Powder metallurgy methodology and a novel solar sintering process are combined to successfully produce porous copper foams with varying porosities from 50 to 70% vol. Firstly, pure copper powder was mixed with saccharose particles acting as spacer-holder and compacted into cylindrical shapes. Saccharose dissolution time, which ranged from 8 to 32 h, was inversely related to the target porosity. Concentrated solar energy, focused using a Fresnel lens, was applicated for the sintering of the remaining copper structures at 850 °C for 10 min. Comparing to conventional sintering in electrical furnace (1075 °C for 8 h), the solar sintering process achieved a full densification at a lower temperature and in a much shorter time. Density, pore size, and porosity morphology and distribution were analysed. The final copper foams exhibited uniform pore distribution and achieved porosities close to the target values, with roughly half of the porosity being open. Additionally, the compressive strength of the solar sintered foams matched, and in some cases, surpassed, that of conventional sintered foams. The utilization of concentrated solar energy has allowed to obtain high quality and densification copper foams with a good combination of mechanical properties and lightweight.
ParvanianAMPanjepourM. Mechanical behavior improvement of open-pore copper foams synthesized through space holder technique. Mater Des2013; 49: 834–841.
3.
AshbyMFEvansTFleckNA, et al.Metal foams: a design guide. Elsevier, 2000.
4.
ChenRTianshouZ. Porous current collectors for passive direct methanol fuel cells. Electrochim Acta2007; 52: 4317–4324.
5.
BidaultFBrettDJLMiddletonPH, et al.A new application for nickel foam in alkaline fuel cells. Int J Hydrogen Energy2009; 34: 6799–6808.
6.
DesgischerHPKrisztB. Handbook of cellular metals: Production, processing, applications. Wiley-vch, 2002.
7.
DaviesGJZhenS. Metallic foams: their production, properties and applications. J Mater Sci1983; 18: 1899–1911.
8.
ThewseyDJZhaoYY. Thermal conductivity of porous copper manufactured by the lost carbonate sintering process. Phys Status Solidi A2008; 205: 1126–1131.
9.
HetsroniGGurevichMRozenblitR. Sintered porous medium heat sink for cooling of high-power mini devices. Int J Heat Fluid Flow2006; 27: 259–266.
10.
AlizadehMMirzaei-AliabadiM. Compressive properties and energy absorption behavior of Al–Al2O3 composite foam synthesized by space-holder technique. Mater Des2012; 35: 419–424.
11.
JiangBZhaoNQShiCS, et al.A novel method for making open cell aluminum foams by powder sintering process. Mater Lett2005; 59: 3333–3336.
12.
HassaniAHabibolahzadehABaftiH. Production of graded aluminum foams via powder space holder technique. Mater Des2012; 40: 510–515.
13.
MondalDPMajumderJDJhaN, et al.Titanium-chemosphere syntactic foam made through powder metallurgy route. Mater Des2012; 34: 82–89.
14.
NevilleBPRabieiA. Composite metal foams processed through powder metallurgy. Mater Des2008; 29: 388–396.
15.
WangQZCuiCXLiuSJ,et al.Open-celled porous Cu prepared by replication of NaCl space-holders. Mater Sci Eng A2010; 527: 1275–1278.
16.
ShahzeydiMHParvanianAMPanjepourM. The distribution and mechanism of pore formation in copper foams fabricated by lost carbonate sintering method. Mater Charact2016; 111: 21–30.
17.
ZhaoYYFungTZhangLP,et al.Lost carbonate sintering process for manufacturing metal foams. Scr Mater2005; 52: 295–298.
18.
ZhangLPZhaoYY. Fabrication of high melting-point porous metals by lost carbonate sintering process via decomposition route. Proc Inst Mech Eng B2008; 222: 267–271.
19.
ZhangLMullenDLynnK,et al.Heat transfer performance of porous copper fabricated by lost carbonate sintering process. MRS Proc2009; 1188: 1188-LL04-07.
20.
XiaoZZhaoY. Heat transfer coefficient of porous copper with homogeneous and hybrid structures in active cooling. J Mater Res2013; 28: 2545–2553.
21.
RomeroPAZhengSFCuitiñoAM. Modeling the dynamic response of visco-elastic open-cell foams. J Mech Phys Solids2008; 56: 1916–1943.
22.
VeyhlCBelovaIVMurchGE,et al.Finite element analysis of the mechanical properties of cellular aluminum based on micro-computed tomography. Mater Sci Eng A2011; 528: 4550–4555.
23.
BanhartJ. Manufacture, characterization and application of cellular metals and metal foams. Prog Mater Sci2001; 46: 559–632.
24.
AhmedYMZRiadMISayedAS, et al.Correlation between factors controlling preparation of porous copper via sintering technique using experimental design. Powder Technol2007; 175: 48–54.
25.
TaoXFZhangLPZhaoYY. Mechanical response of porous copper manufactured by lost carbonate sintering process. Mater Sci Forum2007; 539-543: 1863–1867.
26.
StergioudiFKapraraESimeonidisK, et al.Copper foams in water treatment technology: removal of hexavalent chromium. Mater Des2015; 87: 287–294.
27.
MahaidinAAAbdullahNMohammadM, et al.Effect of sintering cycle on physical and mechanical properties of open pore cell copper foam. Procedia Chem2016; 19: 546–551.
28.
NoorsyakirahAMazlanMAfianOM, et al.Application of potassium carbonate as space holder for metal injection molding process of open pore copper foam. Procedia Chem2016; 19: 552–557.
29.
LuXZhaoYWangG,et al.Effects of structure characteristics and fluid on the effective thermal conductivity of sintered copper foam. Results Phys2020; 19: 103655.
30.
HerranzGRodriguezGP. Uses of concentrated solar energy in materials science. Sol Energy2010; 1: 1–27.
31.
RodríguezGPLopezVDamboreneaJJ,et al.Surface transformation hardening on steels treated with solar energy in central tower and heliostats field. Sol Energy Mater Sol Cells1995; 37: 1–12.
32.
PantelisDIGriniariASaraflogouC. Surface alloying of pre-deposited molybdenum-based powder on 304L stainless steel using concentrated solar energy. Sol Energy Mater Sol Cells2005; 89: 1–11.
33.
RodriguezGPHerranzGRomeroA. Solar gas nitriding of Ti6Al4V alloy. Appl Surf Sci2013; 283: 445–452.
34.
RomeroAGarcíaIArenasMA, et al.High melting point metals welding by concentrated solar energy. Sol Energy2013; 95: 131–143.
35.
RomeroAGarcíaIArenasMA, et al.Ti6Al4V titanium alloy welded using concentrated solar energy. J Mater Process Technol2015; 223: 284–291.
36.
RomeroARodríguezGPMarjalizaE. Processing of intermetallic laminates by self-propagating high–temperature synthesis initiated with concentrated solar energy. J Alloys Compd2022; 891: 161876.
37.
RomeroARodriguezGPBareaR. Sinter-hardening of chromium PM steels with concentrated solar energy. J Mater Process Technol2020; 280: 116616.
38.
HerranzGRomeroAde CastroV,et al.Processing of AISI M2 high speed steel reinforced with vanadium carbide by solar sintering. Mater Des (1980–2015)2014; 54: 934–946.
39.
CañadillaARodríguezGPRomeroA, et al.Sustainable production of copper components using concentrated solar energy in material extrusion additive manufacturing (MEX-CSE). Sustain Mater Technol2024; 39: e00799.
40.
GarciaIGracia-EscosaEBayodM, et al.Sustainable production of titanium foams for biomedical applications by concentrated solar energy sintering. Mater Lett2016; 185: 420–423.
41.
CambroneroLEGCañadasIMartinezD,et al.Foaming of aluminum–silicon alloy using concentrated solar energy. Sol Energy2010; 84: 879–887.
42.
García-CambroneroLECañadasIDiazJJ, et al.Properties of aluminum nodules foamed with concentrated solar energy. EURO PM2011; 2011: 339–344.
43.
CañadillaARomeroARodríguezGP. Sustainable production of powder metallurgy aluminum foams sintered by concentrated solar energy. Metals (Basel)2021; 11: 1544.
44.
ParvanianAMSaadaftarMPanjepourM, et al.The effects of manufacturing parameters on geometrical and mechanical properties of copper foams produced by space holder technique. Mater Des2014; 53: 681–690.
45.
FerriereARodríguezGPSobrinoJA. Flux distribution delivered by a fresnel lens used for concentrated solar energy. J Sol Energy Eng2004; 126: 654–660.
46.
ISO 2738:1999. Sintered metal materials, excluding hardmetals - Permeable sintered metal materials - Determination of density, oil content and open porosity.
47.
U.-E. I. 4506:2018, «Materiales metálicos sinterizados, excepto metal duro. Ensayo de compresión» 2018.
48.
MichailidisNStergioudiF. Establishment of process parameters for producing Al-foam by dissolution and powder sintering method. Mater Des2011; 32: 1559–1564.
49.
HussainZSuffinNA. Microstructure and mechanical behavior of aluminum foam produced by sintering dissolution process using NaCl space holder. J Eng Sci2011; 7: 37–49.
50.
ZhaoYHanFFungT. Optimization of compaction and liquid-state sintering in sintering and dissolution process for manufacturing Al-foams. Mater Sci Eng A2004; 364: 117–125.
51.
KennedyA. Porous metals and metal foams made from powders. Powder Metall2012; 2: 31–46.
52.
TorresYPavónJRodríguezJA. Processing and characterization of porous titanium for implants by using NaCl as space holder. J Mater Process Technol2012; 212: 1061–1069.
53.
SunDXZhaoYY. Static and dynamic energy absorption of Cu foams produced by the sintering and dissolution process. Metall Mater Trans B2003; 34: 69–74.
54.
SinghSBhatnagarN. A survey of fabrication and application of metallic foams (1925–2017). J Porous Mater2018; 25: 537–554.
JiangBZhaoNQLiJJ. Processing of open cell foams with tailored porous morphology. Scr Mater2005; 53: 781–785.
57.
HongKKadarCKnapekM, et al.Comparison of morphology and compressive deformation behavior of copper foams manufactured via freeze-casting and space-holder methods. J Mater Res Technol2021; 15: 6855–6865.
58.
LiCWangYLiuZ, et al.Multifunctional open-cell copper foam with sphere pores by a modified sintering–dissolution process. Metals (Basel)2023; 13: 791.
