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Keywords = diamond–copper composites

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49 pages, 29145 KB  
Article
Standard Testwork Methodologies for Sensor-Based Particle Ore Sorting Project Development and Process Optimization
by Christopher Robben, Kim H. Esbensen, Simon C. Dominy, Marie-Claude Halle, Mike McCubbing and David Turner
Minerals 2026, 16(7), 678; https://doi.org/10.3390/min16070678 - 28 Jun 2026
Viewed by 346
Abstract
Sensor-based Particle Ore Sorting (POS) has gained significant acceptance as a unit process in mineral processing in recent years, particularly in the diamond, copper, tin, and tungsten sectors. The increased uptake has led to a steady increase in testwork volume since 2010. Testwork [...] Read more.
Sensor-based Particle Ore Sorting (POS) has gained significant acceptance as a unit process in mineral processing in recent years, particularly in the diamond, copper, tin, and tungsten sectors. The increased uptake has led to a steady increase in testwork volume since 2010. Testwork is the basis for all technical and financial evaluation of a potential business case for POS. To support the growing volume of POS testwork, this contribution develops standardized test methodologies and sampling requirements for different project stages. Our aim is to bridge the understanding and terminology between the various technical disciplines involved. This allows all stakeholders to enter the complex realm of POS with full transparency. Tests can be conducted using three different feed types: endmember samples, lithotype samples, and composite samples. Four testwork methods are presented for POS project development and optimization: Single Particle Test (SPT), Bench Scale Test (BST), Cascade Test (CT), and Process Test (PT). From the possible combinations, this results in ten POS testwork methods. Each test type serves a different purpose with regard to process effectiveness contributions and relationships to the project lot, serving specific roles during project stages from scoping to feasibility. Specific project parameters are recommended to be defined up front for future POS projects to improve clarity and interpretation of test objectives, limitations, and results. Full article
(This article belongs to the Topic New Advances in Mining Technology, 2nd Edition)
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21 pages, 6359 KB  
Article
Effects of Annealing Temperature on Interfacial Structure and Thermal Conductivity of Hot-Pressed Copper/Cr-Coated Diamond Composites
by Yajing Liu, Xiaohong Chen, Yong Liu, Wei Tian, Fanfan Zhou, Honglei Zhou and Yicheng Wang
Materials 2026, 19(8), 1534; https://doi.org/10.3390/ma19081534 - 11 Apr 2026
Viewed by 851
Abstract
Efficient heat dissipation is crucial for semiconductor devices; however, conventional thermal management materials often cannot meet practical demands because of inadequate thermal conductivity and mismatched coefficients of thermal expansion with semiconductor materials. In this study, we develop a synergistic process integrating magnetron sputtering [...] Read more.
Efficient heat dissipation is crucial for semiconductor devices; however, conventional thermal management materials often cannot meet practical demands because of inadequate thermal conductivity and mismatched coefficients of thermal expansion with semiconductor materials. In this study, we develop a synergistic process integrating magnetron sputtering and annealing to fabricate a composition-controllable Cr/Cr3C2 composite interlayer on diamond surfaces. By regulating the annealing temperature from 700 to 1100 °C, three key parameters of the Cr/Cr3C2 composite interlayer can be tailored: the thickness varies from ~200 to 800 nm, the Cr/Cr3C2 fraction is adjustable, and the surface roughness ranges from 33.3 to 61.6 nm. In the current research, the sample that was annealed at 900 °C for 2 h exhibited the highest coating uniformity, with carbide coverage exceeding 98% and no discernible porosity. This optimized annealing process produces an interlayer with robust coverage, moderate thickness (~300 nm), and low surface roughness (Ra = 33.3 nm), thereby markedly enhancing interfacial bonding and thermal-transport performance. The resulting composite achieves a maximum thermal conductivity of 605.27 W·m−1·K−1, corresponding to 211% of the experimentally measured value for the uncoated sample. Analyses combining the diffusion mismatch model and experimentation indicate that the enhancement originates from improved phonon spectral matching and increased interfacial adhesion energy. This work provides processing guidance for precise interface engineering in high-thermal-conductivity diamond/copper composites. Full article
(This article belongs to the Section Advanced Composites)
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16 pages, 4749 KB  
Article
High Thermal Conductivity Diamond–Copper Composites Prepared via Hot Pressing with Tungsten–Coated Interfacial Layer Optimization
by Qiang Wang, Zhijie Ye, Lei Liu, Jie Bai, Yuning Zhao, Qiang Hu, Hong Liu, Lang Hu, Xiaodong Guo, Yongneng Xiao, Wenxin Cao and Zhenhuai Yang
Materials 2025, 18(16), 3882; https://doi.org/10.3390/ma18163882 - 19 Aug 2025
Cited by 4 | Viewed by 3731
Abstract
Diamond–copper composites, due to their exceptional thermal conductivity, hold significant potential in the field of electronic device thermal management. Hot-press sintering is a promising fabrication technique with industrial application prospects; however, the thermal conductivity of composites prepared by this method has yet to [...] Read more.
Diamond–copper composites, due to their exceptional thermal conductivity, hold significant potential in the field of electronic device thermal management. Hot-press sintering is a promising fabrication technique with industrial application prospects; however, the thermal conductivity of composites prepared by this method has yet to reach optimal levels. In this study, tungsten was deposited on the surface of diamond particles by magnetron sputtering as an interfacial transition layer, and hot-press sintering was employed to fabricate the composites. The findings reveal that with prolonged annealing time, tungsten gradually transformed into W2C and WC, significantly enhancing interfacial bonding strength. When the diamond volume content was 50% and the interfacial coating consisted of 2 wt.% W, 92 wt.% WC, and 6 wt.% W2C, the composite exhibited a thermal conductivity of 640 W/(m·K), the highest value reported among hot-press sintered composites with diamond content below 50%. Additionally, the AMM (Acoustic Mismatch Model) and DMM (Diffusion Mismatch Model) models were utilized to calculate the interfacial thermal conductance between different phases, identifying the optimal interfacial structure as diamond/W2C/WC/W2C/Cu. This composite material shows potential for application in high-power electronic device cooling, thermal management systems, and thermoelectric conversion, providing a more efficient thermal dissipation solution for related devices. Full article
(This article belongs to the Section Advanced Composites)
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12 pages, 7645 KB  
Article
Searching Optimum Self-Brazing Powder Mixtures Intended for Use in Powder Metallurgy Diamond Tools—A Statistical Approach
by Andrzej Romański, Piotr Matusiewicz and Elżbieta Cygan-Bączek
Materials 2025, 18(12), 2726; https://doi.org/10.3390/ma18122726 - 10 Jun 2025
Viewed by 928
Abstract
This paper presents a study on optimising self-brazing powder mixtures for powder metallurgy diamond tools, specifically focusing on wire saws used in cutting natural stone. The research aimed to understand the relationship between the chemical composition of powder mixtures and the hardness of [...] Read more.
This paper presents a study on optimising self-brazing powder mixtures for powder metallurgy diamond tools, specifically focusing on wire saws used in cutting natural stone. The research aimed to understand the relationship between the chemical composition of powder mixtures and the hardness of the sintered matrix. The experimental process involved the use of various commercially available powders, including carbonyl iron, carbonyl nickel, atomised bronze, atomised copper, and ferrophosphorus. The samples made of different powder mixtures were compacted and sintered and then characterised by dimensional change, density, porosity, and hardness. The obtained results were statistically analysed using an analysis of variance (ANOVA) tool to create linear regression models that relate the material properties to their chemical composition. The investigated materials exhibited excellent sintering behaviour and very low porosity, which are beneficial for diamond retention. Very good sinterability of powder mixtures can be achieved by tin bronze addition, which provides a sufficient content of the liquid phase and promotes the shrinkage during sintering. Statistical analysis revealed that hardness was primarily affected by phosphorous content, with nickel having a lesser but still significant impact. The statistical model can predict the hardness of the matrix based on its chemical composition. This model, with a determination coefficient of approximately 80%, can be valuable for developing new metal matrices for diamond-impregnated tools, particularly for wire saw beads production. Full article
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20 pages, 6287 KB  
Article
Analysis of the Wear and Corrosion Resistance on Cu-Ni-Al Composites Reinforced with CeO2 Nanoparticles
by Carola Martínez, Bárbara Valverde, Aurora Del Valle-Rodríguez, Brennie Bustos-De La Fuente, Izabel Fernanda Machado and Francisco Briones
Materials 2025, 18(11), 2438; https://doi.org/10.3390/ma18112438 - 23 May 2025
Cited by 4 | Viewed by 1512
Abstract
This study evaluates the wear and corrosion resistance of the Cu-50Ni-5Al alloy reinforced with CeO2 nanoparticles for potential use as anodes in molten carbonate fuel cells (MCFCs). Cu–50Ni–5Al alloys were synthesized, with and without the incorporation of 1% CeO2 nanoparticles, by [...] Read more.
This study evaluates the wear and corrosion resistance of the Cu-50Ni-5Al alloy reinforced with CeO2 nanoparticles for potential use as anodes in molten carbonate fuel cells (MCFCs). Cu–50Ni–5Al alloys were synthesized, with and without the incorporation of 1% CeO2 nanoparticles, by the mechanical alloying method and spark plasma sintering (SPS). The samples were evaluated using a single scratch test with a cone-spherical diamond indenter under progressive normal loading conditions. A non-contact 3D surface profiler characterized the scratched surfaces to support the analysis. Progressive loading tests indicated a reduction of up to 50% in COF with 1% NPs, with specific values drop-ping from 0.48 in the unreinforced alloy to 0.25 in the CeO2-doped composite at 15 N of applied load. Furthermore, the introduction of CeO2 decreased scratch depths by 25%, indicating enhanced wear resistance. The electrochemical behavior of the samples was evaluated by electrochemical impedance spectroscopy (EIS) in a molten carbonate medium under a H2/N2 atmosphere at 550 °C for 120 h. Subsequently, the corrosion products were characterized using X-ray diffraction (XRD), scanning electron microscopy coupled with energy dispersive spectroscopy (SEM-EDS), and X-ray photoelectron spectroscopy (XPS). The results demonstrated that the CeO2-reinforced alloy exhibits superior electro-chemical stability in molten carbonate environments (Li2CO3-K2CO3) under an H2/N2 atmosphere at 550 °C for 120 h. A marked reduction in polarization resistance and a pronounced re-passivation effect were observed, suggesting enhanced anodic protection. This effect is attributed to the formation of aluminum and copper oxides in both compositions, together with the appearance of NiO as the predominant phase in the materials reinforced with nanoparticles in a hydrogen-reducing atmosphere. The addition of CeO2 nanoparticles significantly improves wear resistance and corrosion performance. Recognizing this effect is vital for creating strategies to enhance the material’s durability in challenging environments like MCFC. Full article
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14 pages, 4838 KB  
Article
Antibacterial and Film Characteristics of Copper-Doped Diamond-like Carbon Films via Sputtering Using a Mixed Target of Copper and Graphite
by Kazuya Kanasugi, Takayoshi Nakajima and Kenji Hirakuri
Coatings 2025, 15(5), 559; https://doi.org/10.3390/coatings15050559 - 7 May 2025
Cited by 2 | Viewed by 1507
Abstract
Copper-doped diamond-like carbon films (Cu-DLC) are effective antibacterial materials and are fabricated using different techniques. By controlling the ratio of the graphite and diamond structures as well as the hydrogen bonds, the biocompatibility, chemical stability, wear resistance, and high hardness of Cu-DLC can [...] Read more.
Copper-doped diamond-like carbon films (Cu-DLC) are effective antibacterial materials and are fabricated using different techniques. By controlling the ratio of the graphite and diamond structures as well as the hydrogen bonds, the biocompatibility, chemical stability, wear resistance, and high hardness of Cu-DLC can be regulated. In this study, three types of Cu-DLC films were deposited on SUS304 substrates using Ar-sputtering with mixed targets comprising different C/Cu ratios. The films’ structures, surface, and antibacterial properties were investigated using electron probe microanalysis, Raman and X-ray photoelectron spectroscopy, atomic force microscopy, and ball-on-disk tests. The Cu concentration in the Cu-DLC films increased with an increase in its content in the target; however, no significant differences were observed in the Raman spectra. The surface composition, roughness, and dynamic friction coefficients were similar across all Cu-DLC films, which displayed smoothness and friction properties similar to those of standard DLC films without Cu. The antibacterial activity (R value) was evaluated as per ISO 22196. Although DLC films exhibited no antibacterial activity (R < 2), all the prepared Cu-DLC films displayed good antibacterial activity (R ≥ 2). The proposed deposition process facilitated Cu-DLC coating, thus promoting its use in the healthcare fields. Full article
(This article belongs to the Special Issue Electrochemical Properties and Applications of Thin Films)
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11 pages, 8437 KB  
Article
An Investigation on the Spark Plasma Sintering Diffusion Bonding of Diamond/Cu Composites with a Cr Interlayer
by Ying Zhou, Daochun Hu, Minghe Chen, Taowen Wu, Jindong Ouyang and Degan Xiong
Materials 2024, 17(24), 6026; https://doi.org/10.3390/ma17246026 - 10 Dec 2024
Cited by 9 | Viewed by 2132
Abstract
Spark plasma sintering (SPS) is an effective technique for studying the diffusion bonding of diamond/Cu composites, and has the potential to advance the application of copper matrix composites. This study investigates the SPS diffusion bonding of diamond/Cu composites using a chromium (Cr) interlayer. [...] Read more.
Spark plasma sintering (SPS) is an effective technique for studying the diffusion bonding of diamond/Cu composites, and has the potential to advance the application of copper matrix composites. This study investigates the SPS diffusion bonding of diamond/Cu composites using a chromium (Cr) interlayer. The effects of process parameters on the microstructure and mechanical properties of the bonding interface were evaluated through shear strength testing and SEM analysis. The results show that shear strength increases with interlayer thickness up to a certain point, after which it decreases. As the bonding temperature, holding time, and bonding pressure increase, defects such as cracks and voids at the diffusion-bonded interface are reduced, resulting in improved shear strength. Under suitable conditions (10 μm interlayer, 810 °C, 60 min, and 10 MPa), the bonding interface is defect-free, achieving a maximum shear strength of 139.89 MPa and a thermal conductivity (TC) of 700.97 W/(m·K), indicating high-quality diffusion bonding. Full article
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13 pages, 4387 KB  
Article
Protective Magnetron Sputtering Physical Vapor Deposition Coatings for Space Application
by Beata Kucharska, Kamil Bochra, Tadeusz Wierzchoń and Jerzy Robert Sobiecki
Coatings 2024, 14(9), 1195; https://doi.org/10.3390/coatings14091195 - 16 Sep 2024
Cited by 4 | Viewed by 2297
Abstract
In this study, the use of Cr/CrN+CrCN/Cr-C:H, Cr/W-C:H, and Cr/CrN+Ag/Cr-C:H coatings deposited on copper beryllium were investigated. These protective coatings were prepared using the Magnetron Sputtering Physical Vapor Deposition (MSPVD) method. The tests were carried out in order to qualify the outer DLC [...] Read more.
In this study, the use of Cr/CrN+CrCN/Cr-C:H, Cr/W-C:H, and Cr/CrN+Ag/Cr-C:H coatings deposited on copper beryllium were investigated. These protective coatings were prepared using the Magnetron Sputtering Physical Vapor Deposition (MSPVD) method. The tests were carried out in order to qualify the outer DLC (Diamond-Like Carbon) layers for use as the protective function and for regulating the thermo-optical properties. The objective of this study was to compare the properties of chromium and chromium nitride-based coatings. The microstructure, architecture, and chemical composition were studied using scanning electron microscopy (SEM), Photo Diode BackScattered Electrons (PDBS), and X-ray dispersion spectroscopy (EDX). The adhesion was evaluated using a scratch test and a peel and pull-off method. The level of protection against the cold welding effect was tested. Thermo-optical, microhardness, and surface electric resistivity tests were performed. It was found that in cases where increased resistance to cold welding is required, DLC2 and DLC3 proved to be the best solutions. An example of such an application is tubular boom antennas, which are stored in a rolled-up form until deployed in space. They are susceptible to cold welding due to vibration during rocket launch and subsequent exposure to high vacuum. Full article
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17 pages, 8575 KB  
Article
RETRACTED: Cr–Diamond/Cu Composites with High Thermal Conductivity Fabricated by Vacuum Hot Pressing
by Qiang Xu, Xiaodie Cao, Yibo Liu, Yanjun Xu and Jiajun Wu
Materials 2024, 17(15), 3711; https://doi.org/10.3390/ma17153711 - 26 Jul 2024
Cited by 6 | Viewed by 3243 | Retraction
Abstract
Chromium-plated diamond/copper composite materials, with Cr layer thicknesses of 150 nm and 200 nm, were synthesized using a vacuum hot-press sintering process. Comparative analysis revealed that the thermal conductivity of the composite material with a Cr layer thickness of 150 nm increased by [...] Read more.
Chromium-plated diamond/copper composite materials, with Cr layer thicknesses of 150 nm and 200 nm, were synthesized using a vacuum hot-press sintering process. Comparative analysis revealed that the thermal conductivity of the composite material with a Cr layer thickness of 150 nm increased by 266%, while that with a Cr layer thickness of 200 nm increased by 242%, relative to the diamond/copper composite materials without Cr plating. This indicates that the introduction of the Cr layer significantly enhanced the thermal conductivity of the composite material. The thermal properties of the composite material initially increased and subsequently decreased with rising sintering temperature. At a sintering temperature of 1050 °C and a diamond particle size of 210 μm, the thermal conductivity of the chromium-plated diamond/copper composite material reached a maximum value of 593.67 W∙m−1∙K−1. This high thermal conductivity is attributed to the formation of chromium carbide at the interface. Additionally, the surface of the diamond particles in contact with the carbide layer exhibited a continuous serrated morphology due to the interface reaction. This “pinning effect” at the interface strengthened the bonding between the diamond particles and the copper matrix, thereby enhancing the overall thermal conductivity of the composite material. Full article
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29 pages, 9666 KB  
Article
Diatoms’ Diversity in the Assessment of the Impact of Diamond and Oil and Gas Mining on Aquatic Ecosystems of the Central Yakut Plain (Eastern Siberia, Yakutia) Using Bioindication and Statistical Mapping Methods
by Sophia Barinova, Viktor Gabyshev, Sergey Genkal and Olga Gabysheva
Diversity 2024, 16(8), 440; https://doi.org/10.3390/d16080440 - 24 Jul 2024
Cited by 3 | Viewed by 3065
Abstract
Diamond and oil and gas production carries risks to the aquatic ecosystem. In Eastern Siberia, on the territory of the Central Yakut Plain, mining development of the Yakut diamond-bearing province and Tas-Yuryakh oil and gas condensate field has been underway for several decades. [...] Read more.
Diamond and oil and gas production carries risks to the aquatic ecosystem. In Eastern Siberia, on the territory of the Central Yakut Plain, mining development of the Yakut diamond-bearing province and Tas-Yuryakh oil and gas condensate field has been underway for several decades. But the problem of studying negative consequences in the region is covered only from the point of view of the impact on terrestrial ecosystems. The purpose of this study was to assess the impact of diamond and oil and gas production on the aquatic ecosystems of the region using the bioindicative properties of diatoms. The work used previously widely tested methods of ecological mapping, JASP, and species–environments relationship analysis. The results of chemical analysis of water showed that in oil and gas production areas, there is no pollution with petroleum products, but the concentration of silicon and zinc is increased. The study identified key pollutants in the Central Yakut Plain and demonstrated the effectiveness of diatoms as bioindicators. Elevated chloride levels were found in diamond mining areas, and increased copper levels were noted in oil production regions. In the diatom flora of the region, 144 species were identified, of which 137 are indicator species. Natural and anthropogenic clusters of environmental factors are identified, characterized by a specific effect on the species composition and taxonomic structure of diatom communities. The results obtained are suitable for assessing the level of anthropogenic impact on aquatic communities of photosynthetic microorganisms in permafrost conditions. Full article
(This article belongs to the Special Issue Freshwater Biodiversity Hotspots in 2024)
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19 pages, 10295 KB  
Article
Production of Cu/Diamond Composite Coatings and Their Selected Properties
by Grzegorz Cieślak, Marta Gostomska, Adrian Dąbrowski, Katarzyna Skroban, Tinatin Ciciszwili-Wyspiańska, Edyta Wojda, Anna Mazurek, Michał Głowacki, Michał Baranowski, Anna Gajewska-Midziałek and Maria Trzaska
Materials 2024, 17(12), 2803; https://doi.org/10.3390/ma17122803 - 8 Jun 2024
Cited by 5 | Viewed by 2527
Abstract
This article presents Cu/diamond composite coatings produced by electrochemical reduction on steel substrates and a comparison of these coatings with a copper coating without diamond nanoparticles (<10 nm). Deposition was carried out using multicomponent electrolyte solutions at a current density of 3 A/dm [...] Read more.
This article presents Cu/diamond composite coatings produced by electrochemical reduction on steel substrates and a comparison of these coatings with a copper coating without diamond nanoparticles (<10 nm). Deposition was carried out using multicomponent electrolyte solutions at a current density of 3 A/dm2 and magnetic stirring speed of 100 rpm. Composite coatings were deposited from baths with different diamond concentrations (4, 6, 8, 10 g/dm3). This study presents the surface morphology and structure of the produced coatings. The surface roughness, coating thickness (XRF), mechanical properties (DSI), and adhesion of coatings to substrates (scratch tests) were also characterized. The coatings were also tested to assess their solderability, including their spreadability, wettability of the solder, durability of solder-coating bonds, and a microstructure study. Full article
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11 pages, 3321 KB  
Article
The Casting and Hot Forging of Low-Carbon Copper-Bearing Steel and Its Substructural Characterization
by Pawan Kumar, Mamookho Elizabeth Makhatha, Shivashankarayya Hiremath and Vishwanatha H. M.
J. Compos. Sci. 2023, 7(10), 414; https://doi.org/10.3390/jcs7100414 - 5 Oct 2023
Viewed by 2487
Abstract
The casting of metal alloys followed by hot forging is a widely used manufacturing technology to produce a homogeneous microstructure. The combination of mechanical and thermal energy envisages the microstructural properties of metal alloys. In the present investigation, a metal alloy of composition [...] Read more.
The casting of metal alloys followed by hot forging is a widely used manufacturing technology to produce a homogeneous microstructure. The combination of mechanical and thermal energy envisages the microstructural properties of metal alloys. In the present investigation, a metal alloy of composition 0.05C-1.52Cu-1.51Mn (in weight %) was cast in an induction furnace using a zirconia crucible. The melt pool was monitored using optical emission spectroscopy (OES) to maintain the desired composition. The as-cast block was then subjected to forging under a pneumatic hammer of 0.5 t capacity so that any casting defects were eliminated. The as-cast block was reheated to a temperature of 1050 °C and held at that temperature for 6 h to homogenize, followed by hammering with a 50% strain using a pneumatic hammer. The microhardness was calculated using a Vickers microhardness testing apparatus. The microstructure characterization of the processed alloy was carried out using an optical microscope, electron backscattered diffraction (EBSD), energy-dispersive X-ray spectroscopy (EDXA), and a transmission electron microscope (TEM). The sample for optical microscopy was cut using a diamond cutter grinding machine and surface polishing was carried out using emery paper. Further, mechanical polishing was performed to prepare the samples for EBSD using a TEGRAPOL polishing machine. The EBSD apparatus was operated at a 20 kV accelerating voltage, 25 mm from the gun, and with a 60 µ aperture size. HKL Technology Channel 5 Software was used for the post-processing of EBSD maps. The procedure of standard polishing for OES and TEM sample preparation was followed. Recrystallization envisages equiaxed grain formation in hot forging; hence, the strain-free grains were observed in the strained matrix. The lower distribution of recrystallized grains indicated that the driving force for recrystallization was not abundant enough to generate a fully recrystallized microstructure. The fractional distribution of the misorientation angle between 15 and 60° confirms the formation of grain boundaries (having a misorientation angle greater than 15°) and dislocations/subgrain/substructures (having a misorientation angle less than 15°). The fraction of misorientation angle distribution was higher between the angles 0.5 and 6.5°; afterwards, it decreased for higher angles. The substructure was observed in the vicinity of grain boundaries. The softening process released certain strains, but still, the dislocation was observed to be deposited mostly in the vicinity of grain boundaries and at the grain interior. The fine precipitates of the microalloying element copper were observed in the range of size in nanometers. However, the densities of these precipitates were limited and most of these precipitates were deposited at the grain interior. The microhardness of 210.8 Hv and mean subgrain size of 1.61 µ were observed the enhanced microhardness was due to the limited recrystallized grains and accumulation of dislocations/subgrain/substructures. Full article
(This article belongs to the Section Composites Modelling and Characterization)
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25 pages, 8091 KB  
Review
Progress in the Copper-Based Diamond Composites for Thermal Conductivity Applications
by Kang Chen, Xuesong Leng, Rui Zhao, Yiyao Kang and Hongsheng Chen
Crystals 2023, 13(6), 906; https://doi.org/10.3390/cryst13060906 - 1 Jun 2023
Cited by 43 | Viewed by 11620
Abstract
Copper-based diamond composites have been the focus of many investigations for higher thermal conductivity applications. However, the natural non-wetting behavior between diamond particles and copper matrix makes it difficult to fabricate copper-based diamond composites with high thermal conductivity. Thus, to promote wettability between [...] Read more.
Copper-based diamond composites have been the focus of many investigations for higher thermal conductivity applications. However, the natural non-wetting behavior between diamond particles and copper matrix makes it difficult to fabricate copper-based diamond composites with high thermal conductivity. Thus, to promote wettability between copper and diamond particles, the copper/diamond interface must be modified by coating alloying elements on the diamond surface or by adding active alloying elements with carbon in the copper matrix. In this paper, we review the research progress on copper-based diamond composites, including theoretical models for calculating the thermal conductivity and the effect of process parameters on the thermal conductivity of copper-based diamond composites. The factors that affect interfacial thermal conductivity are emphatically analyzed in this review. Finally, the current problems of copper-based diamond composites and future research trends are recommended. Full article
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13 pages, 3536 KB  
Article
The Influence of the Carbide-Forming Metallic Additives (W, Mo, Cr, Ti) on the Microstructure and Thermal Conductivity of Copper–Diamond Composites
by Arina V. Ukhina, Dina V. Dudina, Maksim A. Esikov, Dmitrii A. Samoshkin and Sergei V. Stankus
J. Compos. Sci. 2023, 7(6), 219; https://doi.org/10.3390/jcs7060219 - 26 May 2023
Cited by 11 | Viewed by 3030
Abstract
In this study, carbide-forming metallic additives (W, Mo, Cr, Ti) were introduced into the copper matrix to improve the wettability of diamond particles in the copper–diamond composites. The samples were prepared by Spark Plasma Sintering (SPS) and Hot Pressing (HP) at 920 °C. [...] Read more.
In this study, carbide-forming metallic additives (W, Mo, Cr, Ti) were introduced into the copper matrix to improve the wettability of diamond particles in the copper–diamond composites. The samples were prepared by Spark Plasma Sintering (SPS) and Hot Pressing (HP) at 920 °C. The phase composition, microstructure and thermal conductivity of the samples were investigated. The influence of the carbide-forming additive concentration, the sintering method as well as the nature of the metal introduced into the copper matrix on the thermal conductivity of copper–diamond composites was determined. Titanium ensured a more significant wettability improvement at the copper–diamond interface. This is due to its higher solubility in copper in comparison with other metals (W, Mo, Cr) and the possibility of its diffusion through the copper matrix to the diamond surface resulting in the formation of a closer contact at the copper–diamond interface. Full article
(This article belongs to the Section Metal Composites)
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18 pages, 9254 KB  
Article
Mechanical Alloying of Copper- or Iron-Based Metallic Binders for Diamond Tools
by Pyotr Vityaz, Svetlana Kovaliova, Viktor Zhornik, Tatiana Grigoreva and Nikolay Lyakhov
Powders 2023, 2(2), 403-420; https://doi.org/10.3390/powders2020024 - 22 May 2023
Cited by 4 | Viewed by 3726
Abstract
Powder mixtures based on copper or iron are used as metal binder materials in the manufacturing of abrasive and cutting tools. This article discusses some aspects and possibilities of using a high-energy ball milling process to modify the structure and properties of Cu-Sn, [...] Read more.
Powder mixtures based on copper or iron are used as metal binder materials in the manufacturing of abrasive and cutting tools. This article discusses some aspects and possibilities of using a high-energy ball milling process to modify the structure and properties of Cu-Sn, Cu-Sn-Ti and Fe-Ti powders, their sintered materials and composites with diamond. The structures of powders and sintered materials, as well as the binder-to-diamond interfaces in metal matrix composites with diamond fillers, were studied by XRD analysis, scanning electron microscopy and X-ray spectroscopy. Tribological properties and thermal stability of materials in the temperature range of 250–800 °C were investigated. Various mechanisms of dispersion strengthening during the heating of sintered materials are described. It is shown that due to the grain boundary distribution of titanium, it is possible to obtain single-phase powders in the form of a supersaturated solid solution of CuSn20Ti5 and FeTi20, which ensure the formation of thermally hardened alloys with a microhardness of 357–408 HV and 561–622 HV, respectively, in the temperature range of 350–800 °C. The wear resistance of sintered powder alloys increases more than twice. Furthermore, the simultaneous enhancement in both the strength and ductility of metal–diamond titanium-containing composites is achieved through the nanostructural state and the formation of a thin layer (up to 2 μm) of titanium carbide at the interface between the metal matrix and diamond. The developed alloy shows great potential as a binder in diamond tools which are designed for machining abrasive materials. Full article
(This article belongs to the Special Issue Particle Technologies)
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