Microstructure,mechanical behaviour,and thermal shock effects of five layered thick Al/SiC functionally graded material fabricated by spark plasma sintering technique
Restricted accessResearch articleFirst published online 2026
Microstructure,mechanical behaviour,and thermal shock effects of five layered thick Al/SiC functionally graded material fabricated by spark plasma sintering technique
Functionally graded materials (FGMs) with specific material compositional variations ranging from metal-rich to ceramic-rich provide plenty of advantages in aerospace, defence, and automotive applications. In this study, thick Al/SiC FGM was fabricated using the spark plasma sintering technique to investigate the microstructure, mechanical, and thermal shock behaviour. The fabricated thick FGM consisted of five layers with varying proportions of aluminium and silicon carbide, calculated using a power law formulation. The microstructural analysis confirmed the linear increment of the SiC particles across the thickness direction. The mechanical test findings revealed a tensile strength of 139 MPa and a compressive strength of 242 MPa, while micro-hardness and free vibration analysis was carried out further. The thermal shock test micrographs indicated the interfacial fractures and the existence of thick oxide layer, which also confirms through EDS mapping. These research findings enhance the understanding the mechanical and thermal loading behaviour of the Al/SiC FGM’s, which will potentially contributing the usage of FGMs in the advanced engineering applications.
BalaramanPStephen Joseph RajVSreehariVM. Static and dynamic analysis of re-entry vehicle nose structures made of different functionally graded materials. Aerospace2022; 9(12): 812.
2.
UdupaGRaoSSGangadharanKV. Functionally graded composite materials: an overview. Procedia Mater Sci2014; 5: 1291–1299.
3.
BoggarapuVGujjalaROjhaS, et al. State of the art in functionally graded materials. Compos Struct2021; 262: 113596.
4.
NajibiAMokhtariT. Functionally graded materials for knee and hip arthroplasty; an update on design, optimization, and manufacturing. Compos Struct2023; 322: 117350.
5.
SalehBJiangJFathiR, et al. 30 Years of functionally graded materials: an overview of manufacturing methods, applications and future challenges. Compos B Eng2020; 201: 108376.
6.
NaebeMShirvanimoghaddamK. Functionally graded materials: a review of fabrication and properties. Appl Mater Today2016; 5: 223–245.
7.
ReddyKPKandavelTKSreehariVM. Influence of carbon percentage on the wear and friction characteristics of ATOMET 4601 alloys in heavy-duty machinery. Proc Inst Mech Eng Part E: J Process Mech Eng 2024. Published online 17 September 2024. DOI: 10.1177/09544089241283285
8.
GuptaATalhaM. Recent development in modeling and analysis of functionally graded materials and structures. Prog Aerosp Sci2015; 79: 1–14.
9.
SamMJojithRRadhikaN. Progression in manufacturing of functionally graded materials and impact of thermal treatment—a critical review. J Manuf Process2021; 68: 1339–1377.
10.
CanpolatÖÇanakçıAErdemirF. SS316L/Al2O3 functionally graded material for potential biomedical applications. Mater Chem Phys2023; 293: 126958.
11.
RajasekharKSuresh BabuVDavidsonMJ. Microstructural and mechanical properties of Al-Cu functionally graded materials fabricated by powder metallurgy method. Mater Today Proc2021; 41: 1156–1159.
12.
Al-ShafaieSHRadhiNSHusseinMA. Preparation and investigation mechanical properties of functionally graded materials of aluminum-nickel alloys. J Mech Eng Res Dev2021; 44: 102–109.
13.
CanakciAVarolTÖzkayaS, et al. Microstructure and properties of al-b4c functionally graded materials produced by powder metallurgy method. Univ J Mater Sci2014; 2: 90–95.
14.
Nemat-AllaMMAtaMHBayoumiMR, et al. Powder metallurgical fabrication and microstructural investigations of aluminum/steel functionally graded material. Mater Sci Appl2011; 02: 1708–1718.
15.
BarmanMSureshGHari TejaK, et al. Characterization of Cu based functionally graded materials reinforced with SiC. Mater Today Proc2023. DOI: 10.1016/j.matpr.2023.06.400.
16.
ÜbeyliMBalciESarikanB, et al. The ballistic performance of SiC–AA7075 functionally graded composite produced by powder metallurgy. Mater Des2014; 56: 31–36.
17.
JinXWuLSunY, et al. Microstructure and mechanical properties of ZrO2/NiCr functionally graded materials. Mater Sci Eng A2009; 509: 63–68.
18.
FarahmandSMonazzahAHSoorgeeMH. The fabrication of Al2O3–Al FGM by SPS under different sintering temperatures: microstructural evaluation and bending behavior. Ceram Int2019; 45: 22775–22782.
19.
NiXZhaoJSunJ, et al. Fabrication of two-dimensional graded Al2O3-(W, Ti)C–tin–Ni–Mo nano-composites by two-stage sintering. Ceram Int2019; 45: 21564–21571.
20.
BahraminasabMGhaffariSEslami-ShahedH. Al2O3-Ti functionally graded material prepared by spark plasma sintering for orthopaedic applications. J Mech Behav Biomed Mater2017; 72: 82–89.
21.
WatanabeMYokoyamaKImaiY, et al. Spark plasma sintering of sic/graphite functionally graded materials. Ceram Int2022; 48: 8706–8708.
22.
HamamcıMNairFCeritAA. Microstructural and mechanical characterization of functionally graded Fe/Fe2B (Fe/B4C) materials fabricated by in-situ powder metallurgy method. Ceram Int2023; 49: 18786–18799.
23.
SinghMSinghRKRGuptaD. Effect of in-situ cooling during pressure and frictional deformation on mechanical and metallurgical properties of Ni-based functionally graded material developed by wire arc additive manufacturing. Proc Inst Mech Eng Part L: J Mater Des Appl2024; 238: 50–64.
24.
NaikAKNazeerMPrasadDKVD, et al. Development of functionally graded ZrB2–B4C composites for lightweight ultrahigh-temperature aerospace applications. Ceram Int2022; 48: 33332–33339.
25.
TangYQiuWChenL, et al. Preparation of W–V functionally gradient material by spark plasma sintering. Nucl Eng Technol2020; 52: 1706–1713.
26.
SrinivasPNSBabuP RBB. Microstructural, mechanical and tribological characterization on the Al based functionally graded material fabricated powder metallurgy. Mater Res Express2020; 7: 026513. https://doi.org/10.1088/2053-1591/ab6f41
27.
BoggarapuVRama SreekanthPSPeddakondigallaVB, et al. Experimental study on tribological behavior of aluminum–copper functionally graded material. Proc Inst Mech Eng Part L: J Mater Des Appl2023; 237: 1592–1602.
28.
SunJJingQLeiL, et al. Compositional gradient affects the residual stress distribution in Si3N4/SiC functionally graded materials. Ceram Int2023; 49: 19281–19289.
29.
ArslanKGunesR. Experimental damage evaluation of honeycomb sandwich structures with Al/B4C FGM face plates under high velocity impact loads. Compos Struct2018; 202: 304–312.
30.
SharmaASrinivasan K VSDixitM, et al. Ballistic performance of functionally graded boron carbide reinforced Al - Zn - Mg - Cu alloy. J Mater Res Technol2022; 18: 4042–4059.
31.
WangYLiuQZhangB, et al. Ballistic performance of functionally graded B4C/Al composites without abrupt interfaces: experiments and simulations. J Mater Res Technol2023; 25: 1011–1029.
32.
SuryaMSPrasanthiG. Effect of silicon carbide weight percentage and number of layers on microstructural and mechanical properties of Al7075/SiC functionally graded material. Silicon2022; 14: 1339–1348.
33.
SuryaMSPrasanthiG. Manufacturing and micro structure study of Al-SiC functionally graded material. Mater Today Proc2017; 4: 621–627.
34.
SuryaMS. Fabrication, interlayer bonding and mechanical characterization of four layered AA7075/SiC functionally graded material. Silicon2023; 15: 4521–4528.
35.
MunirajDSreehariVM. Damage assessment of sandwich structures with Al/SiC functionally graded plasma sprayed faceplates subjected to single and repeated impacts. Compos Struct2022; 287: 115369.
36.
MunirajDVigneshSSreehariVM. Mechanical characterization and impact damage assessment of Al/SiC functionally graded coating under elevated temperatures. Sci Rep2024; 14: 29134.
37.
MunirajDVigneshSSreehariVM. High-velocity impact studies of honeycomb sandwich structures with Al/Al2O3 and Al/B4C functionally graded plasma sprayed faceplates. J Mater Sci Mater Eng2024; 19: 1–14.
38.
ChandaASahooR. Flexural behavior of functionally graded plates with piezoelectric materials. Arab J Sci Eng2020; 45: 9227–9248.
39.
SinghSDSahooR. Static and free vibration analysis of functionally graded CNT reinforced composite plates using trigonometric shear deformation theory. Structures2020; 28: 685–696.
40.
SinghSDSahooR. Static and free vibration analysis of functionally graded CNT reinforced sandwich plates using inverse hyperbolic shear deformation theory. J Strain Anal Eng Des2021; 56: 386–403.
41.
MonajatiLFaridNFaridM, et al. Vibration and buckling analyses of functionally graded plates based on refined plate theory using airy stress function. Proc Inst Mech Eng Part C: J Mech Eng Sci2022; 236(15): 8231–8244.
42.
VigneshSMunirajDSreehariVM. Experimental and numerical investigation of high-velocity impacts on aluminium 6061 plates under thermal environment. Trans Indian Ins Metals2025; 78: 1–11.
43.
SuryaMSGugulothuSK. Fabrication, mechanical and wear characterization of silicon carbide reinforced aluminium 7075 metal matrix composite. Silicon2022; 14: 2023–2032.
44.
BhattacharyyaMKumarANKapuriaS. Synthesis and characterization of Al/SiC and Ni/Al2O3 functionally graded materials. Mater Sci Eng A2008; 487: 524–535.
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