[1] Huang GF, Huang WQ, Wang LL, Meng Y, Xie Z, Zou BS. Electrochemical study of electroless deposition of Fe–P alloys. Electrochimica acta. 2006 Jun 1;51(21):4471-6.
[2] Huang GF, Huang WQ, Wang LL, Zou BS, Wang QL, Zhang JH. Studies on the Fe-P film plating from a chemical bath: deposition mechanism and parameter effects. International Journal of Electrochemical Science. 2008 Jan 1;3(2):145-53.
[3] Mueller T, Bachmaier A, Konetschnik R, Schoeberl T, Pippan R. Mechanical properties of electrodeposited amorphous/crystalline multilayer structures in the Fe-P system. Materials Science and Engineering: A. 2018 Feb 7;715:83-91.
[4] Matsui I, Omura N. Electrodeposition of bulk nanocrystalline Ni–Fe–P alloys and their mechanical and soft magnetic properties. Materialia. 2020 Aug 1;12:100766.
[5] Linderoth S, Mo/rup S. Chemically prepared amorphous Fe‐B particles: Influence of p H on the composition. Journal of Applied physics. 1990 May 1;67(9):4472-4.
[6] Kong FL, Chang CT, Inoue A, Shalaan E, Al-Marzouki F. Fe-based amorphous soft magnetic alloys with high saturation magnetization and good bending ductility. Journal of Alloys and Compounds. 2014 Dec 5;615:163-6.
[7] Liu T, Ji B, Wu Y, Liu Z, Wang W. Effects of the pH value on the electrodeposition of Fe–P alloy as a magnetic film material. The Journal of Physical Chemistry C. 2022 Sep 1;126(36):15472-84.
[8] Brito MM, Zacarin MG, Arruda RA, Barbano EP, Carlos IA. Investigation of electrochemical deposition of Fe-P alloys on polycrystalline platinum from an alkaline bath. Thin Solid Films. 2020 Apr 1;699:137862.
[9] Kovalska N, Tsyntsaru N, Cesiulis H, Gebert A, Fornell J, Pellicer E, Sort J, Hansal W, Kautek W. Electrodeposition of nanocrystalline Fe-P coatings: influence of bath temperature and glycine concentration on structure, mechanical and corrosion behavior. Coatings. 2019 Mar 13;9(3):189.
[10] Mikó A, Hempelmann R, Lakatos-Varsányi M, Kálmán E. Iron-phosphorous layers deposited by pulse electrochemical technique. Electrochemical and solid-state letters. 2006 May 24;9(8):C126.
[11] Xuan C, Wang J, Xia W, Peng Z, Wu Z, Lei W, Xia K, Xin HL, Wang D. Porous structured Ni–Fe–P nanocubes derived from a prussian blue analogue as an electrocatalyst for efficient overall water splitting. ACS applied materials & interfaces. 2017 Aug 9;9(31):26134-42.
[12] Sequeira CA, Santos DM, Brito PS. Electrocatalytic activity of simple and modified Fe–P electrodeposits for hydrogen evolution from alkaline media. Energy. 2011 Feb 1;36(2):847-53.
[13] Hrubovčáková M, Kupková M, Džupon M. Fe and Fe-P foam for biodegradable bone replacement material: morphology, corrosion behaviour, and mechanical properties. Advances in Materials Science and Engineering. 2016 Jan 1;2016.
[14] Mostavan A, Paternoster C, Tolouei R, Ghali E, Dubé D, Mantovani D. Effect of electrolyte composition and deposition current for Fe/Fe-P electroformed bilayers for biodegradable metallic medical applications. Materials Science and Engineering: C. 2017 Jan 1;70:195-206.
[15] Su Y, Guo Y, Huang Z, Zhang Z, Li G, Lian J, Ren L. Preparation and corrosion behaviors of calcium phosphate conversion coating on magnesium alloy. Surface and Coatings Technology. 2016 Dec 15;307:99-108.
[16] Ruscior C, Croială E. Chemical Iron‐Phosphorus Films. Journal of the Electrochemical Society. 1971 May 1;118(5):696.
[17] Wang F, Itoh K, Watanabe T. Relationship between the crystallographic structure of electrodeposited Fe-P alloy film and its thermal equilibrium phase diagram. Materials transactions. 2003;44(1):127-32.
[18] Elsukov EP, Vorobev YN, Trubachev AV, Barinov VA. Structure and Magnetic Properties of Fe P Electrodeposited Alloys. physica status solidi (a). 1990 Jan 16;117(1):291-8.
[19] Vitkova ST, Kjuchukova M, Raichevski G. Electrochemical preparation of amorphous Fe-P alloys. Journal of applied electrochemistry. 1988 Sep;18:673-8.
[20] Liu Y, Xu X, Sadd M, Kapitanova OO, Krivchenko VA, Ban J, Wang J, Jiao X, Song Z, Song J, Xiong S. Insight into the critical role of exchange current density on electrodeposition behavior of lithium metal. Advanced Science. 2021 Mar;8(5):2003301.
[21] Min C, Li S, Shi Z, Xie J, Ma R. Effect of pH on the electrodeposition nucleation and growth mechanism of cuprous oxide. Journal of Solid State Electrochemistry. 2023 May;27(5):1085-93.
[22] Xiao J, Yu J, Guo F, Qiao Q, Yang H, Guo Y. Effects of Process Parameters and CrCl3 Concentration on the Structure, Surface Morphology, Composition and Corrosion Resistance of Electrodeposited NiCrP Amorphous Alloy Coatings. Coatings. 2020 Aug 17;10(8):795.
[23] Zhang S, Yu J, Wang S, Liu Z, Wróblewski P. Electrodeposition behavior and characterization of Fe-P alloys at different pH values. International Journal of Electrochemical Science. 2023 Nov 1;18(11):100323.
[24] Kim D, Park DY, Yoo BY, Sumodjo PT, Myung NV. Magnetic properties of nanocrystalline iron group thin film alloys electrodeposited from sulfate and chloride baths. Electrochimica Acta. 2003 Feb 20;48(7):819-30.
[25] Chat-Wilk K, Rudnik E, Włoch G. Effect of chloride and sulfate ions on electrodeposition and surface properties of alloys produced from zinc-nickel-manganese gluconate baths. Journal of The Electrochemical Society. 2022 Sep 14;169(9):092515.
[26] Izaki M. Electrodeposition of iron and iron alloys. Modern electroplating. 2010 Oct 4;5.
[27] Zhang S, Yu J, Liu Z, Yin Y, Qiao C. Numerical and experimental investigation of the effect of current density on the anomalous codeposition of ternary Fe-Co-Ni alloy coatings. Materials. 2022 Sep 4;15(17):6141.
[28] Lu ZP, Sepunaru L. Electrodeposition of iron phosphide film for hydrogen evolution reaction. Electrochimica Acta. 2020 Dec 10;363:137167.
[29] Critelli RA, Sumodjo PT, Bertotti M, Torresi RM. Influence of glycine on Co electrodeposition: IR spectroscopy and near-surface pH investigations. Electrochimica Acta. 2018 Jan 10;260:762-71.
[30] Safizadeh F, Sorour N, Ghali E, Houlachi G. Study of the hydrogen evolution reaction on Fe–Mo–P coatings as cathodes for chlorate production. international journal of hydrogen energy. 2017 Feb 23;42(8):5455-63.
