MIS FOSFIDI (Cu₃P): SINTEZ USULLARI, ELEKTROKIMYOVIY XOSSALARI VA KORROZIYAGA QARSHI QO‘LLANILISHINING ZAMONAVIY TAHLILI

Maqola Yon paneli

PDF (inglizcha) Acceptance Certificate
Nashr etilgan: 29.06.2026
DOI: https://doi.org/10.70769/3030-3214.SRT.4.2.2026.29
Kalit so‘zlar:
mis fosfidi, Cu₃P, sintez usullari, elektrokimyoviy xossalar, energiya saqlash, elektrokataliz, korroziyaga qarshi qoplamalar, nanostrukturali materiallar, pirometallurgik qayta ishlash, sharh

Maqolaning Asosiy Qismi

Xoliqulov, D.B.
Olmaliq davlat texnika instituti
Sharopova, D.Y.
Olmaliq davlat texnika instituti

Annotatsiya

Ushbu sharh maqolada mis fosfidi (Cu₃P) asosidagi materiallarning sintez texnologiyalari, kristall tuzilishi, elektrokimyoviy xossalari hamda korroziyaga qarshi qo‘llanilishi bo‘yicha zamonaviy ilmiy tadqiqotlar tahlil qilindi. Yigirmata nufuzli ilmiy manba qiyosiy baholanib, ionotermik, gidrotermal, mexanokimyoviy, kolloid, bug‘ fazali fosforizatsiya va pirometallurgik qayta ishlash usullarining afzalliklari hamda cheklovlari aniqlandi. Shuningdek, sintez usullarining materialning faza tarkibi, morfologiyasi, elektrokimyoviy samaradorligi va korroziyaga chidamliligiga ta'siri baholandi. Tahlil natijalari Cu₃P asosidagi nanostrukturali materiallar energiya saqlash qurilmalari, elektrokataliz va sanoat korroziyasidan himoyalash sohalarida istiqbolli ko‘p funksiyali material ekanligini ko‘rsatdi.

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Maqola Tafsilotlari

Son

Jild 4 № 2 (2026)

Bo‘lim

Kon-metallurgiya va ishlab chiqarish sanoati
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Muallif biografiyalari

Xoliqulov, D.B., Olmaliq davlat texnika instituti

Texnika fanlari doktori (DSc), professor, Olmaliq davlat texnika instituti, Olmaliq, O‘zbekiston

Sharopova, D.Y., Olmaliq davlat texnika instituti

Olmaliq davlat texnika instituti “Metallurgiya” kafedrasi doktoranti, Olmaliq, O‘zbekiston

Iqtibos keltirish tartibi

Xoliqulov, D. B., & Sharopova, D. Y. (2026). MIS FOSFIDI (Cu₃P): SINTEZ USULLARI, ELEKTROKIMYOVIY XOSSALARI VA KORROZIYAGA QARSHI QO‘LLANILISHINING ZAMONAVIY TAHLILI. Sanoatda Raqamli Texnologiyalar, 4(2). https://doi.org/10.70769/3030-3214.SRT.4.2.2026.29

Adabiyotlar ro‘yxati

[1] Aitken, J. A., Ganzha-Hazen, V., & Brock, S. L. (2005). Solvothermal syntheses of Cu₃P via reactions of amorphous red phosphorus with a variety of copper sources. J. Solid State Chem., 178(4), 970–975.

[2] Stan, M. C., et al. (2014). Cu₃P Binary Phosphide: Synthesis via Wet Mechanochemical Method and Electrochemical Behavior as Negative Electrode. Adv. Energy Mater., 4(1), 1301270.

[3] Kumar, S., et al. (2020). Three-Dimensional Graphene-Decorated Copper-Phosphide (Cu₃P@3DG) Heterostructure as an Effective Electrode for a Supercapacitor. Front. Mater., 7, 30.

[4] Wolff, A., et al. (2016). Resource-Efficient High-Yield Ionothermal Synthesis of Microcrystalline Cu₃₋xP. Inorg. Chem., 55(11), 4991–4998.

[5] Sheets, E. J., et al. (2015). An in situ phosphorus source for the synthesis of Cu₃P and subsequent conversion to Cu₃PS₄ nanoparticle clusters. J. Mater. Res., 30(21), 3125–3133.

[6] Wei, S., et al. (2017). One-Step Synthesis of a Self-Supported Copper Phosphide Nanobush for Overall Water Splitting. ACS Appl. Mater. Interfaces, 9(3), 2305–2313.

[7] Wolff, A., et al. (2018). Low-Temperature Tailoring of Cu₃₋xP – Electric Properties, Phase Transitions and Performance in Lithium-Ion Batteries. Chem. Mater., 30(21), 7111–7123.

[8] Sharopova, D. Y. (2025). Anti-Corrosive Properties of Copper Phosphide / Copper Phosphate (Cu₃(PO₄)₂) Derived from Spent Copper Plating Electrolytes. Universum: Technical Sciences, 9(138), 62–66.

[9] Zhao, M., Fang, T., Ni, L., & Shen, Y. (2022). MOF-derived inverse opal Cu₃P@C with multi-stage pore structure as the superior anode material for lithium-ion batteries. Ceramics International, 48(24), 36586–36595.

[10] Bi, M., Yang, F., Wang, T., & Guo, Z. (2023). Controllable synthesis and super electrochemical stability of copper phosphide (Cu₃P) nanosheet catalysts in nearly neutral electrolyte. Materials Chemistry and Physics, 307, 128013.

[11] Ma, X., Huang, X., & Lachgar, A. (2024). Direct Synthesis of CuP₂ and Cu₃P and Their Performance as Electrocatalysts for Hydrogen Evolution, Oxygen Evolution, and Oxygen Reduction Reactions. Solids, 5(1), 140–150.

[12] Jin, M., Zhang, Y., Liu, H., et al. (2024). Heterostructure Cu₃P–Ni₂P electrocatalyst assembled on conductive substrates for highly efficient overall water splitting. Nano Research.

[13] Shen, H., Zhang, Q., Li, X., et al. (2023). Copper phosphide nanowires as high-performance catalysts for efficient water splitting. ACS Omega, 8, 21844–21854.

[14] Harper, A. F., Evans, M. L., & Morris, A. J. (2020). Computational investigation of copper phosphides as conversion anodes for lithium-ion batteries. Chemistry of Materials, 32(14), 6004–6015.

[15] Pfeiffer, H., Tancret, F., Bichat, M.-P., Monconduit, L., Favier, F., & Brousse, T. (2004). Air stable copper phosphide (Cu₃P): A possible negative electrode material for lithium batteries. Electrochemistry Communications, 6(3), 263–267.

[16] Yakubov, M. M., Kholikulov, D. B., Sharapova, D. Y., & Boltayev, O. N. (2022). Technology for Obtaining Copper Phosphide (Cu₃P) in the Form of Solders and an Alloying Component of Copper-Based Alloys. Composite Materials, 2/2022, 165–166.

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