial Chemistry and Structural Engineering Modified Carbon Fibers for Stable Sodium Metal Anodes,” Carbon Energy 6, no. 12 (2024): e601.
[5]

Y. Zhou, Q. Li, Q. Han, et al., “Design of High-Capacity MoS3 Decorated Nitrogen Doped Carbon Coated Cu2S Electrode Structures With Dual Heterogenous Interfaces for Outstanding Sodium-Ion Storage,” Small 19, no. 40 (2023): 2303742.
[6]

T. He, Q. An, M. Zhang, et al., “Multiscale Interface Engineering of Sulfur Doped TiO2 Anode for Ultrafast and Robust Sodium Storage,” ACS Nano 18, no. 7 (2024): 5672-5683.
[7]

H. Yuan, F. Ma, X. Wei, et al., “Ionic-Conducting and Robust Multilayered Solid Electrolyte Interphases for Greatly Improved Rate and Cycling Capabilities of Sodium Ion Full Cells,” Advanced Energy Materials 10, no. 37 (2020): 2001418.
[8]

S. Liu, J. Feng, X. Bian, J. Liu, and H. Xu, “Electroless Deposition of Ni3P-Ni Arrays on 3-D Nickel Foam as a High Performance Anode for Lithium-Ion Batteries,” RSC Advances 5, no. 75 (2015): 60870-60875.
[9]

Q. Feng, T. Li, Y. Miao, et al., “Polyvinylpyrrolidone Assisted Transformation of Cu-MoF Into N/P-Codoped Octahedron Carbon Encapsulated Cu3P Nanoparticles as High Performance Anode for Lithium Ion Batteries,” Journal of Colloid and Interface Science 608, no. 1 (2022): 227-238.
[10]

C. Dong, L. Guo, Y. He, et al., “Sandwich-Like Ni2P Nanoarray/Nitrogen-Doped Graphene Nanoarchitecture as a High-Performance Anode for Sodium and Lithium Ion Batteries,” Energy Storage Materials 15 (2018): 234-241.
[11]

J. Li, X. Li, P. Liu, et al., “Self-Supporting Hybrid Fiber Mats of Cu3P-Co2P/N-C Endowed With Enhanced Lithium/Sodium Ions Storage Performances,” ACS Applied Materials & Interfaces 11, no. 12 (2019): 11442-11450.
[12]

Y. Yun, B. Xi, Y. Gu, et al., “Cu3P Nanoparticles Confined in Nitrogen/Phosphorus Dual-Doped Porous Carbon Nanosheets for Efficient Potassium Storage,” Journal of Energy Chemistry 66 (2022): 339-347.
[13]

L. Zhou, P. Jiao, L. Fang, et al., “Two-Phase Transition Induced Amorphous Metal Phosphides Enabling Rapid, Reversible Alkali-Metal Ion Storage,” ACS Nano 15, no. 8 (2021): 13486-13494.
[14]

Q. Li, Q. Jiao, H. Li, et al., “Constructing Layered Double Hydroxide Derived Heterogeneous Ti3C2Tx@S-MCoP (M = Ni, Mn, Zn) with S-Vacancies to Boost Sodium Storage Performance,” Journal of Materials Chemistry A 10, no. 40 (2022): 21690-21700.
[15]

J. L. Zhang, C. L. Li, W. H. Wang, and D. Y. W. Yu, “Facile Synthesis of Hollow Cu3P for Sodium-Ion Batteries Anode,” Rare Metals 40 (2021): 3460-3465.
[16]

H. Li, X. Wang, Z. Zhao, et al., “Microstructure Controlled Synthesis of Ni, N-Codoped Cop/Carbon Fiber Hybrids With Improving Reaction Kinetics for Superior Sodium Storage,” Journal of Materials Science & Technology 99 (2022): 184-192.
[17]

M. Fan, Y. Chen, Y. Xie, et al., “Half-Cell and Full-Cell Applications of Highly Stable and Binder-Free Sodium Ion Batteries Based on Cu3P Nanowire Anodes,” Advanced Functional Materials 26, no. 28 (2016): 5019-5027.
[18]

Z. Hu, Q. Liu, W. Lai, et al., “Manipulating Molecular Structure and Morphology to Invoke High-Performance Sodium Storage of Copper Phosphide,” Advanced Energy Materials 10, no. 19 (2020): 1903542.
[19]

Z. Kong, L. Wang, S. Iqbal, et al., “Iron Selenide-Based Heterojunction Construction and Defect Engineering for Fast Potassium/Sodium-Ion Storage,” Small 18, no. 15 (2022): 2107252.
[20]

W. Liu, H. Gao, Z. Zhang, et al., “CoP/Cu3P Heterostructured Nanoplates for High-Rate Supercapacitor Electrodes,” Chemical Engineering Journal 437 (2022): 135352.
[21]

H. Zhou, Y. Zhao, Y. Jin, Q. Fan, Y. Dong, and Q. Kuang, “Bimetallic Phosphide Ni2P/CoP@rGO Heterostructure for High-Performance Lithium/Sodium-Ion Batteries,” Journal of Power Sources 560 (2023): 232715.
[22]

H. M. Saleem, M. Jamil, M. Tabish, et al., “Facile Synthesis of FeP-Decorated Heteroatomic-Doped Onion-Like Carbon Nanospheres for Pseudocapacitance Enhanced Sodium Storage,” ACS Applied Energy Materials 6, no. 19 (2023): 9885-9896.
[23]

G. Ou, M. Huang, X. Lu, et al., “A Metal-Organic Framework-Derived Strategy for Constructing Synergistic N-Doped Carbon-Encapsulated NiCoP@N-C-Based Anodes Toward High-Efficient Lithium Storage,” Small 20, no. 17 (2024): 2307615.
[24]

Y. Zhang, G. Wang, L. Wang, et al., “Graphene-Encapsulated Cup2: a Promising Anode Material With High Reversible Capacity and Superior Rate-Performance for Sodium-Ion Batteries,” Nano Letters 19, no. 4 (2019): 2575-2582.
[25]

Y. Sun, Y. L. Yang, X. L. Shi, et al., “An Ultra-Stable Sodium Half/Full Battery Based on a Unique Micro-Channel Pine-Derived Carbon/SnS2@Reduced Graphene Oxide Film,” Battery Energy 2, no. 2 (2023): 20220046.
[26]

J. Zhong and J. Li, “Copper Phosphide Nanostructures Covalently Modified Ti3C2Tx for Fast Lithium-Ion Storage by Enhanced Kinetics and Pesudocapacitance,” Small 20, no. 9 (2024): 2306241.
[27]

G. Ma, Y. Wang, J. Song, et al., “Understanding Electrolyte Salt Chemistry for Advanced Potassium Storage Performances of Transition-Metal Sulfides,” Carbon Energy 4, no. 3 (2022): 332-345.
[28]

Y. Li, S. Wu, L. Chen, H. Fan, Y. Zhang, and L. Zeng, “Multiple Yolks-Shell Cobalt Phosphosulfide Nanocrystals Encapsulating Into Rich Heteroatoms Co-Doped Carbon Frameworks for Advanced Sodium/Potassium Ion Batteries,” Chinese Chemical Letters (2024): 110371.
[29]

Q. Chang, Y. Jin, M. Jia, Q. Yuan, C. Zhao, and M. Jia, “Sulfur-Doped CoP@ Nitrogen-Doped Porous Carbon Hollow Tube as an Advanced Anode With Excellent Cycling Stability for Sodium-Ion Batteries,” Journal of Colloid and Interface Science 575 (2020): 61-68.
[30]

B. Zhang, L. Wang, B. Wang, et al., “Petroleum Coke Derived Porous Carbon/NiCoP With Efficient Reviving Catalytic and Adsorptive Activity as Sulfur Host for High Performance Lithium-Sulfur Batteries,” Nano Research 15, no. 5 (2022): 4058-4067.
[31]

Y. Feng, M. Xu, T. He, et al., “Copse: A New Ternary Anode Material for Stable and High Rate Sodium/Potassium-Ion Batteries,” Advanced Materials 33, no. 16 (2021): 2007262.
[32]

J. Zhu, Q. He, Y. Liu, et al., “Three-Dimensional, Hetero-Structured, Cu3P@C Nanosheets With Excellent Cycling Stability as Na-Ion Battery Anode Material,” Journal of Materials Chemistry A 7, no. 28 (2019): 16999-17007.
[33]

C. Dong, H. Shao, Y. Zhou, et al., “Construction of ZnS/Sb2S3 Heterojunction as an Ion-Transport Booster Toward High-Performance Sodium Storage,” Advanced Functional Materials 33, no. 9 (2023): 2211864.
[34]

C. Dong, J. Liang, Y. He, et al., “NiS1.03 Hollow Spheres and Cages as Superhigh Rate Capacity and Stable Anode Materials for Half/Full Sodium-Ion Batteries,” ACS Nano 12, no. 8 (2018): 8277-8287.
[35]

X. Zhang, L. Zhang, W. Zhang, S. Xue, and Y. Tang, “A Fast and Stable Sodium-Based Dual-Ion Battery Achieved by Cu3P@P-Doped Carbon Matrix Anode,” Journal of Power Sources 518 (2022): 230741.
[36]

G. Li, J. Liu, C. Xu, et al., “Regulating the Fe-Spin State by Fe/Fe3C Neighbored Single Fe-N4 Sites in Defective Carbon Promotes the Oxygen Reduction Activity,” Energy Storage Materials 56 (2023): 394-402.
[37]

C. Dong, L. Guo, H. Li, et al., “Rational Fabrication of CoS2/Co4S3@N-Doped Carbon Microspheres as Excellent Cycling Performance Anode for Half/Full Sodium Ion Batteries,” Energy Storage Materials 25 (2020): 679-686.
[38]

P. Xu, K. Dai, C. Yang, et al., “Efficient Synthesis of Cu3P Nanoparticles Confined in 3D Nitrogen Doped Carbon Networks as High Performance Anode for Lithium/Sodium-Ion Batteries,” Journal of Alloys and Compounds 849 (2020): 156436.
[39]

Q. Guo, H. Shao, K. Zhang, et al., “CoP Nanoparticles Intertwined With Graphene Nanosheets as a Superior Anode for Half/Full Sodium-Ion Batteries,” ChemElectroChem 8, no. 11 (2021): 2022-2027.
[40]

S. Park, C. W. Kim, K. S. Lee, S. J. Hwang, Y. Piao, and Y. Piao, “A Densely Packed Air-Stable Free-Standing Film With FeP Nanoparticles@C@P-Doped Reduced Graphene Oxide for Sodium-Ion Batteries,” Nanoscale 15, no. 34 (2023): 14155-14164.
[41]

L. Wang, Q. Li, Z. Chen, et al., “Metal Phosphide Anodes in Sodium-Ion Batteries: Latest Applications and Progress,” Small 20, no. 26 (2024): 2310426.
[42]

J. Duan, S. Deng, W. Wu, et al., “Chitosan Derived Carbon Matrix Encapsulated CuP2 Nanoparticles for Sodium-Ion Storage,” ACS Applied Materials & Interfaces 11, no. 13 (2019): 12415-12420.
[43]

Q. Zhao, Y. Ge, and X. Wang, “Metal-Organic-Framework-Derived Cubic Co2P@NC for Fast Sodium-Ion Storage,” Journal of Alloys and Compounds 947 (2023): 169346.
[44]

C. Dong, L. Wu, Y. He, et al., “Willow-Leaf-Like ZnSe@N-Doped Carbon Nanoarchitecture as a Stable and High-Performance Anode Material for Sodium-Ion and Potassium-Ion Batteries,” Small 16, no. 47 (2020): 2004580.
[45]

X. Wang, B. Xi, X. Ma, et al., “Boosting Zinc-Ion Storage Capability by Effectively Suppressing Vanadium Dissolution Based on Robust Layered Barium Vanadate,” Nano Letters 20, no. 4 (2020): 2899-2906.
[46]

J. Yu, Y. He, J. Li, et al., “In-Situ Rooting Biconical-Nanorods-Like Co-Doped FeP@Carbon Architectures Toward Enhanced Lithium Storage Performance,” Chemical Engineering Journal 477 (2023): 146996.
[47]

F. Wu, X. Gao, X. Xu, et al., “MnO2 Nanosheet-Assembled Hollow Polyhedron Grown on Carbon Cloth for Flexible Aqueous Zinc-Ion Batteries,” Chemsuschem 13, no. 6 (2020): 1537-1545.
[48]

Y. Du, Y. Wang, Z. Cao, et al., “Facile Synthesis of Cu7.2S4/RGO Composites for an Ultrastable and High-Rate Sodium Storage Anode,” Materials Today Chemistry 35 (2024): 101838.
[49]

J. Cheng, Z. Niu, Z. Zhao, et al., “Enhanced Ion/Electron Migration and Sodium Storage Driven by Different MoS2-ZnIn2S4 Heterointerfaces,” Advanced Energy Materials 13, no. 5 (2022): 2203248.
[50]

Y. Wang, Y. Wang, Z. Cai, et al., “Nitrogen-Doped Carbon Coated Zinc Selenide Nanoparticles Derived From Metal-Organic Frameworks as High-Rate and Long-Life Anode Materials for Half/Full Sodium-Ion Batteries,” Inorganic Chemistry Frontiers 11, no. 21 (2024): 7552-7562.
[51]

Y. Zhou, Y. Li, Y. He, et al., “Uniform Bi3Se4@N-Doped Carbon Spheres as Anode for Superior Lithium and Potassium Storage Performance,” Journal of Alloys and Compounds 960 (2023): 170616.
[52]

B. Zhang, B. Xu, Z. Xiao, L. Cao, H. Geng, and X. Ou, “Inner-Stress-Dissipative, Rapid Self-Healing Core-Shell Sulfide Quantum Dots for Remarkable Potassium-Ion Storage,” Energy Storage Materials 56 (2023): 96-107.
[53]

M. Xie, C. Li, S. Zhang, et al., “Topological Insulator Bi2Se3-Assisted Heterostructure for Ultrafast Charging Sodium-Ion Batteries,” Small 19, no. 33 (2023): 2301436.
[54]

H. Li, Y. He, Q. Wang, et al., “SnSe2/NiSe2@N-Doped Carbon Yolk-Shell Heterostructure Construction and Selenium Vacancies Engineering for Ultrastable Sodium-Ion Storage,” Advanced Energy Materials 13, no. 47 (2023): 2302901.
[55]

J. Zhong and J. Li, “Copper Phosphide Nanostructures Covalently Modified Ti3C2Tx for Fast Lithium-Ion Storage by Enhanced Kinetics and Pesudocapacitance,” Small 20, no. 9 (2023): 2306241.
[56]

Y. Xu, Q. Wei, C. Xu, et al., “Layer-by-Layer Na3V2(PO4)3 Embedded in Reduced Graphene Oxide as Superior Rate and Ultralong-Life Sodium-Ion Battery Cathode,” Advanced Energy Materials 6, no. 14 (2016): 1600389.

RIGHTS & PERMISSIONS

2025 The Author(s). Carbon Energy published by Wenzhou University and John Wiley & Sons Australia, Ltd.

AI Summary AI Mindmap
PDF

18

Accesses

0

Citation

Detail
Sections
Recommended

AI思维导图

/