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Synthesis of Ni-P/Ni-P-W Nanocomposite Coating and its Tribological Resistance
A. Ansari1, K. D. Singh2, Sulaxna Sharma3, Vijay Kumar4, Vakul Bansal5, Awanish Kumar Sharma6

1A. Ansari, Research Scholars Department of Physics, GEU Dehradunand J.V Jain College Saharanpur (Uttar Pradesh), India.

2K.D. Singh, Research Scholars Department of Physics, GEU Dehradunand J.V Jain College Saharanpur (Uttar Pradesh), India.

3Sulaxna Sharma, Assistant Professor, THDC, IHET Tehri. 

4Vijay Kumar, Professor Department of Physics, Graphic Era Hill University Dehradun, Saharanpur (Uttar Pradesh), India.

5Vakul Bansal, Professor Department of Physics, J.V Jain College Saharanpur (Uttar Pradesh), India.

6Awanish Kumar Sharma, Professor Department of Physics, Graphic Era Deemed to be University Dehradun, India.

Manuscript received on 13 October 2019 | Revised Manuscript received on 20 October 2019 | Manuscript Published on 29 June 2020 | PP: 17-19 | Volume-8 Issue-10S2 August 2019 | Retrieval Number: : J100508810S219/2019©BEIESP | DOI: 10.35940/ijitee.J1005.08810S219

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© The Authors. Blue Eyes Intelligence Engineering and Sciences Publication (BEIESP). This is an open-access article under the CC-BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Abstract: The synthesized tungsten nanoparticles (0.5 g/l, range 40 to 150 nm) are dispersed randomly into electroless Ni-P matrix for Ni-P-W nanocomposite platings on an AISI1040 grade steel substrate (MS). The thickness of these deposits is in range of 15 to 25 micrometer. The scanning electron microscope attached in permutation of energy dispersive spectroscopy furthermore X-ray diffraction techniques were exploited to analyze surface morphology, elemental symphony and phases of platings correspondingly. The results of these studies reveal successful fusion of tungsten nanoparticles as white globules into electroless Ni-P matrix and with those as-deposited platings have amorphous structure and heated platings (400°C) have crystalline structure. Further Ni-P/Ni-P-W platings are investigated for microhardness by respective technique. The results of the studies corroborate that inclusion of tungsten nanoparticles into electroless Ni-P plating enhances the microhardness. The phase transformation initiation of amorphous nickel is headed toward nickel phosphide and crystalline nickel completely at 400°C which improved microhardness of nanocomposite Ni-P-W electro less platings.

Keywords: Electroless plating, Ni-P-W, characterization, microhardness.
Scope of the Article: Composite Materials