Restricted accessResearch articleFirst published online 2025
Enhanced mechanical performance of AA7075-boron carbide/blast furnace slag hybrid composite through friction stir welding with cryogenically treated tool: A microstructural and mechanical characterization
AluminIum 7075 hybrid metal matrix composites are widely utilized in aerospace, automotive, defense and marine applications due to their superior strength, stiffness, hardness and wear resistance properties. Friction stir welding (FSW) is a promising technique for joining such composites, but its industrial application is limited by the challenges such as excessive tool wear, reduced weld strength and weld defects caused by too degradation. This study focuses on development of an H13 tool with enhanced wear resistance for the FSW of AA7075 hybrid metal matrix composite (MMC) reinforced with 5%, 10%, 15% of boron carbide (B4C) particles and 8% blast furnace slag (BFS) by weight. A cryogenically treated H13 tool was proposed to improve tool durability and minimize the wear. The treated tool shows a remarkable 336% improvement in wear resistance under in situ welding compared to untreated tool. Micro-mechanical characterization of the welded joints was performed, revealing improved weld properties, particularly in plates with higher reinforcement percentages. Mechanical testing revealed that the ultimate tensile strength increased with reinforcement content with a maximum of 266.37 ± 3.17 MPa (50.14% higher than the unreinforced sample) for the sample containing 15 wt% of B4C + 8 wt% of BFS, while microhardness improved by 12% achieving a peak value of 164.42 Hv. These findings demonstrate that the use of cryogenically treated H13 tools enables the FSW of highly reinforced AA7075 MMCs, producing defect-free joints with superior strength and hardness, thereby extending the potential of FSW in advanced structural applications.
EmamianSSAwangMYusofF, et al.Improving the friction stir welding tool life for joining the metal matrix composites. Int J Adv Manuf Tech2020; 106: 3217–3227.
2.
PradoRAMurrLEShindoDJ, et al.Tool wear in the friction-stir welding of aluminum alloy 6061+ 20% Al2O3: a preliminary study. Scr Mater2001; 45: 75–80.
3.
JafariHMansouriHHonarpishehM. Investigation of residual stress distribution of dissimilar Al-7075-T6 and Al-6061-T6 in the friction stir welding process strengthened with SiO2 nanoparticles. J Manuf Process2019; 43: 145–153.
4.
Mohammadi-pourMKhodabandehAMohammadi-pourS, et al.Microstructure and mechanical properties of joints welded by friction-stir welding in aluminum alloy 7075-T6 plates for aerospace application. Rare Met2025; 44: 2085–2093.
5.
BozkurtYBoumerzougZ. Tool material effect on the friction stir butt welding of AA2124-T4 alloy matrix MMC. J Mater Res Technol2018; 7: 29–38.
6.
AliKSMohanavelVVendanSA, et al.Mechanical and microstructural characterization of friction stir welded SiC and B4C reinforced aluminium alloy AA6061 metal matrix composites. Materials (Basel)2021; 14: 3110.
7.
LiuHJFengJCFujiiH, et al.Wear characteristics of a WC–Co tool in friction stir welding of AC4A+ 30 vol% SiCp composite. Int J Mach Tools Manuf2005; 45: 1635–1639.
8.
SharmaASinghSPalK. Investigation of microstructural and mechanical properties of Al alloy 7075-T6/B4C nanocomposite concocted via friction stir process. Ceram Int2022; 48: 35708–35718.
9.
Barbaz-IsfahaniRDadrasHSaber-SamandariS, et al.A comprehensive investigation of the low-velocity impact response of enhanced GFRP composites with single and hybrid loading of various types of nanoparticles. Heliyon2023; 9: e15930.
10.
RahmaniFBarbaz-IsfahaniRSaber-SamandariS, et al.Experimental and analytical investigation on forced and free vibration of sandwich structures with reinforced composite faces in an acidic environment. Heliyon2023; 9: e20864.
11.
IpekogluMNekouyanAAlbayrakO, et al.Mechanical characterization of B4C reinforced aluminum matrix composites produced by squeeze casting. J Mater Res2017; 32: 599–605.
12.
SahlotPJhaKDeyGK, et al.Quantitative wear analysis of H13 steel tool during friction stir welding of Cu-0.8% Cr-0.1% Zr alloy. Wear2017; 378-379: 82–89.
13.
MoradiMMAvalHJJamaatiR. Effect of pre and post welding heat treatment in SiC-fortified dissimilar AA6061-AA2024 FSW butt joint. J Manuf Process2017; 30: 97–105.
14.
BistASainiJSSharmaV. Comparison of tool wear during friction stir welding of Al alloy and Al-SiC metal matrix composite. Proc Inst Mech Eng Part D2021; 235: 1522–1533.
15.
RanaHGBadhekaVJKumarA. Fabrication of Al7075/B4C surface composite by novel friction stir processing (FSP) and investigation on wear properties. Procedia Technol2016; 23: 519–528.
16.
IkumapayiOMAkinlabiETSharmaA, et al.Tribological, structural and mechanical characteristics of friction stir processed aluminium-based matrix composites reinforced with stainless steel micro-particles. Eng Solid Mech2020; 8: 253–270.
17.
Molla RamezaniNDavoodiBAberoumandM, et al.Assessment of tool wear and mechanical properties of Al 7075 nanocomposite in friction stir processing (FSP). J Braz Soc Mech Sci Eng2019; 41: 1–4.
18.
KoneshlouMAslKMKhomamizadehF. Effect of cryogenic treatment on microstructure, mechanical and wear behaviors of AISI H13 hot work tool steel. Cryogenics2011; 51: 55–61.
19.
ÇiçekAKaraFKıvakT, et al.Effects of deep cryogenic treatment on the wear resistance and mechanical properties of AISI H13 hot-work tool steel. J Mater Eng Perform2015; 24: 4431–4439.
20.
KumarSNagrajMBongaleA, et al.Deep cryogenic treatment of AISI M2 tool steel and optimisation of its wear characteristics using Taguchi‘s approach. Arab J Sci Eng2018; 43: 4917–4929.
21.
MoscosoMFRamosFDde Lima LessaCR, et al.Effects of cooling parameter and cryogenic treatment on microstructure and fracture toughness of AISI D2 tool steel. J Mater Eng Perform2020; 29: 7929–7939.
22.
SurekhaKEls-BotesA. Effect of cryotreatment on tool wear behaviour of Bohler K390 and AISI H13 tool steel during friction stir welding of copper. Trans Indian Inst Met2012; 65: 259–264.
23.
LiJZhangXBuH, et al.Effects of deep cryogenic treatment on the microstructure evolution, mechanical and thermal fatigue properties of H13 hot work die steel. J Mater Res Technol2023; 27: 8100–8118.
24.
ChinnasamyMRathanasamyRPalSK, et al.Effectiveness of cryogenic treatment on cutting tool inserts: a review. Int J Refract Met Hard Mater2022; 108: 105946.
25.
RajaPSakthivelMKumarTS, et al.Deep cryo treated tungsten carbide tools on AISI 1045 steel turning through grey relational analysis and preference selection index. Sci Rep2025; 15: 18452.
26.
SinghLPSinghJ. Effect of cryogenic treatment on the microstructure and wear behavior of a T-42 tool steel. Mater Test2015; 57: 306–310.
27.
SinghHSinghSGoyalA. Wear resistance enhancement of AISI D3 tool steels by cryogenic treatment: a review. Asian Rev Mech Eng2018; 7: 15–17.
28.
KumarNPatnaikPKMishraSK, et al.Mechanical and tribological properties of Al7075 based metal matrix composite reinforced with boron carbide and blast furnace slag. Mater Today Proc2023. https://doi.org/10.1016/j.matpr.2023.12.037
29.
AttallahMMSalemHG. Friction stir welding parameters: a tool for controlling abnormal grain growth during subsequent heat treatment. Mater Sci Eng A2005; 391: 51–59.
30.
LackiPWięckowskiWLutyG, et al.Evaluation of usefulness of AlCrN coatings for increased life of tools used in friction stir welding (FSW) of sheet aluminum alloy. Materials (Basel)2020; 13: 4124.
31.
PandaMRMahapatraandSSMohantyCP. Parametric investigation of friction stir welding on AA6061 using Taguchi technique. Mater Today Proc2015; 2: 2399–2406.
32.
ChandanaRSaraswathammaK. Impact of tool pin profiles in friction stir welding process-a review. Mater Today Proc2023; 76: 602–606.
33.
KoradeDRamanaKVJagtapK. Wear and fatigue behaviour of deep cryogenically treated H21 tool steel. Trans Indian Inst Met2020; 73: 843–851.
34.
RhyimYMHanSHNaYS, et al.Effect of deep cryogenic treatment on carbide precipitation and mechanical properties of tool steel. Solid State Phenomena2006; 118: 9–14.
35.
BoztepeAGecuR. Influence of cryogenic treatment and tempering temperature on microstructural evolution and dry sliding wear behavior of AISI D3 cold-work tool steel. J Tribol2025; 147: 064201.
36.
GecuR. Combined effects of cryogenic treatment and tempering on microstructural and tribological features of AISI H13 steel. Mater Chem Phys2022; 292: 126802.
37.
DemirEToktasI. Effects of cryogenic treatment on residual stresses of AISI D2 tool steel. Kovove Mater2018; 56: 153–161.
38.
PodržajPJermanBKlobčarD. Welding defects at friction stir welding. Metalurgija2015; 54: 387–389.
39.
KalaiselvanKDinaharanIMuruganN. Characterization of friction stir welded boron carbide particulate reinforced AA6061 aluminum alloy stir cast composite. Mater Des2014; 55: 176–182.
40.
RoyPSinghSPalK. Enhancement of mechanical and tribological properties of SiC-and CB-reinforced aluminium 7075 hybrid composites through friction stir processing. Adv Compos Mater2019; 28: 1–8.
41.
BauriRYadavDKumarCS, et al.Tungsten particle reinforced Al 5083 composite with high strength and ductility. Mater Sci Eng A2015; 620: 67–75.
42.
DinaharanI. Influence of ceramic particulate type on microstructure and tensile strength of aluminum matrix composites produced using friction stir processing. J Asian Ceram Soc2016; 4: 209–218.
43.
SureshR. Comparative study on dry sliding wear behavior of mono (Al2219/B4C) and hybrid (Al2219/B4C/Gr) metal matrix composites using statistical technique. J Mech Behav Mater2020; 29: 57–68.
44.
NarimaniMLotfiBSadeghianZ. Evaluation of the microstructure and wear behaviour of AA6063-B4C/TiB2 mono and hybrid composite layers produced by friction stir processing. Surf Coat Technol2016; 285: 1–10.
45.
LuoA. Heterogeneous nucleation and grain refinement in cast Mg (AZ91)/SiCp metal matrix composites. Can Metall Q1996; 35: 375–383.
46.
ChenXGDa SilvaMGougeonP, et al.Microstructure and mechanical properties of friction stir welded AA6063–B4C metal matrix composites. Mater Sci Eng A2009; 518: 174–184.
47.
BandhuDThakurAPurohitR, et al.Characterization & evaluation of Al7075 MMCs reinforced with ceramic particulates and influence of age hardening on their tensile behavior. J Mech Sci Technol2018; 32: 3123–3128.
48.
PrabhuSShettigarAKRaoK, et al.Influence of welding process parameters on microstructure and mechanical properties of friction stir welded aluminium matrix composite. Mater Sci Forum2016; 880: 50–53.
49.
BabuBSPrathapPBalajiT, et al.Studies on mechanical properties of aluminum based hybrid metal matrix composites. Mater Today Proc2020; 33: 1144–1148.
50.
BhojanASenthilkumarNDeepanrajB. Parametric influence of friction stir welding on cast Al6061/20% SiC/2% MoS2 MMC mechanical properties. Appl Mech Mater2016; 852: 297–303.
51.
FernandezGJMurrLE. Characterization of tool wear and weld optimization in the friction-stir welding of cast aluminum 359+ 20% SiC metal-matrix composite. Mater Charact2004; 52: 65–75.
52.
SalihOSOuHWeiX, et al.Microstructure and mechanical properties of friction stir welded AA6092/SiC metal matrix composite. Mater Sci Eng A2019; 742: 78–88.
53.
AlanemeKKBodunrinMO. Mechanical behaviour of alumina reinforced AA 6063 metal matrix composites developed by two step-stir casting process. Acta Tech Corviniensis Bull Eng2013; 6: 105.
54.
LloydDJ. Particle reinforced aluminium and magnesium matrix composites. Int Mater Rev1994; 39: 1–23.
55.
SrivatsanTS. Microstructure, tensile properties and fracture behaviour of Al2O3 particulate-reinforced aluminium alloy metal matrix composites. J Mater Sci1996; 31: 1375–1388.
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