Microstructure and properties of Al2CrFeCoCuTiNix high-entropy alloys prepared by laser cladding

► We use a new method (laser cladding) to prepare Al2CrFeCoCuTiNix high-entropy alloys. ► We studied the effect of Ni content on alloys’ properties. ► Alloys show high microhardness, excellent corrosion resistance and wear resistance. ► The laser cladding layers play a good protective effect on Q235...

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Published in:	Journal of alloys and compounds Vol. 553; pp. 216 - 220
Main Authors:	Qiu, Xing-Wu, Liu, Chun-Ge
Format:	Journal Article
Language:	English
Published:	Kidlington Elsevier B.V 15-03-2013 Elsevier
Subjects:	Al2CrFeCoCuTiNix Alloys Applied sciences Cladding Coating Contact of materials. Friction. Wear Corrosion Corrosion prevention Corrosion resistance Exact sciences and technology Hardness High-entropy alloy Joining, thermal cutting: metallurgical aspects Killed steels Laser cladding Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology Metals. Metallurgy Microstructure Nickel Properties Protective coatings Wear resistance Laser cladding Al2CrFeCoCuTiNix Microstructure Properties High-entropy alloy high entropy alloy Scanning electron microscopy Vickers hardness FCC lattices CrFeCoCuTiNi Aluminium alloy Al Phase analysis Cladding X ray diffraction Microhardness Corrosion resistance BCC lattices Wear resistance Heat affected zone Nanocrystal
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Abstract	► We use a new method (laser cladding) to prepare Al2CrFeCoCuTiNix high-entropy alloys. ► We studied the effect of Ni content on alloys’ properties. ► Alloys show high microhardness, excellent corrosion resistance and wear resistance. ► The laser cladding layers play a good protective effect on Q235 steel. The Al2CrFeCoCuTiNix high-entropy alloys were prepared by laser cladding. Using metallurgical microscope, scanning electron microscopy with spectroscopy (SEM/EDS), X-ray diffraction, micro/Vickers hardness tester, electrochemical workstation and tribometer the structure and hardness, corrosion resistance and wear resistance of Al2CrFeCoCuTiNix high-entropy alloys were tested. The result shows that, Al2CrFeCoCuTiNix high-entropy alloy samples consist of the cladding zone, bounding zone and heat affected zone. The bounding zone is between cladding layer and the substrate of a good combination; the cladding zone is composed mainly of axis crystal, nanocrystalline and fine white crystals. The Al2CrFeCoCuTiNix high-entropy alloys coating phase structure samples (FCC and BCC structure) due to high-entropy effect. The surface microhardness of Al2CrFeCoCuTiNix high-entropy alloys samples up to 1102 HV, about 4 times as the substrate, and the hardness increases with increasing Ni content. Al2CrFeCoCuTiNix high-entropy alloys coating has good corrosion resistance in 1mol/L NaOH solution and 3.5% NaCl solution. With the increase of Ni content, the corrosion resistance first increases and then decreases. The relative wear resistance of Al2CrFeCoCuTiNix high-entropy alloys coating shows a first increased and then a decreased trend with the increase of Ni content. Both the hardness and ductility are affected by wear resistance. The coating can play a good protective role on substrate Q235 steel.
AbstractList	► We use a new method (laser cladding) to prepare Al2CrFeCoCuTiNix high-entropy alloys. ► We studied the effect of Ni content on alloys’ properties. ► Alloys show high microhardness, excellent corrosion resistance and wear resistance. ► The laser cladding layers play a good protective effect on Q235 steel. The Al2CrFeCoCuTiNix high-entropy alloys were prepared by laser cladding. Using metallurgical microscope, scanning electron microscopy with spectroscopy (SEM/EDS), X-ray diffraction, micro/Vickers hardness tester, electrochemical workstation and tribometer the structure and hardness, corrosion resistance and wear resistance of Al2CrFeCoCuTiNix high-entropy alloys were tested. The result shows that, Al2CrFeCoCuTiNix high-entropy alloy samples consist of the cladding zone, bounding zone and heat affected zone. The bounding zone is between cladding layer and the substrate of a good combination; the cladding zone is composed mainly of axis crystal, nanocrystalline and fine white crystals. The Al2CrFeCoCuTiNix high-entropy alloys coating phase structure samples (FCC and BCC structure) due to high-entropy effect. The surface microhardness of Al2CrFeCoCuTiNix high-entropy alloys samples up to 1102 HV, about 4 times as the substrate, and the hardness increases with increasing Ni content. Al2CrFeCoCuTiNix high-entropy alloys coating has good corrosion resistance in 1mol/L NaOH solution and 3.5% NaCl solution. With the increase of Ni content, the corrosion resistance first increases and then decreases. The relative wear resistance of Al2CrFeCoCuTiNix high-entropy alloys coating shows a first increased and then a decreased trend with the increase of Ni content. Both the hardness and ductility are affected by wear resistance. The coating can play a good protective role on substrate Q235 steel. The Al2CrFeCoCuTiNix high-entropy alloys were prepared by laser cladding. Using metallurgical microscope, scanning electron microscopy with spectroscopy (SEM/EDS), X-ray diffraction, micro/Vickers hardness tester, electrochemical workstation and tribometer the structure and hardness, corrosion resistance and wear resistance of Al2CrFeCoCuTiNix high-entropy alloys were tested. The result shows that, Al2CrFeCoCuTiNix high-entropy alloy samples consist of the cladding zone, bounding zone and heat affected zone. The bounding zone is between cladding layer and the substrate of a good combination; the cladding zone is composed mainly of axis crystal, nanocrystalline and fine white crystals. The Al2CrFeCoCuTiNix high-entropy alloys coating phase structure samples (FCC and BCC structure) due to high-entropy effect. The surface microhardness of Al2CrFeCoCuTiNix high-entropy alloys samples up to 1102 HV, about 4 times as the substrate, and the hardness increases with increasing Ni content. Al2CrFeCoCuTiNix high-entropy alloys coating has good corrosion resistance in 1 mol/L NaOH solution and 3.5% NaCl solution. With the increase of Ni content, the corrosion resistance first increases and then decreases. The relative wear resistance of Al2CrFeCoCuTiNix high-entropy alloys coating shows a first increased and then a decreased trend with the increase of Ni content. Both the hardness and ductility are affected by wear resistance. The coating can play a good protective role on substrate Q235 steel.
Author	Liu, Chun-Ge Qiu, Xing-Wu
Author_xml	– sequence: 1 givenname: Xing-Wu surname: Qiu fullname: Qiu, Xing-Wu email: fallenrain922@163.com organization: Department of Materials Engineering, Sichuan College of Architectural Technology, Deyang 618000, China – sequence: 2 givenname: Chun-Ge surname: Liu fullname: Liu, Chun-Ge organization: Department of Transportation and Municipal Engineering, Sichuan College of Architectural Technology, Deyang 618000, China
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Keywords	Laser cladding Al2CrFeCoCuTiNix Microstructure Properties High-entropy alloy high entropy alloy Scanning electron microscopy Vickers hardness FCC lattices CrFeCoCuTiNi Aluminium alloy Al Phase analysis Cladding X ray diffraction Microhardness Corrosion resistance BCC lattices Wear resistance Heat affected zone Nanocrystal
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Snippet	► We use a new method (laser cladding) to prepare Al2CrFeCoCuTiNix high-entropy alloys. ► We studied the effect of Ni content on alloys’ properties. ► Alloys... The Al2CrFeCoCuTiNix high-entropy alloys were prepared by laser cladding. Using metallurgical microscope, scanning electron microscopy with spectroscopy...
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SubjectTerms	Al2CrFeCoCuTiNix Alloys Applied sciences Cladding Coating Contact of materials. Friction. Wear Corrosion Corrosion prevention Corrosion resistance Exact sciences and technology Hardness High-entropy alloy Joining, thermal cutting: metallurgical aspects Killed steels Laser cladding Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology Metals. Metallurgy Microstructure Nickel Properties Protective coatings Wear resistance
Title	Microstructure and properties of Al2CrFeCoCuTiNix high-entropy alloys prepared by laser cladding
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