The effect of surfactants on the particle size of iron, cobalt and nickel nanopowders

This paper studies the effect of surfactants on the particle size of metal nanopowders (NPs): iron, cobalt and nickel synthesized using chemical-metallurgy method – hydrogen reduction of hydroxide compounds FeOOH, Co(OH)₂ and Ni(OH)₂ at 400, 285, and 280 °С, respectively. These hydroxides were pre-synthesized via chemical deposition from the corresponding nitrate solutions with NaOH alkali solution (10 wt.%) using sodium dodecyl sulfate (SDS) (0.1 %) and ethylenediaminetetraacetic acid disodium salt (EDTA) (0.3 %). The obtained NPs were studied using such methods as X-ray diffractometry (XRD), scanning electron microscopy (SEM), and measurements of the specific surface area by low-temperature nitrogen adsorption. According to XRD shows that all the obtained samples of NPs Fe, Co and Ni contain pure metallic phases. The results of electron microscopic analysis and measurement of the specific surface area of powder samples show that the addition of various surfactants to the initial synthesis medium of hydroxide compounds has a significant effect on the size and morphology of the obtained NPs. It was found that the addition of 0.1 % SDS leads to a decrease in the average size of the obtained particles, and the presence of 0.3 % EDTA contributes to the formation of larger metal particles. It was shown that the use of 0.3 % EDTA in deposition of initial hydroxide precursors makes it possible to obtain metal NPs with the narrowest crystallite size distributions.

nanopowder, nanoparticle, iron, cobalt, nickel, surfactant, sodium dodecyl sulfate, ethylenediaminetetraacetic acid disodium salt, coherent scattering region, specific surface area

1. Springer handbook of nanotechnology. Ed. Bhushan Bharat. 4th ed. Berlin: Verlag Heidelberg, 2017.

2. Yaroslavtsev A.B., Ivanov V.K., Fedorov P.P., Baranchikov A.E., Lermontov S.A., Malkova A.N., Malygin A.A., Yampol’skii Yu.P., Belov N.A., Alent’ev A.Yu., Leonidov I.A., Dobrovol’skii Yu.A., Skundin A.M., Kozyukhin S.A., Sherchenkov A.A., Grinberg V.A., Kondratov S.V., Yurkov G.Yu., Fionov A.S., Khadzhiev S.N., Maksimov A.L., Kadiev Kh.M., Shtanskii D.V., Levashov E.A., Sukhorukova I.V., Gusarov V.V., Al’myasheva O.V., Marikutsa A.V., Rumyantseva M.N., Gas’kov A.M. Ed. A.B. Yaroslavtsev. Nanomaterials. Properties and promising applications. Moscow: Nauchnyi mir, 2014 (In Russ.).

3. Samal S.S., Manohara S.R. Nanoscience and nanotechnology in India: A broad perspective. Mater. Today Proc. 2019. Vol. 10. P. 151—158.

4. Olawoyin R. Nanotechnology: The future of fire safety. Safety Sci. 2018. Vol. 110. P. 214—221.

5. Justin D., Geraldine R. Does nanotechnology research generate an innovation premium over other types of research? Evidence from Ireland. Technol. Soc. 2019. Vol. 59. P. 101183—101190.

6. Vibhu K.V., Sakthivel R.R.M., Surabhi S., Moon A. Nanotechnology in spine surgery: A current update and critical review of the literature. World Neurosurgery. 2019. Vol. 123. P. 142—155.

7. Chao’en Li, Lisa Wong, Liangguang Tang, Nicola Scarlett, Ken Chiang, Jim Patel, Nicholas Burke, Valérie Sage. Kinetic modelling of temperature-programmed reduction of cobalt oxide by hydrogen. Appl. Catal., A. 2017. Vol. 537. P. 1—11.

8. Levina V.V. Preparation of one- and two-component nanomaterials based on iron, nickel, copper, cobalt by chemical dispersion: Dissertation of Dr. Sci. (Tech.). Moscow: MISIS, 2005 (In Russ.).

9. Zhu W., Dong X., Huang H., Qi M. Iron nanoparticlesbased magnetorheological fluids: A balance between MR effect and sedimentation stability. J. Magn. Magn. Mater. 2019. Vol. 491. P. 165556—165561.

10. Jyoti Chaudhary, Giriraj Tailor, Yadav B.L., Oshon Michael. Synthesis and biological function of nickel and copper nanoparticles. Heliyon. 2019. Vol. 5. Iss. 6. P. 1878—1882.

11. Ryzhonkov D.I., Levina V.V., Dzidziguri E.L. Nanomaterials. Moscow: BINOM. Laboratoriya znanii, 2012 (In Russ.).

12. Forsman J. Production of Co, Ni, and Cu nanoparticles by hydrogen reduction: Thesis for the degree of Dr. Sci. (Tech.). Espoo (Finland): Aalto University School of Science and Technology, 2013.

13. Noémie Ballot, Frédéric Schoenstein, Silvana Mercone, T. Chauveau, Ovidiu Brinza, Noureddine Jouini. Reduction under hydrogen of ferrite MFe 2 O 4 (M: Fe, Co, Ni) nanoparticles obtained by hydrolysis in polyol medium: A novel route to elaborate CoFe2 , Fe and Ni3 Fe nanoparticles. J. Alloys Compd. 2012. Vol. 536. P. 381—385.

14. Konyukhov Yu.V., Ryzhonkov D.I., Levina V.V., Dzidziguri E.L. Obtaining nanopowders of iron from iron ore rawmaterials. Izvestiya vuzov. Chernaya metallurgiya. 2005. No. 3. P. 11—15 (In Russ.).

15. Dahman Y. Nanotechnology and functional materials for engineers. Elsevier Health Sciences Division, 2017.

16. Banik S., Mahajan A. Size control synthesis of pure Ni nanoparticles and anodic-oxidation of Butan-1-ol in alkali. Mater. Chem. Phys. 2019. Vol. 235. P. 121747—121756.

17. Jun Liang, Jing Wang, Saijie Li, Lu Xu, Rui Wang, Ruipeng Chen, Yunfeng Sun. The size-controllable preparation of chitosan/silver nanoparticle composite microsphere and its antimicrobial performance. Carbohyd. Polym. 2019. Vol. 220. P. 22—29.

18. Andrew Pendergast, Matthew Glasscott, Christophe Renault, Jeffrey E. Dick. One-step electrodeposition of ligand-free Pd—Pt alloy nanoparticles from water droplets: Controlling size, coverage, and elemental stoichiometry. Electrochem. Commun. 2019. Vol. 98. P. 1—5.

19. Delbecq F., Delfosse P. Study of a gelated Deep Eutectic solvent metal salt solution as template for the production of size-controlled small noble metal nanoparticles. Colloids Surf., A. 2019. Vol. 567. P. 55—62.

20. Linlin Xu, Danye Liu, Dong Chen, Hui Liu, Jun Yang. Size and shape controlled synthesis of rhodium nanoparticles. Heliyon. 2019. Vol. 5. Iss. 1. P. 1165—1208.

21. Konyukhov Yu.V. Development of scientific and technological foundations for obtaining nanopowders from industrial raw materials and materials modification using energy-mechanical processing: Dissertation of Dr. Sci. (Tech.). Moscow: MISIS, 2018 (In Russ.).

22. Nguyen V.M. Development of effective methods for producing nanopowders of the iron triad by hydrogen reduction from oxide compounds in a vortex field and thin layers: Dissertation of PhD. Sci. (Tech.). Moscow: MISIS, 2018 (In Russ.).

23. Dzidziguri E.L., Sidorova E.N. Ultrafine media. X-ray diffractometry for materials research. Moscow: MISIS, 2007 (In Russ.).

24. Frolov Yu.G. The course of colloid chemistry. Surface phenomena and disperse systems. Moscow: Khimiya, 1989 (In Russ.).

25. Abramzon A.A., Bobrova L.E., Zaichenko L.P., Izmailova V.N., Novozhenets A.A., Rokhlenko A.A., Tulovskaya Z.D., Shits L.A., Yampolskaya G.P. Handbook of surfactants and interfacial phenomena. Leningrad: Khimiya, 1984 (In Russ.).

26. Antonov A.N. The effect of surfactants on the synthesis of iron hydroxide nanoparticles: Dissertation of Cand. Sci. (Phys.-Math.). Moscow: MGU, 2013 (In Russ.).