Your search keyword '"DIAMOND-LIKE CARBON"' showing total 10,025 results

1. Cathode cooling effects on the neutron production rate in the glow discharge type of fusion neutron source.

Author

Sakabe, Toshiro, Ishii, Takaya, Mukai, Keisuke, and Yagi, Juro

Subjects

*NUCLEAR fusion, *COOLING of water, *DIAMOND-like carbon, *NEUTRON sources, *COOLING systems, *DEUTERIUM

Abstract

Fusion reactions on the cathode surface of glow discharge deuterium–deuterium fusion neutron sources contribute significantly to the neutron production rate (NPR). While the NPR shows a linear relationship with current in the low current regime, a rise in cathode temperature in the high-current regime causes stagnation of the NPR. This tendency may be caused by high-temperature-induced desorption of deuterium on the cathode. This study aims to clarify the relationship between NPR and deuterium desorption. The present study utilized a water-cooling system to prevent deuterium desorption on the cathode. A stainless-steel 304 cathode and a diamond-like carbon (DLC)-coated cathode were tested. The cooling system kept the cathode temperature below 315 K throughout the experiment. In the case of the DLC-coated cathode, the water-cooling system improves the NPR in a high-current regime (30 mA or more in the present study). At 50 kV and 60 mA, the NPRs were 1.87 × 106 and 8.39 × 105 (n/s), with and without water cooling, respectively. Furthermore, without the cooling system, the NPR correlation with the cathode temperature indicates good agreement with the estimation model of deuterium desorption on the DLC-coated cathode. This study demonstrates that suppression of deuterium desorption in the cathode improves NPR, especially in the high-current regime. [ABSTRACT FROM AUTHOR]

Published

2024

2. Diamond-like carbon conversion surfaces for space applications.

Author

Sokół, Justyna M., Lin, Jianliang, Fuselier, Stephen A., Eliason, Travis, Gomez, John E., Rodriguez, Benjamin, Pham, John N, Schiferl, Clark, Rincon, Christopher, Bernier, Cedric, Andersson, Caden, Mendoza, Felicia, Gasser, Jonathan, Wurz, Peter, Galli, André, Hertzberg, Eric, and Schwadron, Nathan A.

Subjects

*DIAMOND-like carbon, *SURFACE coatings, *ANGULAR distribution (Nuclear physics), *ION beams, *SURFACE roughness, *DIAMOND crystals

Abstract

We present diamond-like carbon (DLC) conversion surfaces to detect particles with energy below 2 keV. Conversion surfaces have been widely applied in measurements of low-energy particles by instruments onboard planetary and heliophysics missions. Their effectiveness is characterized by the efficiency in changing the charge state of the incident particles while maintaining a narrow angular distribution for the reflected particles. DLC as a conversion surface coating material has high conversion efficiency. We developed a conversion surface production process that provides ultra-smooth and ultra-thin DLC conversion surfaces. The process includes substrate preparation through precision cleaning, plasma immersion ion deposition of the DLC film, and diagnostics of the film parameters. The latter includes the measurement of the coating thickness, surface roughness, and the conversion efficiency for ion beams with energy below 2 keV. The process we developed provides the DLC conversion surface coating of repeatable parameters with a mean surface roughness of 3.4 ± 0.2 Å and a mean film thickness of 46.7 ± 0.8 nm uniform across the sample area. Ion beam measurements showed a negative ion yield of 1%–2% for hydrogen atoms and 8%–15% for oxygen atoms with an angular scatter distribution of 10°–20° at full width of half maximum. These results agree with those of other conversion surface coatings in the literature. The DLC conversion surfaces presented here are implemented in the conversion surface subsystem of the Interstellar Mapping and Acceleration Probe (IMAP)-Lo instrument of the IMAP mission scheduled for launch in 2025. [ABSTRACT FROM AUTHOR]

Published

2024

3. Synergistic lubrication of diamond-like carbon and poly-α-olefin oil: Coupled dependence on oil viscosity and applied load.

Author

Ding, Jiaqing, Lu, Shiqi, Chen, Zan, Wei, Xubing, Zhang, Haolin, Guo, Peng, Feng, Cunao, Chen, Kai, Lee, Kwang-Ryeol, and Li, Xiaowei

Subjects

*DIAMOND-like carbon, *VISCOSITY, *GRAPHITIZATION, *SURFACE states, *MICROSTRUCTURE, *LUBRICATION systems

Abstract

Diamond-like carbon (DLC)/poly-α-olefin (PAO) composite system attracts much attention in reducing the tribo-induced risks for mechanical mobility systems and energy saving. However, the coupled effect of applied load and PAO viscosity on the tribological behavior of the DLC/PAO system, which normally causes the transition between different lubrication states of mated surfaces, and the corresponding synergistic mechanism remain unclear. Here, we fabricated the DLC/PAO composite system, and the evolutions of microstructure, morphologies, and tribological properties induced by both PAO viscosity and applied load were investigated systematically. Results indicated that under low applied load, the system with moderate PAO viscosity exhibited the best tribological performance, while the PAO with high viscosity was suggested with increasing the applied load. Moreover, the variations of PAO viscosity and applied load seriously affected the distribution and load-bearing capacity of oil, interfacial graphitization degree, and formation of lubricating oil film, which brought complicated effects on the tribological properties of composite systems. The present results guide the selection and design of an advanced DLC/PAO lubrication system according to the working conditions. [ABSTRACT FROM AUTHOR]

Published

2024

4. Influence of the base pressure in deposition of a‐SiCx interlayers for adhesion of Diamond‐Like Carbon on metallic alloy.

Author

Weber, Jennifer Stefani, Goldbeck, Michael Cristian, Piroli, Vanessa, Boeira, Carla Daniela, Perotti, Bruna Louise, Fukumasu, Newton Kiyoshi, Alvarez, Fernando, Michels, Alexandre Fassini, and Figueroa, Carlos Alejandro

Subjects

*IRON alloys, *ALLOYS, *AMORPHOUS substances, *AMORPHOUS silicon, *IMPACT loads, *DIAMOND-like carbon

Abstract

Diamond‐like carbon (DLC) is an amorphous material widely used in industrial applications due to its chemical, mechanical, and tribological properties and, also, for decorative purposes. However, its low adhesion to ferrous alloys reduces its effectiveness in certain applications, necessitating the use of adhesion interlayers to reduce stresses at the interfaces and enhance the density of strong bonds. In this context, the factors that promote good adhesion in this system and specify the parameters must be understood in detail. Thus, the present study aims to assess the influence of the base pressure on the deposition of an amorphous silicon carbide adhesion interlayer between DLC coating and a ferrous alloy substrate. Microstructural, physicochemical, morphological, and mechanotribological analyses were conducted to understand the adhesion behavior in terms of structural and chemical aspects. In addition to the influence of the interlayer thickness, the elemental Si/C ratios and the relative oxygen content have an impact on the maximum load supported by the coatings, as well as the different delamination mechanisms generated in adhesion tests. [ABSTRACT FROM AUTHOR]

Published

2024

5. Construction of a Composite Sn‐DLC Artificial Protective Layer with Hierarchical Interfacial Coupling Based on Gradient Coating Technology Toward Robust Anodes for Zn Metal Batteries.

Author

Guo, Xiuli, Peng, Qiaoling, Shin, Kyungsoo, Zheng, Ye, Tunmee, Sarayut, Zou, Caineng, Zhou, Xiaolong, and Tang, Yongbing

Subjects

*CHEMICAL bonds, *POTENTIAL energy, *INTERFACE stability, *DENDRITIC crystals, *COMPOSITE construction

Abstract

Developing a robust zinc (Zn) anode, free from Zn dendrites and unwanted side reactions, relies on designing a durable and efficient interfacial protection layer. In this study, gradient coating technology is employed to construct a hierarchically structured composite of Sn with diamond‐like carbon (DLC/Sn‐DLC) as an artificial protective layer. The DLC framework endows DLC/Sn‐DLC layer with high stability and adaptability, achieving long‐term stability of the anode–electrolyte interface. The gradual‐composite Sn, with its Sn─O─C interface chemical bonds, facilitates rapid charge transfer and offers ample zincophilic sites at the base, promoting uniform Zn2+ reduction reaction and deposition. Additionally, the DLC/Sn‐DLC composite exhibits a "lotus effect" and favorable hydrophobic properties, preventing water‐reduced side reactions. Leveraging this structural design and the synergistic cooperation of DLC and Sn, the DLC/Sn‐DLC@Zn electrode demonstrates remarkable Zn plating/stripping reversibility, eliminating Zn dendrites and side reactions. Notably, under a high current density of 10 mA cm−2, the DLC/Sn‐DLC@Zn anode‐based symmetrical cell exhibits stable operation for over 1550 h, with a low nucleation overpotential of 101 mV. The DLC/Sn‐DLC@Zn||Mn3O4‐CNTs full battery delivers a high capacity of 109.8 mAh cm−2 after 5800 cycles at 2 A g−1, and the pouch cell shows potential for energy storage applications. [ABSTRACT FROM AUTHOR]

Published

2024

6. Experimental Verification of Inter Relation between Fowler–Nordheim and Millikan–Lauritsen Plot in Chemically Synthesized Zinc Oxide System.

Author

Kumar, Pankaj and Banerjee, Diptonil

Subjects

*FIELD emission, *DIAMOND-like carbon, *ZINC oxide, *BAND gaps, *X-ray diffraction

Abstract

Cold cathode emission or cold field emission (CFE) is a purely quantum mechanical phenomenon and a phenomenon of wonder. The exact science behind the observed current (I)–voltage (V) is yet to be pin pointed. For instance, a good cold emitter is very reasonably supposed to have low work function and good conductivity whereas a carbon allotropes like diamonds have just the reverse in both the cases, i.e., it is insulating in nature having very wide band gap as well as high work function yet it is considered to be an efficient field emitter. Since early of 20th century, till its middle a number of groups have suggested different equations or relations that can adequately describe the experimental CFE I–V characteristics adequately. Although they all fundamentally follow an exponential law, but so far, the relation suggests by Fowler and Nordheim (F–N) is the most accepted one. However, there is another relationship suggested by Millikan and Lauritsen (M–L) which is in spite of being reasonable not so common now a day to use. This work revisits different popular approaches for analyzing cold emission data. With this aim, the experimental CFE data obtained for chemically synthesized zinc oxide nanorods are chosen. The proper phase formation of ZnO is confirmed by XRD study whereas FESEM shows the rod like morphology. EDX confirms the proper stoichiometric ratio for the sample. After detail analysis it is confirmed that the theoretically proposed relation between F–N and M–L experimentally holds good as well and thus it would not be wrong to analyze the CFE data by simple M–L theory. [ABSTRACT FROM AUTHOR]

Published

2024

7. Quantum Cone—A Nano-Source of Light with Dispersive Spectrum Distributed along Height and in Time.

Author

Medvids, Arturs, Ščajev, Patrik, and Hara, Kazuhiko

Subjects

*LIGHT sources, *DIAMOND-like carbon, *ELECTRIC fields, *EXCITON theory, *MOLECULAR spectra, *QUANTUM dots

Abstract

We study a quantum cone, a novel structure composed of multiple quantum dots with gradually decreasing diameters from the base to the top. The dot distribution leads to a dispersive radiated spectrum. The blue edge of the spectrum is determined by the quantum confinement of excitons on top of the cones, while the red edge is determined by the bandgap of a semiconductor. We observe the kinetics of photoluminescence by obeying the stretch-exponential law from quantum cones formed on the surface of diamond-like carbon (DLC). They are explained by an increase in the lifetime of excitons along the height of the cone from the top to the base of the cone and an increasing concentration of excitons at the base due to their drift in the quasi-built-in electric field of the quantum cone. The possible visualization of the quantum cone tops of DLC using irradiation by a UV light source is shown. A quantum cone is an innovative nano-source of light because it substitutes for two elements in a conventional spectrometer: a source of light and a dispersive element—an ultrafast monochromator. These features enable the building of a nano-spectrometer to measure the absorbance spectra of virus and molecule particles. [ABSTRACT FROM AUTHOR]

Published

2024

8. Optimizing gas pressure for enhanced tribological properties of DLC-coated graphite.

Author

Samiee, M., Seyedraoufi, Z. S., Abbasi, M., Eshraghi, M. J., and Abouei, V.

Subjects

*PLASMA-enhanced chemical vapor deposition, *RAMAN microscopy, *NANOINDENTATION tests, *HARDNESS testing, *RAMAN spectroscopy

Abstract

In this study, for the first time, the optimization of applied pressure for achieving the one of the best tribological properties of diamond-like carbon (DLC) coating on graphite surface using plasma-enhanced chemical vapor deposition (PECVD) method was investigated. Raman spectroscopy and microscopy methods were used to characterize the applied coating. Additionally, the mechanical properties of the coating were investigated through nanoindentation testing. The wear resistance of coating has been tested as functional test. The results indicated that with increasing gas pressure, the sp3 hybridization percentage decreases, while the ID/IG ratio increases. The average roughness values for the uncoated sample and the coated samples at working pressures of 25, 30, and 35 mTorr were obtained as 1.6, 5.1, 3, and 2.4 nm, respectively. The results of hardness and wear tests showed that these properties were optimized by reducing the applied gas pressure. The highest hardness was 11.59 GPa, and the best sample in terms of the mechanical properties of the coating was the sample applied at a gas pressure of 25 mTorr. Results show that the optimal sample in tribological performance is the one applied at a working pressure of 25 mTorr. Because this sample demonstrates the lowest coefficient of friction, and wear depth. [ABSTRACT FROM AUTHOR]

Published

2024

9. Submillimeter‐Scale Superlubric Triboelectric Nanogenerator.

Author

Bu, Tianzhao, Deng, Wenli, Liu, Yaoyao, Wang, Zhong Lin, Chen, Xinchun, and Zhang, Chi

Subjects

*MECHANICAL energy, *JOINTS (Anatomy), *ENERGY harvesting, *POWER density, *DIELECTRICS

Abstract

Triboelectric nanogenerator (TENG) for mechanical energy harvesting has been regarded as one of the most prospective energy technologies for the new era. However, inevitable material wear during triboelectrification results in output reduction and even failure of the TENG. In this work, a submillimeter‐scale superlubric TENG (SS‐TENG) is reported that enables ultra‐low friction coefficient (µ) and stable power generation. By using the micro/nano‐processing technology, the interdigital electrodes are embedded into the dielectric layer as a flat surface, on which the highly‐hydrogenated diamond‐like carbon (PLC) is deposited as the triboelectric layer to effectively reduce the friction coefficient. The frictional properties are systematically investigated at different parameters, in which a submillimeter‐scale (130 µm) superlubricity state (µ = 0.0084) is achieved at 4 N, 2 Hz and nitrogen atmosphere. Meanwhile, the SS‐TENG has a maximum power density of 3 mW m−2, which can remain stable at the superlubric condition. This work has first realized the freestanding‐mode superlubric TENG in submillimeter scale and provided a viable strategy for the development of long‐lifetime TENG, which may have great applications in frictional energy recovery from mechanical components, human joint motion, and the natural environment. [ABSTRACT FROM AUTHOR]

Published

2024

10. Multilayer Diamond‐Like Carbon Films on Monocrystalline Diamond.

Author

Okhapkin, Andrey, Drozdov, Mikhail, Yunin, Pavel, Kraev, Stanislav, Korolyov, Sergey, and Radishev, Dmitry

Subjects

*SECONDARY ion mass spectrometry, *DIAMOND films, *CARBON films, *SUBSTRATES (Materials science), *DEPTH profiling

Abstract

Multilayer films of diamond‐like carbon (DLC) on monocrystalline diamond substrates have been for the first time obtained by plasma‐chemical deposition. Their chemical composition and structural and morphological properties are studied. The DLC individual layers differ in their sp3 carbon content. The multilayer nature of the resulting coatings is confirmed by periodic density modulation on the small‐angle X‐ray reflectometry curve and modulations in the CsC8, CsC6, CsC4 lines on the crater depth profile of secondary ions of elements (secondary ion mass spectrometry). The dependence of the deposition rate of multilayer DLC films on diamond, their composition and properties on the argon additive to the reaction gas mixture, as well as on methane flow, pressure and growth time, are studied. [ABSTRACT FROM AUTHOR]

Published

2024

11. Influence of the Metallic Sublayer on Corrosion Resistance in Hanks' Solution of 316L Stainless Steel Coated with Diamond-like Carbon.

Author

Dobruchowska, Ewa, Schulz, Justyna, Zavaleyev, Viktor, Walkowicz, Jan, Suszko, Tomasz, and Warcholinski, Bogdan

Subjects

*METAL coating, *CARBON films, *THIN films, *CORROSION resistance, *SUBSTRATES (Materials science), *DIAMOND-like carbon

Abstract

The purpose of the study was to ascertain the corrosion resistance in Hanks' solution of Cr-Ni-Mo stainless steel (AISI 316L) coated with diamond-like carbon (DLC) coatings to establish its suitability for biomedical applications, e.g., as temporary implants. The influence of the carbon coating thickness as well as the correlated effect of the metallic sublayer type and defects present in DLC films on corrosion propagation were discussed. The results obtained were compared with findings on the adhesion of DLC to the steel substrate. The synthesis of carbon thin films with Cr and Ti adhesive sublayers was performed using a combined DC and a high-power-impulse vacuum-arc process. Evaluation of the corrosion resistance was carried out by means of potentiodynamic polarisation tests and scanning electron microscopy. Adhesive properties of the sublayer/DLC coating systems were measured using a scratch tester. It was found that systems with Ti sublayers were less susceptible to the corrosion processes, particularly to pitting. The best anti-corrosion properties were obtained by merging Ti with a DLC coating with a thickness equal to 0.5 μm. The protective properties of the Cr/DLC systems were independent of the carbon coating thickness. On the other hand, the DLC coatings with the Cr sublayer showed better adhesion to the substrate. [ABSTRACT FROM AUTHOR]

Published

2024

12. Durable and High‐Performance Triboelectric Nanogenerator Based on an Inorganic Triboelectric Pair of Diamond‐Like‐Carbon and Glass.

Author

Li, Wenjian, Lu, Liqiang, Zhang, Chi, Loos, Katja, and Pei, Yutao

Subjects

*NANOGENERATORS, *ENERGY harvesting, *POWER density, *INTERFACE structures, *CHARGE transfer

Abstract

The long‐term durability of triboelectric nanogenerators (TENGs) remains a main challenge for practical applications because of inevitable material abrasion and wear, especially for sliding TENGs. Herein, an inorganic triboelectric pair composed of diamond‐like carbon (DLC) and glass with excellent durability and triboelectric output for sliding‐mode TENGs is proposed. This triboelectric pair possesses a low coefficient of friction and little abrasion and accordingly excellent durability (>500 000 cycles). Moreover, compared with the traditional copper‐polytetrafluoroethylene (Cu‐PTFE) TENG with maximum transferred charges of 50 nC, those of the DLC‐glass TENG reaches 141 nC. Due to the low‐friction and high hardness of the triboelectric pair, the output quickly recovers after simply cleaning wear debris. The DLC‐glass TENG demonstrates an output power density of 530 mW m−2 and a fourfold faster capacitor charging speed than the Cu‐PTFE TENG. Compared to the reported durable TENGs via structure optimization and interface lubrication, the DLC‐glass TENG shows higher outputs and simpler structure. This DLC‐glass pair structure is also introduced into a spherical TENG for blue energy harvesting with excellent durability. The inorganic triboelectric pair with excellent mechanical durability and electrical performance proposed in this work shows huge prospects for practical applications of TENGs. [ABSTRACT FROM AUTHOR]

Published

2024

13. Macroscale Superlubricity with High Pressure Enabled by Partially Oxidized Violet Phosphorus for Engineering Steel.

Author

Zhang, Yi, Chen, Hao, Gao, Kai, Li, Yunze, Jiao, Jianguo, Xie, Guoxin, and Luo, Jianbin

Subjects

*ADSORPTION (Chemistry), *LUBRICANT additives, *AMORPHOUS carbon, *OLEIC acid, *CHARGE carrier mobility, *DIAMOND-like carbon

Abstract

As a novel cross‐structured 2D material, violet phosphorus (VP) promises to further develop the dynamic performance, energy efficiency, and service lifetime of mechanical components owing to its high strength and toughness, large carrier mobility, wide bandgap, and good friction‐reducing properties. In this work, the partially oxidized violet phosphorus nanosheets (oVP) are synthesized and employed as the lubricating additives in the poly alpha olefin (PAO) oil environment with less oleic acid (OA) improver, which can trigger the macroscale superlubricity on the diamond‐like carbon (DLC) film deposited steel surface at high loading pressures (>800 MPa) and sliding speeds (>0.1 m s−1). The friction coefficient (COF) of the steel‐DLC tribopair lubricated by the oVP‐PAO oil can reduce down to 0.0064 with little wear. At the high‐pressure sliding interface, the force‐thermal coupling action during the running‐in process promotes the cleavage and recombination of oVP nanosheets and OA molecules to form a reliable chemical adsorption tribofilm mainly composed of phosphorus oxides and amorphous carbon, which prevents the original asperities from direct contact and provides an ultralow shear strength. These findings suggest a new method to achieve macroscale oil‐based high‐pressure superlubricity for engineering steel through the lubrication and catalyzation effects of oVP. [ABSTRACT FROM AUTHOR]

Published

2024

14. Application of x-ray energy dispersive spectroscopy to analyzing the thickness of diamond-like carbon film deposited on the surface of microparticles.

Author

Zhao, Junping, An, Zhengjie, Ai, Zhijun, Wu, Zhicheng, and Zhang, Qiaogen

Subjects

*DIAMOND-like carbon, *ENERGY dispersive X-ray spectroscopy, *SURFACE coatings, *ELECTRONS

Abstract

Depositing diamond-like carbon (DLC) film is considered to be more promising for surface modification of microparticles. The development of reliable and precise measurement techniques for DLC coatings on microparticles is crucial for advancing research in this field. This paper introduces a methodological approach for quantifying the thickness of the film on microparticles. The thickness of the film is obtained by establishing the quantitative relationship between the energy lost when electrons pass through the film and the thickness of the film. The proposed method allows for the estimation of film thickness by assessing solely the elemental abundance on the particle surfaces. [ABSTRACT FROM AUTHOR]

Published

2024

15. Elevated Temperature Tribological Behavior of Duplex Layer CrN/DLC and Nano Multilayer DLC-W Coatings Deposited on Carburized and Hardened 16MnCr5 Steel.

Author

Kolawole, Funsho Olaitan, Kolawole, Shola Kolade, Fukumasu, Newton Kiyoshi, Varela, Luis Bernardo, Vencovsky, Paulo Konrad, Ludewigs, Danilo Assad, de Souza, Roberto Martins, and Tschiptschin, André Paulo

Subjects

ADHESIVE wear, INTERNAL combustion engines, MECHANICAL wear, WEAR resistance, MATERIAL plasticity, DIAMOND-like carbon

Abstract

This study investigates the impact of temperature on the tribological performance of duplex layer CrN/DLC and nano-multilayers DLC-W coatings deposited using hybrid PVD-PECVD techniques on carburized and hardened 16MnCr5 discs cut from internal combustion engines valve tappets. Reciprocating dry sliding experiments were conducted at 25 °C, 150 °C, 200 °C, and 250 °C to analyze the high-temperature tribological behavior of the coatings. The wear mechanisms were characterized using SEM, EDS mapping, Raman spectroscopy, and nanoindentation. The lowest coefficient of friction was obtained for CrN/DLC at 25 °C. The CrN/DLC coefficients of friction (COF) increase with temperatures due to increasing adhesive wear. Similarly, DLC-W exhibited a comparable trend with increasing temperature from 25 °C to 250 °C. Both coatings' wear resistance decreased with higher temperatures due to the transformation of sp3 C bonds to sp2 C bonds, facilitating the plastic deformation of the coatings and afterward of the substrate. The CrN/DLC displayed superior wear resistance to the DLC-W coating across all temperatures. The DLC-W multilayer coating showed poor wear resistance above 150 °C, being completely removed during the testing. Compared to both coatings, the uncoated 16MnCr5 discs exhibited higher coefficients of friction and wear rates at all temperatures. Predominant wear mechanisms observed in the coated discs were adhesive and abrasive. The study revealed a decrease in the coatings' structural and mechanical properties with rising temperatures. Hard abrasive WC particles were identified as contributing to increased wear rates in the multilayer DLC-W coatings. [ABSTRACT FROM AUTHOR]

Published

2024

16. Impact of Diamond-like Carbon Films on Reverse Torque: Superior Performance in Implant Abutments with Internal Conical Connections.

Author

Coelho, Arianne Vallim Pinto, Figueiredo, Viviane Maria Gonçalves de, Ferreira, Leandro Lameirão, Silva, Alecsandro de Moura, Oliani, Marcelo Gallo, Queiroz, José Renato Cavalcanti de, Sobrinho, Argemiro Soares da Silva, Nogueira Junior, Lafayette, and Prado, Renata Falchete do

Subjects

CHEMICAL vapor deposition, DENTAL abutments, SOLID lubricants, DENTAL implants, SCANNING electron microscopy, DIAMOND-like carbon

Abstract

The loosening or fracture of the prosthetic abutment screw is the most frequently reported complication in implant dentistry. Thin diamond-like carbon (DLC) films offer a low friction coefficient and high wear resistance, functioning as a solid lubricant to prevent the weakening of the implant–abutment system. This study evaluated the effects of DLC nanofilms on the reverse torque of prosthetic abutments after simulated chewing. Abutments with 8° and 11° taper connections, with and without DLC or silver-doped DLC coatings, were tested. The films were deposited through the plasma enhanced chemical vapor deposition process. After two million cycles of mechanical loading, reverse torque was measured. Analyses with scanning electron microscopy were conducted on three samples of each group before and after mechanical cycling to verify the adaptation of the abutments. Tribology, Raman and energy-dispersive spectroscopy analyses were performed. All groups showed a reduction in insertion torque, except the DLC-coated 8° abutments, which demonstrated increased reverse torque. The 11° taper groups experienced the most torque loss. The nanofilm had no significant effect on maintaining insertion torque, except for the DLC8 group, which showed improved performance. [ABSTRACT FROM AUTHOR]

Published

2024

17. Tribological Comparison of Coatings Produced by PVD Sputtering for Application on Combustion Piston Rings.

Author

Ferreira, Ney Francisco, Fernandes, Filipe, Neis, Patric Daniel, Poletto, Jean Carlos, Yaqub, Talha Bin, Cavaleiro, Albano, Vilhena, Luis, and Ramalho, Amilcar

Subjects

PISTON rings, BOUNDARY lubrication, DRY friction, DOPING agents (Chemistry), ENERGY consumption, DIAMOND-like carbon

Abstract

This article compares the tribological performance of coatings produced by PVD sputtering. Transition metal dichalcogenide (TMD) coatings doped with carbon (WSC and MoSeC) and nitrogen (WSN and MoSeN) and a conventional diamond-like carbon (DLC) coating are compared. The tribological evaluation was oriented towards the use of coatings on piston rings. Block-on-ring tests in a condition lubricated with an additive-free polyalphaolefin (PAO 8) and at temperatures of 30, 60, and 100 °C were carried out to evaluate the coatings in boundary lubrication conditions. A load scanner test was used to evaluate dry friction and scuffing propensity. In addition to WSN, all other TMD coatings (WSC, MoSeC, and MoSeN) exhibited lower friction than DLC in dry and lubricated conditions. The study reveals that WSC, among TMD coatings, offers promising results, with significantly lower friction levels than DLC, while demonstrating reduced wear and a lower risk of metal adhesion. These findings suggest that WSC may be a viable alternative to DLC in piston rings, with potential benefits for reducing fuel consumption and increasing engine durability. [ABSTRACT FROM AUTHOR]

Published

2024

18. Optimizing gas pressure for enhanced tribological properties of DLC-coated graphite

Author

M. Samiee, Z. S. Seyedraoufi, M. Abbasi, M. J. Eshraghi, and V. Abouei

Subjects

Graphite, Diamond-like carbon, PECVD, Wear, Friction coefficient, Medicine, Science

Abstract

Abstract In this study, for the first time, the optimization of applied pressure for achieving the one of the best tribological properties of diamond-like carbon (DLC) coating on graphite surface using plasma-enhanced chemical vapor deposition (PECVD) method was investigated. Raman spectroscopy and microscopy methods were used to characterize the applied coating. Additionally, the mechanical properties of the coating were investigated through nanoindentation testing. The wear resistance of coating has been tested as functional test. The results indicated that with increasing gas pressure, the sp3 hybridization percentage decreases, while the ID/IG ratio increases. The average roughness values for the uncoated sample and the coated samples at working pressures of 25, 30, and 35 mTorr were obtained as 1.6, 5.1, 3, and 2.4 nm, respectively. The results of hardness and wear tests showed that these properties were optimized by reducing the applied gas pressure. The highest hardness was 11.59 GPa, and the best sample in terms of the mechanical properties of the coating was the sample applied at a gas pressure of 25 mTorr. Results show that the optimal sample in tribological performance is the one applied at a working pressure of 25 mTorr. Because this sample demonstrates the lowest coefficient of friction, and wear depth.

Published

2024

19. Vanishing Friction: Progress toward Mechanistic Understanding and Potential Engineering Applications

Author

Diana Berman and Ali Erdemir

Subjects

superlubricity, 2d materials, friction, mxene, diamond-like carbon, Physics, QC1-999, Engineering (General). Civil engineering (General), TA1-2040, Mechanical engineering and machinery, TJ1-1570, Chemistry, QD1-999

Abstract

Friction and wear collectively account for nearly a quarter of the world’s energy consumption, resulting in over eight Gigatons of CO2 emissions annually. With increasing mobility and industrial activity, the adverse effects of friction and wear on energy, the environment, the global economy, and sustainability will undoubtedly intensify. Unless we reverse this unsustainable trend, our planet could face a major ecological and environmental catastrophe. Fortunately, significant strides have been made in reducing friction to almost undetectable levels, with friction coefficients below 0.001. These remarkable achievements have resulted from numerous collaborative efforts and global initiatives focused on developing novel materials, surfaces, and interfaces that exhibit minimal or near zero friction, even at macro or engineering scales. This paper provides a comprehensive overview of the factors that contribute to and hinder superlubric sliding conditions, examining the impact of both intrinsic and extrinsic factors that are integral parts of the test conditions and environments. Drawing from recent analytical, experimental, and computational findings, underlying mechanisms most responsible for superlubricity are also discussed. The paper discusses recent mechanistic studies on highly ordered 2D materials, such as graphene, MoS2, h-BN, MXene, etc., and thin solid coatings such as diamond-like carbon or DLCs, as well as liquids, and discusses their potential for the development of large-scale mechanical systems. These exciting advancements pave the way for designing and producing next-generation engineering systems that can minimize friction in practical applications, thus conserving energy, enhancing durability, and protecting the environment for a sustainable future.

Published

2024

20. Molecular dynamics simulation of hybrid structure and mechanical properties of DLC/Ni-DLC thin films.

Author

Xiaoqiang, Wang, Xu, Zhang, Xiangyi, Hu, Yingjian, Tian, Haojie, Wang, Haoran, Fu, and Huimin, Li

Subjects

*DIAMOND-like carbon, *MOLECULAR dynamics, *THIN films, *HYBRID computer simulation, *RESIDUAL stresses, *MAGNETRON sputtering, *SUBSTRATES (Materials science)

Abstract

To improve the mechanical properties of the rolling body surface of wind power bearings, extend its service life. In this study, a large-scale molecular/atomic parallel processor LAMMPS was introduced, and then the process of magnetron sputtering technology in the preparation of DLC/Ni-DLC thin films on the 42CrMo substrate material was simulated. The effects of deposition parameters such as sputtering temperature, sputtering voltage, deposition air pressure, and Ni doping on the residual stress, film base bonding, and organizational structure of the thin films were investigated. The simulation results show that for different deposition parameters, the atomic tensile and compressive stresses existed simultaneously in DLC/Ni-DLC films, and the residual stresses were between − 0.504–5.003 Gpa and − 2.11–0.065 Gpa, respectively; the doping of Ni effectively improved the distribution of hybrid structure and the mechanical properties of the DLC films, and the ratio of the sp3 hybrid structure in the film organization was about 2.56 times higher than that of the non-doped films, and the membrane base bonding force was increased by 32.78% and the residual stress is reduced and transitioned from tensile stress to compressive stress. In addition, it was observed that the thickness of the mixed layer of DLC/Ni-DLC films with the substrate was not increased after the thickness of the mixed layer was extended to about 2 nm. Nickel doping and reasonable control of deposition parameters help to reduce the residual stress and improve the bonding strength of the film by changing the organizational structure of the film, which provides an important theoretical and scientific basis for the preparation of low-stress, high-performance and long-life DLC films and the wide application of rolling bodies for wind power bearings under complex working conditions. [ABSTRACT FROM AUTHOR]

Published

2024

21. Development of Antimicrobial Surfaces Using Diamond-like Carbon or Diamond-like Carbon-Based Coatings.

Author

Fujii, Yasuhiro, Nakatani, Tatsuyuki, Ousaka, Daiki, Oozawa, Susumu, Sasai, Yasushi, and Kasahara, Shingo

Subjects

*DIAMOND-like carbon, *CARBON-based materials, *TECHNOLOGICAL innovations, *SURFACE roughness, *BACTERIAL adhesion, *CARBON nanofibers

Abstract

The medical device market is a high-growth sector expected to sustain an annual growth rate of over 5%, even in developed countries. Daily, numerous patients have medical devices implanted or inserted within their bodies. While medical devices have significantly improved patient outcomes, as foreign objects, their wider use can lead to an increase in device-related infections, thereby imposing a burden on healthcare systems. Multiple materials with significant societal impact have evolved over time: the 19th century was the age of iron, the 20th century was dominated by silicon, and the 21st century is often referred to as the era of carbon. In particular, the development of nanocarbon materials and their potential applications in medicine are being explored, although the scope of these applications remains limited. Technological innovations in carbon materials are remarkable, and their application in medicine is expected to advance greatly. For example, diamond-like carbon (DLC) has garnered considerable attention for the development of antimicrobial surfaces. Both DLC itself and its derivatives have been reported to exhibit anti-microbial properties. This review discusses the current state of DLC-based antimicrobial surface development. [ABSTRACT FROM AUTHOR]

Published

2024

22. Statistical model for predicting friction coefficient and wear of duplex CrN/DLC and nano-multilayer DLC-W coatings using ANOVA.

Author

Kolawole, Funsho Olaitan and Kolawole, Shola Kolade

Subjects

DIAMOND-like carbon, STATISTICAL models, REGRESSION analysis, MECHANICAL wear, STATISTICAL reliability

Abstract

Diamond-like carbon (DLC) coatings are gaining wider attraction due to their excellent mechanical and tribological properties. This research presents statistical models to predict the wear and friction coefficient of duplex CrN/DLC and nano-multilayer DLC-W coatings through analysis of variance (ANOVA). The coatings were deposited using a hybrid PVD/PECVD system onto carburized and quenched martensitic valve tappets. Tribological tests were conducted on the coatings in a ball-on-plane configuration using a reciprocating slide on an Optimol SRV® v4 device under dry conditions. ANOVA and regression analysis were employed to analyze the wear rate and coefficient of friction (COF), leading to the development of a prediction equation. The results indicated that both applied load and operating temperature had nearly equal influence on the COF and wear of the coatings. The reliability of the proposed statistical models was approximately 92–96% for duplex CrN/DLC and 90–97% for nano-multilayer DLC-W. These models are applicable only to the tested parameters within the deformation region. They can be used to predict the tribological operating conditions for the duplex CrN/DLC and nano-multilayer DLC-W coatings, helping to prevent premature failure. [ABSTRACT FROM AUTHOR]

Published

2024

23. Carbon Nanomaterials-Based Novel Hybrid Platforms for Electrochemical Sensor Applications in Drug Analysis.

Author

Cetinkaya, Ahmet, Kaya, S. Irem, Ozcelikay, Goksu, Budak, Fatma, and Ozkan, Sibel A.

Subjects

*DIAMOND-like carbon, *ELECTROCHEMICAL sensors, *DRUG analysis, *ELECTROCHEMICAL analysis, *CONDUCTING polymers, *CARBON nanofibers

Abstract

Nowadays, the rapid improvements in the medical and pharmaceutical fields increase the diversity and use of drugs. However, problems such as the use of multiple or combined drugs in the treatment of diseases and insensible use of over-the-counter drugs have caused concerns about the side-effect profiles and therapeutic ranges of drugs and environmental contamination and pollution problems due to pharmaceuticals waste. Therefore, the analysis of drugs in various media such as biological, pharmaceutical, and environmental samples is an important topic of discussion. Electrochemical methods are advantageous for sensor applications due to their easy application, low cost, versatility, high sensitivity, and environmentally-friendliness. Carbon nanomaterials such as diamond-like carbon thin films, carbon nanotubes, carbon nanofibers, graphene oxide, and nanodiamonds are used to enhance the performance of the electrochemical sensors with catalytic effects. To further improve this effect, it is aimed to create hybrid platforms by using different carbon nanomaterials together or with materials such as conductive polymers and ionic liquids. In this review, the most used carbon nanoforms will be evaluated in terms of electrochemical characterizations and physicochemical properties. Furthermore, the effect of hybrid platforms developed in the most recent studies on electrochemical sensors will be examined and evaluated in terms of drug analysis studies in the last five years. [ABSTRACT FROM AUTHOR]

Published

2024

24. The oxygen plasma etching behavior onto diamond-like carbon coating for micro-texturing: Experimental and molecular dynamics study.

Author

Yunata, Ersyzario Edo, Suaebah, Evi, and Arifin, Rizal

Subjects

DIAMOND-like carbon, PLASMA etching, OXYGEN plasmas, MOLECULAR dynamics, REACTIVE oxygen species

Abstract

In this study, the experiment and molecular dynamic simulations were used to show how oxygen plasma etching works on diamond-like carbon (DLC) for micro-texturing. On the experimental side, C–C bonds on the DLC were dissociated by the irradiated oxygen. The physical bombardment of reactive oxygen ions selectively removes the carbon atoms in the unmasked area via the generation and desorption of gaseous carbon monoxide and carbon dioxide molecules. Molecular dynamic simulation exhibits the reactivity of O2 molecules with C atoms in the DLC. The quantity of O2 molecules and the formation of new molecules (CO) were proven in this simulation. [ABSTRACT FROM AUTHOR]

Published

2024

25. Process-Integrated Component Microtexturing for Tribologically Optimized Contacts Using the Example of the Cam Tappet—Numerical Design, Manufacturing, DLC-Coating and Experimental Analysis.

Author

Orgeldinger, Christian, Reck, Manuel, Seynstahl, Armin, Rosnitschek, Tobias, Merklein, Marion, and Tremmel, Stephan

Subjects

LUBRICATED friction, SHEET metal, MANUFACTURING processes, SURFACE coatings, FRICTION, DIAMOND-like carbon, ELASTOHYDRODYNAMIC lubrication

Abstract

To meet the demand for energy-efficient and, at the same time, durable, functional components, the improvement of tribological behavior is playing an increasingly important role. One approach to reducing friction in lubricated tribological systems is the microtexturing of the surfaces tailored to the application, but in most cases, this leads to increased manufacturing costs and thus often makes their use in industry more difficult. In this work, we, therefore, present an approach for an efficient design and fully integrated production process using a cam tappet as an example. For the used cam tappet contact, we first determined the optimal texture geometries using two differently complex EHL (elastohydrodynamic lubrication) simulation models. Based on these, textured tappets were manufactured in a combined manner using sheet-bulk metal-forming and deposition with a diamond-like-carbon (DLC) coating for additional wear protection without further post-processing of the coating. We show that the simulation approach used has a rather subordinate influence on the optimization result. The combined forming of components with textured surfaces is limited by the local material flow, the resulting texture distortion, and tool wear. However, a targeted process design can help to exploit the potential of single-stage forming. The applied DLC coating has good adhesion and can completely prevent wear in subsequent reciprocal pin-on-disc tests, while the friction in the run-in behavior is initially higher due to the soothing effects of the coating. The experiments also show a tendency for shallow textures to exhibit lower friction compared to deeper ones, which corresponds to the expectations from the simulation. [ABSTRACT FROM AUTHOR]

Published

2024

26. The Evaluation of the Cytotoxicity and Corrosion Processes of Porous Structures Manufactured Using Binder Jetting Technology from Stainless Steel 316L with Diamond-like Carbon Coating.

Author

Laskowska, Dorota, Mitura, Katarzyna, Bałasz, Błażej, Wilczek, Piotr, Samotus, Aneta, Kaczorowski, Witold, Grabarczyk, Jacek, Svobodová, Lucie, Bakalova, Totka, and Mitura, Stanisław

Subjects

POROUS metals, DIAMOND-like carbon, CYTOTOXINS, ORTHOPEDIC implants, STAINLESS steel, OSSEOINTEGRATION

Abstract

With the growing interest in additive manufacturing technology, assessing the biocompatibility of manufactured elements for medical and veterinary applications has become crucial. This study aimed to investigate the corrosion properties and cytotoxicity of porous structures designed to enhance the osseointegration potential of implant surfaces. The structures were fabricated using BJ technology from 316L stainless steel powder, and their surfaces were modified with a DLC coating. The studies carried out on porous metal samples with and without DLC coatings demonstrated low cytotoxicity. However, no significant differences were found between the uncoated and DLC-coated samples, likely due to variations in the thickness of the coating on the porous samples and the occurrence of mechanical damage. [ABSTRACT FROM AUTHOR]

Published

2024

27. Tribological Properties of CrN/DLC and CrN Coatings under Different Testing Conditions.

Author

Zhang, Shuling, Yang, Xiangdong, Huang, Tenglong, Guo, Feng, Dai, Longjie, Liu, Yi, and Zhang, Bo

Subjects

DC sputtering, DRY friction, COMPOSITE coating, MECHANICAL wear, X-ray photoelectron spectroscopy, DIAMOND-like carbon, FRETTING corrosion

Abstract

CrN and diamond-like carbon (DLC) coatings are deposited on the surface of 431 stainless steel by the direct current magnetron sputtering technique. The surface morphology, micro-structure, hardness, friction, and wear properties of CrN, CrN/DLC and multi-layer composite DLC coatings are investigated by scanning electron microscopy, X-ray diffraction, Raman spectroscopy, X-ray photoelectron spectroscopy, nanoindentation tester, scratch tester, and friction and wear tester. The results show that the surface of the single CrN coating is very rough for the columnar crystal structure with preferred orientation. When it serves as inner transition layers to form the composite DLC coatings, the surface gets much smoother, with reduced defects. The friction and wear results indicate that the composite DLC coatings exhibit lower coefficients of friction, and better wear and corrosion resistance in dry friction, deionized water, and seawater. In the dry wear and friction process, the single CrN coating is easily worn out, and severe friction oxidation and furrow wear both appear with a friction coefficient of 0.48. But the friction coefficient of a CrN coating in seawater is reduced to 0.16, and friction oxidation and wear loss are further reduced with water lubrication. The CrN/DLC coating has excellent tribological performance in three test concoctions and has the lowest friction coefficient of 0.08 in seawater, which is related to the higher sp3 bond content, density (1.907 g/cm3) and high degree of amorphization, contributing to high hardness and a self-lubrication effect. However, due to the limited thickness of CrN/DLC (1.14 µm), it easily peels off and fails during friction and wear in different testing conditions. In multi-layer composite DLC coatings, there are more sp2 bonds with decreased amorphization, high enough thickness (4.02 µm), and increased bonding strength for the formation of different carbides and nitrides of chromium as transition layers, which gives rise to the further decreased average friction coefficient and the lowest wear loss. Therefore, the CrN coating alone has good wear resistance, and, as with the inner transition layer with a DLC coating, it can effectively improve the overall thickness and the bonding strength of the multi-layer films by optimizing the chemical compounds of DLC coatings. These results provide experimental support and reference for the design and selection of surface coatings for 431 stainless steels in different working conditions. [ABSTRACT FROM AUTHOR]

Published

2024

28. Robust Macroscale Superlubricity in Humid Air via Designing Amorphous DLC/Crystalline TMDs Friction Pair.

Author

Zhu, Dongxiang, Zhang, Jie, Li, Panpan, Li, Zhan, Li, Hongxuan, Liu, Xiaohong, Ma, Tianbao, Ji, Li, Zhou, Huidi, and Chen, Jianmin

Subjects

*FRICTION, *INDUSTRY 4.0, *DIAMOND-like carbon, *CRYSTAL grain boundaries, *AMORPHOUS carbon, *SURFACE defects, *ENERGY consumption

Abstract

Superlubricity, a cutting‐edge concept, has the potential to drive the Fourth Industrial Revolution giving its near‐zero energy consumption, but the challenge is how to achieve it in humid air with chemical activity and at macroscale surfaces with unavoidable defects. Here, a novel principle involving the amorphous/crystalline friction pair based on the cognition that tribochemical interaction sites originate from grain boundary defect locations is proposed to achieve macroscale superlubricity in humid air. The absence of grain boundaries in amorphous diamond‐like carbon (DLC) significantly reduces chemical interaction during the sliding process. This is supported by experimental observations of priority oxidation at the grain boundaries. Results indicate DLC versus MoS2 friction pair has weakened chemical interaction and less humid insensitivity compared to the MoS2 versus MoS2 pair, even increasing the contact area. Theoretical simulation suggests that DLC versus MoS2 pair eliminates the cross‐linking of friction interlayers induced by the enrichment of H2O molecules at MoS2 defects. The robust superlubricity is achieved for the typical friction pair of DLC versus MoS2 in air (RH≤25%) at macroscopic contact pressure (1.1 GPa) with friction coefficient in 10−3 magnitude and extra‐long anti‐wear life (more than 2 × 105 cycles), which is of significance for the industrialization of superlubricity. [ABSTRACT FROM AUTHOR]

Published

2024

29. DLC FILMS ON Ti6Al4V SUBSTRATES OF NANOINDENTATION, SURFACE ROUGHNESS FOR LASER POWDER BED FUSION WAS PERFORMED UTILIZING ORTHOPEDIC IMPLANT MATERIALS.

Author

MARICHAMY, M., CHOCKALINGAM, K., and ARUNACHALAM, N.

Subjects

*SUBSTRATES (Materials science), *SURFACE roughness, *ORTHOPEDIC implants, *TITANIUM powder, *DIAMOND-like carbon, *NANOINDENTATION tests, *NANOINDENTATION, *TITANIUM

Abstract

Diamond-like carbon (DLC) films on titanium alloy Ti6Al4V substrates were tested with nanoindentation and surface roughness to look at the hardness and roughness of the coating and substrate systems as well as their mechanical properties. The powdered titanium alloy Ti6Al4V used in the substrate specimen was produced using laser powder bed fusion, an additive manufacturing process. In this study, we investigated the influence of substrates on the nanoindentation and surface roughness of the DLC film layer with an estimated 2.21μm thickness on Ti6Al4V substrates. The findings of the nanoindentation show that the reaction to the impact was more flexible than expected. Maximum load, residual nanoindentation depth, hardness, and modulus may influence mechanical properties. The DLC-film Ti6Al4V substrate materials’ top surface roughness is measured. As a result of the increased load-carrying ability of DLC/Ti6Al4V, Ti6Al4V is a superior choice for substrate materials for DLC films, A DLC coating, measuring 2.21μ m in thickness, was applied to a Ti6Al4V substrate utilizing a 5-min chromium deposition process. The biocompatibility of the substrates plays a crucial role in determining the DLC films capacity to prolong the lifespan of bone implants. [ABSTRACT FROM AUTHOR]

Published

2024

30. Tailoring the mechanical and high‐temperature tribological properties of Si‐DLC films by controlling the Si content.

Author

Yu, Weijie, Mei, Qiuping, Huang, Weijiu, Wang, Junjun, and Su, Yongyao

Subjects

*DIAMOND-like carbon, *X-ray photoelectron spectroscopy, *SCANNING electron microscopes, *REACTIVE sputtering, *HIGH temperatures, *MAGNETRON sputtering

Abstract

The poor high‐temperature tribological performance of diamond‐like carbon (DLC) films severely limits their applications. To address this issue, silicon (Si) doped DLC films with Si content ranging from 0 to 11.52 at.% were synthesized utilizing the plasma‐assisted reactive magnetron sputtering technique. The influence of Si incorporation on the microstructure and mechanical properties was meticulously investigated by Raman spectroscopy, scanning electron microscope (SEM), X‐ray photoelectron spectroscopy (XPS), nanoindentation, and scratch testing. To ascertain the tribological behavior of the Si‐DLC films under elevated temperature conditions, in situ high‐temperature tests were conducted, spanning temperatures from ambient to 500°C. The findings indicated that distinct lubrication mechanisms prevail for Si‐DLC films with varying Si content across different temperature domains. As the test temperature and Si content increased, the lubrication mechanism exhibited a gradual transitions from high‐temperature induced graphitization to a particle wear regime dominated by SiC and formed SiO2 abrasive phases. The comprehensive performance of the films peaked at a Si content of 4.72 at.%, suggesting an optimal composition for high‐temperature applications. It is postulated that the in‐depth investigation presented herein holds considerable value for the design and fabrication of DLC films intended for use in high‐temperature settings, potentially unlocking their full potential in such demanding environments. [ABSTRACT FROM AUTHOR]

Published

2024

31. Surface Integrity in Laser De-coating of Tooling.

Author

Reduan, Muhammad Tajuddin and Mativenga, Paul

Abstract

Laser de-coating technology is a promising method for the selective removal of coatings on cutting tools. When the coating is removed, it is essential to ensure that the surface integrity is not compromised. The laser cleaning process can also be targeted to enhance surface integrity. Among the many different types of coating used on tooling is Diamond-like Carbon (DLC). The coating has excellent performance in terms of a low coefficient of friction. This research investigates the effect of laser de-coating on the surface morphology, composition, residual stress, nano hardness, and surface roughness when removing DLC coating on tungsten carbide substrates to facilitate re-use in a circular economy. The research provides a greater understanding of the effect of laser process parameters in de-coating and on preserving the surface integrity and enabling favorable residual stress. This research is vital in the transition towards optimized remanufacturing of tooling and in enabling circularity. [ABSTRACT FROM AUTHOR]

Published

2024

32. Evaluation of the effects of the application of Ti−C:H DLC coatings obtained by PVD techniques in the kinematic pairs of internal combustion engines and powertrain systems.

Author

MURZYŃSKI, Dawid

Subjects

INTERNAL combustion engines, ELECTRON microscopes, MOTOR vehicles, PROFILOMETER, COEFFICIENTS (Statistics)

Abstract

The article attempts to analyze the possible effects of using Ti−C:H DLC carbon coatings produced by pulsed magnetron sputtering (PVD) to reduce friction coefficient and wear in kinematic pairs found in internal combustion engines and powertrain systems used in automotive vehicles. The aim of such action is primarily to reduce internal losses in the aforementioned units. The coatings were deposited on heat-treated bearing steel 100Cr6, and examined using a scanning electron microscope FEI Quanta 200 Mark II with the chemical analyzer EDS EDAX Genesis XM 2i, tribotester T−01M examining the friction coefficient in the ball-disc correlation and Hommel Werke T8000 profilometers, additionally, in order to check the coating thickness, studies were carried out using the Calotest method. The results obtained indicate that both the friction coefficient and wear are drastically reduced concerning samples on which no DLC coatings were applied. [ABSTRACT FROM AUTHOR]

Published

2024

33. Fabrication and Tribological Properties of Diamond-like Carbon Film with Cr Doping by High-Power Impulse Magnetron Sputtering.

Author

Liu, Shuai, Zhuang, Wenjian, Ding, Jicheng, Liu, Yuan, Yu, Weibo, Yang, Ying, Liu, Xingguang, Yuan, Jing, and Zheng, Jun

Subjects

MECHANICAL wear, FRETTING corrosion, GAS mixtures, MAGNETRON sputtering, WEAR resistance, DIAMOND-like carbon

Abstract

The present study aims to investigate the advantages of diamond-like carbon (DLC) films in reducing friction and lubrication to address issues such as the low surface hardness, high friction coefficients, and poor wear resistance of titanium alloys. Cr-doped DLC films were deposited by high-power impulse magnetron sputtering (HiPIMS) in an atmosphere of a gas mixture of Ar and C2H2. The energy of the deposited particles was controlled by adjusting the target powers, and four sets of film samples with different powers (4 kW, 8 kW, 12 kW, and 16 kW) were fabricated. The results showed that with an increase in target power, the Cr content increased from 3.73 at. % to 22.65 at. %; meanwhile, the microstructure of the film evolved from an amorphous feature to a nanocomposite structure, with carbide embedded in an amorphous carbon matrix. The sp2-C bond content was also increased in films, suggesting an intensification of the film's graphitization. The hardness of films exhibited a trend of initially increasing and then decreasing, reaching the maximum value at 12 kW. The friction coefficient and wear rate of films showed a reverse trend compared to hardness variation, namely initially decreasing and then increasing. The friction coefficient reached a minimum value of 0.14, and the wear rate was 2.50 × 10−7 (mm3)/(N·m), at 8 kW. The abrasive wear was the primary wear mechanism for films deposited at a higher target power. Therefore, by adjusting the target power parameter, it is possible to control the content of the metal and sp2/sp3 bonds in metal-doped DLC films, thereby regulating the mechanical and tribological properties of the films and providing an effective approach for addressing surface issues in titanium alloys. [ABSTRACT FROM AUTHOR]

Published

2024

34. The Green Lubricant Coatings Deposited by Physical Vapor Deposition for Demanding Tribological Applications: A Review.

Author

Kong, Fanlin, Luan, Jing, Xie, Fuxiang, Zhang, Zhijie, Evaristo, Manuel, and Cavaleiro, Albano

Subjects

TRANSITION metal nitrides, PHYSICAL vapor deposition, DIAMOND-like carbon, SUSTAINABLE design, SURFACE coatings

Abstract

The emergence of nanotechnology and surface engineering techniques provides new opportunities for designing self-lubricant coatings with enhanced properties. In recent years, green coating technologies have played a vital role in environmental preservation. This article mainly reviews five typical types of self-lubricant coatings including MoN coatings, VN coatings, WN coatings and TMN (Transition Metal Nitride) soft-metal coatings, and DLC (Diamond-like Carbon) with lubricant agents deposited by PVD (Physical Vapor Deposition) for the demanding tribological applications, which is the latest research into the green lubricant coatings. Furthermore, it is of great significance for designing the green self-lubricant coatings to adapt the demanding tribological applications to meet the industrial requirements. [ABSTRACT FROM AUTHOR]

Published

2024

35. Anti-Corrosion SiO x -Doped DLC Coating for Raster Steel Linear Scales.

Author

Lazauskas, Algirdas, Grigaliūnas, Viktoras, Jucius, Dalius, Meškinis, Šarūnas, Andrulevičius, Mindaugas, Guobienė, Asta, Vasiliauskas, Andrius, and Kasparaitis, Albinas

Subjects

CARBON-based materials, SALT spray testing, SOLUTION (Chemistry), AMORPHOUS substances, AMORPHOUS carbon, DIAMOND-like carbon

Abstract

In this study, we investigated the efficacy of SiOx-doped diamond-like carbon (DLC) films for enhancing the corrosion resistance of raster steel linear scales. The research work highlights the significant role of DLC film materials in enhancing corrosion resistance, making them a promising solution for various industrial applications. The Raman spectroscopy analysis of SiOx-doped DLC films, synthesized via a direct ion beam technique with HMDSO vapor, revealed prominent D and G bands characteristic of amorphous carbon materials, with a high degree of disorder indicated by an ID/IG ratio of 1.85. X-ray diffraction patterns confirmed the amorphous nature of the SiOx-doped DLC films and the minimal impact of the DLC deposition process on the underlying crystalline structure of steel. UV–Vis-NIR reflectance spectra of SiOx-doped DLC on stainless steel demonstrated improvements in the blue wavelength region compared to stainless steel with ripples alone, which is beneficial for applications utilizing blue light. Corrosion tests, including immersion in a 5% salt solution and salt spray testing, showed that SiOx-doped DLC-coated stainless steel exhibited superior corrosion resistance compared to uncoated steel, with no significant signs of corrosion observed after extended exposure. These findings underscore the potential of SiOx-doped DLC coatings to provide long-term corrosion protection and maintain the structural integrity and surface quality of steel components in harsh environments. [ABSTRACT FROM AUTHOR]

Published

2024

36. In-situ Verschleißmessung an DLC-Schichten unter anwendungsnahen Bedingungen.

Author

Zellhofer, Manuel, Jech, Martin, and Badisch, Ewald

Abstract

Copyright of BHM Berg- und Hüttenmännische Monatshefte is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

37. Polyethylene Glycol Monolaurate Lubrication Triggers Liquid Superlubricity on Diamond-like Carbon Film.

Author

Sun, Shouyi, Ma, Xiaoyang, Song, Wei, Ding, Zhengmao, and Li, Jinjin

Abstract

Achieving the ultralow coefficient of friction (COF) is the goal pursued by the industrial field. In this work, the macroscopic superlubricity with a COF of 0.003 on the DLC film was achieved at an approximate temperature of 45–100 °C when it slid against the steel ball with the lubrication of polyethylene glycol monolaurate (PEGM). The superlubricity state was achieved in a mixed lubrication regime, mainly containing boundary lubrication and thin film lubrication. The friction action under high temperature facilitated the chemisorption of PEGM molecules on the friction pair to form the tribochemical films, providing a low shear strength under boundary lubrication. Meanwhile, the PEGM molecules could form an ordered layer and a liquid layer on the tribochemical films due to the strong polarity of PEGM molecules, which attained the thin film lubrication to reduce friction. Moreover, the friction promoted the in situ generation of carbonaceous sheets in the contact region, providing low shear strength and reducing COF under boundary lubrication. This finding provides insight into the superlubricity mechanism of DLC film and expands its engineering application in superlubricity technology. [ABSTRACT FROM AUTHOR]

Published

2024

38. Diamond-like carbon (DLC) coating on graphite: Investigating the achievement of maximum wear properties using the PECVD method.

Author

Samiee, Mohsen, Seyedraoufi, Zahra-Sadat, Abbasi, Mehrdad, Eshraghi, Mohammad Javad, and Abouei, Vahid

Subjects

*MECHANICAL wear, *PLASMA-enhanced chemical vapor deposition, *FIELD emission electron microscopy, *DIAMOND-like carbon, *ATOMIC force microscopy, *NANOINDENTATION, *MODULUS of elasticity

Abstract

Considering the potential for morphological changes and the adjustment of the sp3/sp2 ratio in diamond-like carbon (DLC) coatings, and consequently the possibility of adjusting the properties of self-lubricating, hardness, and wear of these coatings, the present study investigates the effect of varying the power applied during the deposition of coatings using plasma-enhanced chemical vapor deposition (PECVD) method. Raman spectroscopy, Atomic Force Microscopy (AFM), Field Emission Scanning Electron Microscopy (FESEM), nanoindentation, wear, and wear depth tests were employed for this purpose. The results obtained from the Raman spectroscopy indicated that the percentage of sp3 hybridization, as well as the amount of internal stress, increased with the higher applied power of the coating. AFM results also reveal an increase in surface roughness with increasing applied power, and FESEM results indicate a reduction in the diameter of DLC grains with increasing applied power. Moreover, the alternating increase in hardness and modulus of elasticity, along with a decrease in friction coefficient and wear depth, are among the other effects of increasing the applied power. Therefore, the results of this research suggest an enhancement in the tribological properties of the applied coating at higher powers (up to 250 W). [ABSTRACT FROM AUTHOR]

Published

2024

39. Processing and analysis of friction vibration signal of diamond-like carbon film microtextured dry gas seal rings.

Author

Chen, Delin, Chen, Yan, and Chen, Jinxin

Subjects

*DIAMOND-like carbon, *FEATURE extraction, *FREQUENCIES of oscillating systems, *DYNAMIC pressure, *FRICTION, *SIGNAL processing, *TRIBOLOGY

Abstract

Purpose: This paper aims to analyze the characteristics of friction vibration signals and identify the vibration excitation source at the start and stop stage of microtextured end face of dry gas seals. Design/methodology/approach: The friction pair consists of a diamond-like carbon (DLC) film microtextured seal ring and a spiral groove seal ring. Friction vibration signal feature extraction method based on harmonic wavelet packet and spectrum analysis was proposed. Signals were collected using acceleration sensor, acquisition card and LabVIEW software. Vibration acceleration signal was decomposed into 32 frequency bands using MATLAB wavelet packet transformation. The 32nd band coefficient was extracted for reconstruction, time-domain and spectral waveforms were obtained and spectra before/after denoising were compared. Findings: The end face of the DLC film microtextured seal ring generates a good dynamic pressure effect, and the friction and vibration reduction effects are obvious. The harmonic wavelet packet can decompose the vibration signal conveniently and precisely. In the case of this experiment, the frequency of vibration of the seal ring is 7500 HZ. Originality/value: The results show that the method is effective for the processing of friction vibration signal and the identification of vibration excitation source. The findings will provide ideas for the frictional vibration signal processing and basis for further research in the field of tribology of dry gas seal ring. Peer review: The peer review history for this article is available at: https://publons.com/publon/10.1108/ILT-03-2024-0084/ [ABSTRACT FROM AUTHOR]

Published

2024

40. Fracture toughness of duplex CrN/DLC and nano-multilayer DLC-W deposited on valve tappet via hybrid PVD and PECVD.

Author

Kolawole, Funsho Olaitan, Kolawole, Shola Kolade, Bello, Sefiu Adekunle, Yakubu, Shedrach, Adigun, Oluwole Daniel, Owa, Adebayo Felix, Umunakwe, Reginald, Adebayo, Abdullahi Olawale, and Madueke, Chioma Ifeyinwa

Subjects

*FRACTURE toughness, *DIAMOND-like carbon, *VALVES, *MICROHARDNESS, *SURFACE coatings, *HARDNESS

Abstract

DLC coatings are well known for their high fracture toughness, however, often exhibit poor adhesion properties on metallic substrates. The use of interlayers and metallic doping can be used to overcome such challenge. In this study duplex CrN/DLC and nano-multilayer DLC-W coatings were both deposited on hydraulic valve tappet using a hybrid PVD/PECVD deposition system. Microhardness measurements were taken for the uncoated valve tappet, duplex CrN/DLC and nano-multilayer DLC-W coated valve tappet at loads of 0.98 N, 1.96 N, 2.94 N, 4.9 N, 9.8 N and 19.6 N for 15 seconds using a Shimadzu hardness tester. The fracture toughness was evaluated using the Vickers indentation method from microhardness indents on the surface of the coatings. The fracture toughness for duplex CrN/DLC and nano-multilayer DLC-W coatings indented at 4.9 N, 9.8 N and 19.6 N, reveals that the fracture toughness for the duplex CrN/DLC were 20.24 ± 0.97 MPa.m1/2, 17.18 ± 0.86 MPa.m1/2 and 6.6 ± 0.28 MPa.m1/2 respectively. While the fracture toughness for nano-multilayer DLC-W was calculated as 3.75 ± 0.41 MPa.m1/2 and 4.67 ± 0.38 MPa.m1/2 at 9.8 N and 19.6 N respectively. [ABSTRACT FROM AUTHOR]

Published

2024

41. Improved Tribological Performance of ta-C/MoSx Coatings Deposited on Laser Micro-Structured Steel Substrates in Both Vacuum and Air.

Author

Makowski, Stefan, Härtwig, Fabian, Soldera, Marcos, Ojeil, Mahmoud, Lorenz, Lars, Kaulfuß, Frank, and Lasagni, Andrés Fabián

Subjects

DIAMOND-like carbon, SUBSTRATES (Materials science), STEEL, VACUUM arcs, SURFACE coatings, TRIBOLOGICAL ceramics, ANTIREFLECTIVE coatings, AUTOMOBILE bodies

Abstract

Vacuum and air atmospheres impose very different requirements on tribological-loaded contacts, which usually require different surface materials. While hard tetrahedral amorphous carbon (ta-C) coatings provide good tribological properties in air, soft coatings such as molybdenum disulfide (MoS2) work well in a vacuum. Tribological performance in the respective other environment, however, is poor. In this work, the combination of laser microstructured (direct laser interference patterning) steel substrates and the deposition of ta-C and MoSx coatings with vacuum arc evaporation (LaserArc™) was studied, resulting in steel/DLIP, steel/DLIP/ta-C, steel/DLIP/MoSx, steel/DLIP/ta-C/MoSx, and steel/MoSx surface combinations. The tribological properties were studied using a ball-on-disk tribometer with a steel ball counter body in air and in a vacuum (p < 5 × 10−7 mbar). The type of the topmost coating governed their tribological properties in the respective atmosphere, and no general beneficial influence of the microstructure was found. However, steel/DLIP/ta-C/MoSx performed best in both conditions and endured the highest contact pressure, which is attributed to the mechanical support of the ta-C coating and MoSx reservoir in the remaining structure, as evidenced by Raman spectroscopy. The findings suggest that such combination allows for surfaces bearing a high load capacity that can be applied in both a vacuum and in air, for example, in multi-use space applications. [ABSTRACT FROM AUTHOR]

Published

2024

42. Diamond-like carbon coating to inner surface of polyurethane tube reduces Staphylococcus aureus bacterial adhesion and biofilm formation.

Author

Kuwada, Noriaki, Fujii, Yasuhiro, Nakatani, Tatsuyuki, Ousaka, Daiki, Tsuji, Tatsunori, Imai, Yuichi, Kobayashi, Yasuyuki, Oozawa, Susumu, Kasahara, Shingo, and Tanemoto, Kazuo

Abstract

Staphylococcus aureus is one of the main causative bacteria for polyurethane catheter and artificial graft infection. Recently, we developed a unique technique for coating diamond-like carbon (DLC) inside the luminal resin structure of polyurethane tubes. This study aimed to elucidate the infection-preventing effects of diamond-like carbon (DLC) coating on a polyurethane surface against S. aureus. We applied DLC to polyurethane tubes and rolled polyurethane sheets with our newly developed DLC coating technique for resin tubes. The DLC-coated and uncoated polyurethane surfaces were tested in smoothness, hydrophilicity, zeta-potential, and anti-bacterial properties against S. aureus (biofilm formation and bacterial attachment) by contact with bacterial fluids under static and flow conditions. The DLC-coated polyurethane surface was significantly smoother, more hydrophilic, and had a more negative zeta-potential than did the uncoated polyurethane surface. Upon exposure to bacterial fluid under both static and flow conditions, DLC-coated polyurethane exhibited significantly less biofilm formation than uncoated polyurethane, based on absorbance measurements. In addition, the adherence of S. aureus was significantly lower for DLC-coated polyurethane than for uncoated polyurethane under both conditions, based on scanning electron microscopy. These results show that applying DLC coating to the luminal resin of polyurethane tubes may impart antimicrobial effects against S. aureus to implantable medical polyurethane devices, such as vascular grafts and central venous catheters. [ABSTRACT FROM AUTHOR]

Published

2024

43. Enhancing UV Radiation Resilience of DLC-Coated Stainless Steel with TiO 2 : A Dual-Layer Approach.

Author

Macário, Paulo Fabrício, da Silveira, Carolina Hahn, Vieira, Angela Aparecida Moraes, Marcondes, André Ricardo, Marques, Francisco das Chagas, Fechine, Guilhermino José Macêdo, and Vieira, Lúcia

Subjects

ULTRAVIOLET radiation, STAINLESS steel, TITANIUM dioxide, DIAMOND-like carbon, PROTECTIVE coatings

Abstract

This study presents an innovative dual-layer coating approach integrating titanium dioxide (TiO2) onto diamond-like carbon (DLC)-coated 316L stainless steel. The combination of PECVD-deposited DLC and ALD-deposited TiO2 aims to preserve the inherent tribological properties of DLC while mitigating UV-induced degradation. By leveraging the ability of TiO2 to absorb, reflect, and scatter UV light, this dual-layer strategy significantly enhances the durability of DLC coatings in radiation-prone environments. The effects of accelerated aging through UV exposure on DLC and DLC/TiO2 films were evaluated using an Accelerated Weathering Tester. Comprehensive analyses were conducted to assess the structural and mechanical properties before and after UV exposure, including Raman spectroscopy, profilometry, SEM, EDS, nanoindentation, and tribometry. The results demonstrate that the TiO2 layer effectively mitigates UV-induced damage, preserving the DLC film's integrity and tribological performance even after 408 h of UV aging. Specifically, the DLC/TiO2 coatings maintained lower roughness, higher hardness, and better adhesion than DLC-only coatings under identical conditions. This research significantly advances protective coating technology by enhancing the durability and performance of DLC films, particularly in aerospace and other demanding industries where exposure to UV radiation is a critical concern. [ABSTRACT FROM AUTHOR]

Published

2024

44. Tribocatalytic Reaction Enabled by TiO 2 Nanoparticle for MoDTC-Derived Tribofilm Formation at ta-C/Steel Contact.

Author

Matsukawa, Daiki, Park, Jae-Hyeok, Lee, Woo-Young, Tokoroyama, Takayuki, Kim, Jae-Il, Ichino, Ryoichi, and Umehara, Noritsugu

Subjects

TITANIUM dioxide, NANOPARTICLES, DIAMOND-like carbon, FRICTION, RUTILE

Abstract

Tribochemically produced triboproducts are becoming increasingly important in tribosystems and serve to improve system performance by preventing friction or wear. Diamond-like carbon (DLC) is chemically stable, which features a trade-off with tribological pros and cons. Chemically stable DLC is thermally stable and suppresses surface damage in a high-temperature operating environment; however, it causes a detrimental effect that hinders the formation of a competent tribofilm. In this study, we dispersed highly reactive TiO2 nanoparticles (TDONPs) in molybdenum dithiocarbamate (MoDTC)-containing lubricant for adhering triboproducts on the DLC surface. In addition, TDONPs contributed to the decomposition of triboproducts by promoting the decomposition of MoDTC through its catalytic role. Rutile TDONPs were more helpful in reducing friction than anatase TDONPs and improved the friction performance by up to ~100%. [ABSTRACT FROM AUTHOR]

Published

2024

45. Durable and High‐Performance Triboelectric Nanogenerator Based on an Inorganic Triboelectric Pair of Diamond‐Like‐Carbon and Glass

Author

Wenjian Li, Liqiang Lu, Chi Zhang, Katja Loos, and Yutao Pei

Subjects

diamond‐like carbon, TENG, triboelectric nanogenerator, ultradurable, Science

Abstract

Abstract The long‐term durability of triboelectric nanogenerators (TENGs) remains a main challenge for practical applications because of inevitable material abrasion and wear, especially for sliding TENGs. Herein, an inorganic triboelectric pair composed of diamond‐like carbon (DLC) and glass with excellent durability and triboelectric output for sliding‐mode TENGs is proposed. This triboelectric pair possesses a low coefficient of friction and little abrasion and accordingly excellent durability (>500 000 cycles). Moreover, compared with the traditional copper‐polytetrafluoroethylene (Cu‐PTFE) TENG with maximum transferred charges of 50 nC, those of the DLC‐glass TENG reaches 141 nC. Due to the low‐friction and high hardness of the triboelectric pair, the output quickly recovers after simply cleaning wear debris. The DLC‐glass TENG demonstrates an output power density of 530 mW m−2 and a fourfold faster capacitor charging speed than the Cu‐PTFE TENG. Compared to the reported durable TENGs via structure optimization and interface lubrication, the DLC‐glass TENG shows higher outputs and simpler structure. This DLC‐glass pair structure is also introduced into a spherical TENG for blue energy harvesting with excellent durability. The inorganic triboelectric pair with excellent mechanical durability and electrical performance proposed in this work shows huge prospects for practical applications of TENGs.

Published

2024

46. Use of silicon or carbonitriding interface in the adhesion of Ag-DLC film on titanium alloy: a comparative study

Author

Adriano de Oliveira, Argemiro S. da Silva Sobrinho, Douglas M. G. Leite, Jonas J. Neto, Rodolfo L. P. Gonçalves, and Marcos Massi

Subjects

diamond-like carbon, PECVD, hollow cathode, carbonitriding, titanium, scratch, Mining engineering. Metallurgy, TN1-997, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Abstract A Hollow Cathode Plasma Enhanced Chemical Vapor Deposition (HC-PECVD) reactor was used to deposit silver doped Diamond-Like Carbon (Ag-DLC) films on Ti6Al4V alloy employing two methodologies: i) producing a silicon interlayer, using tetramethylsilane (TMS) as silicon precursor, varying the argon flow of the hollow cathode; and ii) carbonitriding the substrate. Profilometry, Raman, and Secondary Ion Mass Spectrometry (SIMS), as well as nanohardness, micro-scratch, scratch, and VDI 3198 indentation tests were used to evaluate the characteristics of the films and their adhesion on the substrates. The results demonstrated that the argon flow can be used for tuning the Ag-DLC film’s hardness, toughness, and adherence on silicon interlayers. The carbonitriding process, in turn, provided an improvement in the film toughness compared with non-carbonitrided samples. Considering the lower cost and easier handling of N2 compared to the silicon precursors commonly available (TMS, HDMSO, SiH4, etc.), the carbonitriding process proved more appropriate to improve the adhesion of the Ag-DLC films on the Ti6Al4V alloy.

Published

2024

47. Development of Low-Friction Technology for Treating Nitrogen-Containing Diamond-Like Carbon Coatings in Ambient Air Using Dielectric Barrier Discharge

Author

Wu, Wenjun, Umehara, Noritsugu, Tokoroyama, Takayuki, Murashima, Motoyuki, Zhang, Ruixi, Ceccarelli, Marco, Series Editor, Corves, Burkhard, Advisory Editor, Glazunov, Victor, Advisory Editor, Hernández, Alfonso, Advisory Editor, Huang, Tian, Advisory Editor, Jauregui Correa, Juan Carlos, Advisory Editor, Takeda, Yukio, Advisory Editor, Agrawal, Sunil K., Advisory Editor, Ciulli, Enrico, editor, and Ruggiero, Alessandro, editor

Published

2024

48. Diamond-Like Carbon Depositing on the Surface of Polylactide Membrane for Prevention of Adhesion Formation During Tendon Repair

Author

Yao Xiao, Zaijin Tao, Yufeng Ju, Xiaolu Huang, Xinshu Zhang, Xiaonan Liu, Pavel A. Volotovski, Chao Huang, Hongqi Chen, Yaozhong Zhang, and Shen Liu

Subjects

Diamond-like carbon, Reactive oxygen species scavenging, Foreign body reaction, Biodegradation, Antioxidant, Peritendinous adhesion, Technology

Abstract

Highlights The anti-adhesion effect of polylactic acid (PLA) membrane with diamond-like carbon (DLC) depositing is 44.72%, enhanced by 23.11% compared to PLA. DLC deposited on PLA membranes has been shown to effectively reduce the levels of reactive oxygen species, leading to a decrease in the expression of pro-inflammatory cytokines within peritendinous adhesion tissue. DLC decelerates PLA biodegradation and lactic production, which reduces the number of CD68+CD206+ macrophages within peritendinous adhesion tissue.

Published

2024

49. Desired: At the Intersection of Luxury and Technology.

Author

WHITE, JEREMY

Subjects

LUXURIES, BICYCLE racing, SOUND recording & reproducing, DIAMOND-like carbon, LED displays, HEADPHONES

Abstract

This article discusses several luxury and technology products. It highlights the Aston Martin .1R bicycle, which is a collaboration between Aston Martin and J.Laverack. The bicycle features a frame made of titanium and carbon fiber, with no visible bolts or attachments. Another product mentioned is the Model B3 armchair, inspired by Marcel Breuer's design and produced by Aram and Knoll. Other products include the Miniot Black Wheel Turntable, the Kustem Trolley, the Austrian Audio The Composer headphones, the Elipson W35 XI spherical speaker, and the Adsum + ELAC Debut Connex DCB41-DS speakers. [Extracted from the article]

Published

2024

50. Reduction in Powder Wall Friction by an a-C:H:Si Film.

Author

Lanzerstorfer, Christof, Forsich, Christian, Delfin, Francisco, Schachinger, Manuel C. J., and Heim, Daniel

Subjects

*FRICTION, *POWDERS, *ALUMINUM powder, *ALUMINUM oxide, *SILICON carbide, *CALCIUM carbonate

Abstract

The wall friction angle is an important parameter in powder flow. In a recent study for various powders, a reduction in the wall friction angle for steel was demonstrated by the application of an a-C:H:Si film on the steel surface. This work presents the results of a study of this effect in more detail regarding the influence of the powder material, the wall normal stress and the particle size of the powder for mass median diameters from 4 µm to approximately 150 µm. The wall friction angles were measured using a Schulze ring shear tester for three different powder materials: aluminum oxide, calcium carbonate and silicon carbide. The results showed little difference with respect to powder chemistry. For the coarser powders, the reduction in the wall friction angle due to the a-C:H:Si coating was highest (10° to 12°) and rather stress-independent, while for the fine and medium-size powders the reduction was lower and stress-dependent. With increasing wall normal stress, the reduction in the wall friction angle increased. These results can be explained by the friction reduction mechanism of a-C:H:Si, which requires a certain contact pressure for superficial graphitization. [ABSTRACT FROM AUTHOR]

Published

2024