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Your search keyword '"Popescu, Andrei C."' showing total 36 results
Start Over Author "Popescu, Andrei C." Publication Type Academic Journals
36 results on '"Popescu, Andrei C."'

9. In Situ Fabrication of TiC/Ti–Matrix Composites by Laser Directed Energy Deposition.

Author

Mihai, Sabin, Baciu, Florin, Radu, Robert, Chioibasu, Diana, and Popescu, Andrei C.

Subjects
SOLUTION strengthening, MECHANICAL wear, TITANIUM carbide, LASER beams, LASER deposition, HYPEREUTECTIC alloys, TITANIUM composites
Abstract

In this study, crack-free TiC/Ti composites with TiC content ranging from 0 to 15 wt.% were successfully fabricated using Direct Energy Deposition with a dual-feeder system that concomitantly delivered different amounts of both constituents into a high-power laser beam. The samples were investigated to evaluate the morphologies and distribution behavior of TiC. The microhardness values of the samples obtained under optimal processing conditions increased from 192 ± 5.3 HV0.2 (pure Ti) to 300 ± 14.2 HV0.2 (Ti + wt.% 15 TiC). Also, TiC has a significant impact on the Ti matrix, increasing the strength of TMCs up to 725 ± 5.4 MPa, while the elongation drastically decreased to 0.62 ± 0.04%. The wear rate is not proportionally affected by the rise content of TiC reinforcement; the hypoeutectic region of TMCs exhibited a wear rate of 2.45 mm3/N·m (Ti + wt.% 3 TiC) and a friction coefficient of 0.48 compared to the ones from the hypereutectic region, which measured a wear rate of 3.02 mm3/N·m (Ti + wt.% 15 TiC) and a friction coefficient of 0.63. The improved values of mechanical properties in the case of TMCs as compared to pure Ti are provided due to the solid solution strengthening of carbon and the fine grain strengthening. This work outlines a method for changing TiC morphologies to improve the hardness and tensile strength of TMCs fabricated starting from micro-scale powder. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Additive Manufacturing: Experiments, Simulations, and Data-Driven Modelling.

Author

Mahmood, Muhammad Arif, Ur Rehman, Asif, Khraisheh, Marwan, Salamci, Metin U., Ur Rehman, Rashid, Sajjad, Uzair, Ristoscu, Carmen, Popescu, Andrei C., Oane, Mihai, and Mihailescu, Ion N.

Subjects
MATERIALS science, MANUFACTURING processes, HEAT resistant alloys, FRICTION stir processing, NANOCOMPOSITE materials, TITANIUM alloys
Abstract

This document is an editorial from the journal "Crystals" that provides an overview of recent developments in additive manufacturing (AM) and highlights the studies featured in a special issue of the journal. The studies cover various aspects of AM, including laser additive manufacturing, electrodeposition, and fused filament fabrication, and explore innovations in material properties, microstructural control, and overall performance. The editorial also identifies existing knowledge gaps in AM and suggests future research directions, such as multi-material AM techniques, advanced simulation and modeling tools, scalability, sustainability, and long-term durability and performance studies. The document emphasizes the importance of continued research in these areas to fully realize the potential of AM and drive industrial innovation. [Extracted from the article]

Published
2024
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13. Laser Additive Manufacturing of Bulk Silicon Nitride Ceramic: Modeling versus Integral Transform Technique with Experimental Correlation.

Author

Mihailescu, Cristian N., Oane, Mihai, Sava, Bogdan A., Popescu, Andrei C., Elisa, Mihail, Mahmood, Muhammad Arif, Mihailescu, Natalia, Filip, Ana V., Anghel, Sinziana Andreea, Mihailescu, Ion N., and Ristoscu, Carmen

Subjects
INTEGRAL transforms, SILICON nitride, BEER-Lambert law, HEAT equation, LASERS, CERAMICS
Abstract

A semi-analytical-numerical solution is theorized to describe the laser additive manufacturing via laser-bulk ceramic interaction modeling. The Fourier heat equation was used to infer the thermal distribution within the ceramic sample. Appropriate boundary conditions, including convection and radiation, were applied to the bulk sample. It was irradiated with a Gaussian spatial continuous mode fiber laser (λ = 1.075 µm) while a Lambert-Beer law was assumed to describe the laser beam absorption. A close correlation between computational predictions versus experimental results was validated in the case of laser additive manufacturing of silicon nitride bulk ceramics. The thermal field value rises but stays confined within the irradiated zone due to heat propagation with an infinite speed, a characteristic of the Fourier heat equation. An inverse correlation was observed between the laser beam scanning speed and thermal distribution intensity. Whenever the laser scanning speed increases, photons interact with and transfer less energy to the sample, resulting in a lower thermal distribution intensity. This model could prove useful for the description and monitoring of low-intensity laser beam-ceramic processing. [ABSTRACT FROM AUTHOR]

Published
2022
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14. An Experimental Study on Nano-Carbon Films as an Anti-Wear Protection for Drilling Tools.

Author

Popescu, Camelia, Cristea, Daniel, Bita, Bogdan, Cristescu, Rodica, Craciun, Doina, Chioibasu, Georgiana Diana, Luculescu, Catalin, Paun, Irina, Duta, Liviu, and Popescu, Andrei C.

Subjects
CARBON, THIN films, PULSED laser deposition
Abstract

Carbon thin films of 50-100 nm thickness were synthesized by Pulsed Laser Deposition in vacuum at different laser fluences from 2 to 6 J/cm2. The deposited films were characterized by Raman spectroscopy for compositional assessment, scanning electron microscopy for morphology/thickness evaluations, and X-ray reflectivity for density, thickness, and roughness determinations. The films were ~100 nm thin, smooth, droplet-free, made of a-C:H type of diamond-like carbon. The mechanical properties of synthesized films were studied by nanoindentation and adhesion tests. The films that were obtained at low laser fluences (2, 3 J/cm2) had better mechanical properties as compared to those synthesized at higher fluences. The mean values of hardness were around 20 GPa, while the friction coefficient was 0.06. The deposition conditions of carbon thin films that displayed the best mechanical properties were further used to coat commercial drills. Both uncoated and coated drills were tested on plates that were made of three types of steel: Stainless steel 304, general use AISI 572 Gr 65 steel (OL60), and AISI D3 tool steel (C120). All of the drill edges and tips were studied by optical and scanning electron microscopes. The coated samples were clearly found to be more resistant, and displayed less morphological defects than their uncoated counterparts when drilling stainless steel and OL60 plates. In the case of C120 steel, carbon coatings failed because of the high friction between drill and the metal plate resulting in tip edges blunting that occurred during processing. [ABSTRACT FROM AUTHOR]

Published
2017
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15. Control of Porosity and Spatter in Laser Welding of Thick AlMg5 Parts Using High-Speed Imaging and Optical Microscopy.

Author

Popescu, Andrei C., Delval, Christophe, and Leparoux, Marc

Subjects
LASER welding, POROSITY, MICROSCOPY, OPTICAL microscopes, IRRADIATION
Abstract

We report on a feedback mechanism for rapid identification of optimal laser parameters during welding of AlMg5 coupons using real-time monitoring by high-speed imaging. The purpose was to constrain the liquid movement in the groove in order to obtain pore-free welds in this otherwise difficult-to-weld alloy. High-speed imaging of the welding process via an optical microscope allowed for recording at millimeter level, providing new information on liquid-metal dynamics during laser irradiation as well as plausible explanations for spatter occurrence and pores formation. The pore formation and especially the position of these pores had to be controlled in order to weld 3 mm thick samples. By tuning both laser power and pulse duration, pores were aligned on a single line, at the bottom of the weld. A laser pass of reduced power on that side was then sufficient for removing all pores and providing a suitable weld. [ABSTRACT FROM AUTHOR]

Published
2017
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16. Thickness Influence on In Vitro Biocompatibility of Titanium Nitride Thin Films Synthesized by Pulsed Laser Deposition.

Author

Duta, Liviu, Stan, George E., Popa, Adrian C., Husanu, Marius A., Moga, Sorin, Socol, Marcela, Zgura, Irina, Miculescu, Florin, Urzica, Iuliana, Popescu, Andrei C., and Mihailescu, Ion N.

Subjects
TITANIUM nitride films, BIOCOMPATIBILITY, PULSED laser deposition, BONDING of stainless steel, X-ray photoelectron spectroscopy
Abstract

We report a study on the biocompatibility vs. thickness in the case of titanium nitride (TiN) films synthesized on 410 medical grade stainless steel substrates by pulsed laser deposition. The films were grown in a nitrogen atmosphere, and their in vitro cytotoxicity was assessed according to ISO 10993-5 [1]. Extensive physical-chemical analyses have been carried out on the deposited structures with various thicknesses in order to explain the differences in biological behavior: profilometry, scanning electron microscopy, atomic force microscopy, X-ray photoelectron spectroscopy (XPS), X-ray diffraction and surface energy measurements. XPS revealed the presence of titanium oxynitride beside TiN in amounts that vary with the film thickness. The cytocompatibility of films seems to be influenced by their TiN surface content. The thinner films seem to be more suitable for medical applications, due to the combined high values of bonding strength and superior cytocompatibility. [ABSTRACT FROM AUTHOR]

Published
2016
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17. The Role of Ambient Gas and Pressure on the Structuring of Hard Diamond-Like Carbon Films Synthesized by Pulsed Laser Deposition.

Author

Popescu, Andrei C., Stan, George E., Duta, Liviu, Nita, Cristina, Popescu, Camelia, Surdu, Vasile-Adrian, Husanu, Marius-Adrian, Bita, Bogdan, Ghisleni, Rudy, Himcinschi, Cameliu, and Craciun, Valentin

Subjects
*CARBON films, *THIN films, *PULSED laser deposition, *DIAMOND films, *CHEMICAL bonds
Abstract

Hard carbon thin films were synthesized on Si (100) and quartz substrates by the Pulsed Laser Deposition (PLD) technique in vacuum or methane ambient to study their suitability for applications requiring high mechanical resistance. The deposited films' surface morphology was investigated by scanning electron microscopy, crystalline status by X-ray diffraction, packing and density by X-ray reflectivity, chemical bonding by Raman and X-ray photoelectron spectroscopy, adherence by "pull-out" measurements and mechanical properties by nanoindentation tests. Films synthesized in vacuum were a-C DLC type, while films synthesized in methane were categorized as a-C:H. The majority of PLD films consisted of two layers: one low density layer towards the surface and a higher density layer in contact with the substrate. The deposition gas pressure played a crucial role on films thickness, component layers thickness ratio, structure and mechanical properties. The films were smooth, amorphous and composed of a mixture of sp3-sp2 carbon, with sp3 content ranging between 50% and 90%. The thickness and density of the two constituent layers of a film directly determined its mechanical properties. [ABSTRACT FROM AUTHOR]

Published
2015
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18. Nanoprofiles evaluation of ZnO thin films by an evanescent light method.

Author

Mirchin, Nina, Peled, Aaron, Duta, Liviu, Popescu, Andrei C., Dorcioman, Gabriela, and Mihailescu, Ion N.

Abstract

ABSTRACT The extraction efficiency of evanescent light from ZnO nanolayers and their thickness profiles in the range of (1-105) nm was evaluated by a new microscopy technique, differential evanescent light intensity imaging method. It is based on capturing the evanescent light scattered by the layer of the material deposited on glass substrates. The analyzed ZnO films were obtained by pulsed laser deposition at 27°C and 100°C, using a nanosecond UV laser source. Microsc. Res. Tech., 76:992-996, 2013. © 2013 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published
2013
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19. Post-Processing Techniques to Enhance the Quality of Metallic Parts Produced by Additive Manufacturing.

Author

Mahmood, Muhammad Arif, Chioibasu, Diana, Ur Rehman, Asif, Mihai, Sabin, and Popescu, Andrei C.

Subjects
LASER peening, FATIGUE life, SURFACE finishing, GRAIN refinement, STRAIN rate
Abstract

Additive manufacturing (AM) processes can produce three-dimensional (3D) near-net-shape parts based on computer-aided design (CAD) models. Compared to traditional manufacturing processes, AM processes can generate parts with intricate geometries, operational flexibility and reduced manufacturing time, thus saving time and money. On the other hand, AM processes face complex issues, including poor surface finish, unwanted microstructure phases, defects, wear tracks, reduced corrosion resistance and reduced fatigue life. These problems prevent AM parts from real-time operational applications. Post-processing techniques, including laser shock peening, laser polishing, conventional machining methods and thermal processes, are usually applied to resolve these issues. These processes have proved their capability to enhance the surface characteristics and physical and mechanical properties. In this study, various post-processing techniques and their implementations have been compiled. The effect of post-processing techniques on additively manufactured parts has been discussed. It was found that laser shock peening (LSP) can cause severe strain rate generation, especially in thinner components. LSP can control the surface regularities and local grain refinement, thus elevating the hardness value. Laser polishing (LP) can reduce surface roughness up to 95% and increase hardness, collectively, compared to the as-built parts. Conventional machining processes enhance surface quality; however, their influence on hardness has not been proved yet. Thermal post-processing techniques are applied to eliminate porosity up to 99.99%, increase corrosion resistance, and finally, the mechanical properties' elevation. For future perspectives, to prescribe a particular post-processing technique for specific defects, standardization is necessary. This study provides a detailed overview of the post-processing techniques applied to enhance the mechanical and physical properties of AM-ed parts. A particular method can be chosen based on one's requirements. [ABSTRACT FROM AUTHOR]

Published
2022
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20. Non-Destructive X-ray Characterization of a Novel Joining Method Based on Laser-Melting Deposition for AISI 304 Stainless Steel.

Author

Mahmood, Muhammad Arif, Chioibasu, Diana, Mihai, Sabin, Iovea, Mihai, Mihailescu, Ion N., and Popescu, Andrei C.

Subjects
LASER welding, STAINLESS steel, FILLER materials, OXYACETYLENE welding & cutting, LASER deposition, X-rays
Abstract

In this study, an application of the laser-melting deposition additive manufacturing technique as a welding method has been studied for the laser welding (LW) of AISI 304 stainless steel, specifically 0.4 mm and 0.5 mm thick sheets. The welding was carried out without and with filler material. Inconel 718 powder particles were used as filler material in the second case. A series of experiments were designed by changing the process parameters to identify the effect of operating conditions on the weld width, depth, and height. The welds were examined through metallographic experiments performed at various cross-sections to identify the defects and pores. All the deposited welds were passed through a customized mini-focus X-ray system to analyze the weld uniformities. The optimal operating conditions were determined for 0.4 mm and 0.5 mm sheets for the LW with and without filler material. It was found that laser power, laser scanning speed, powder flow rate, and helium to argon gases mixture-control the weld bead dimensions and quality. X-ray analyses showed that the optimal operating conditions gave the least peak value of non-uniformity in the laser welds. This study opens a new window for laser welding via additive manufacturing with X-ray monitoring. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Spatter Formation and Splashing Induced Defects in Laser-Based Powder Bed Fusion of AlSi10Mg Alloy: A Novel Hydrodynamics Modelling with Empirical Testing.

Author

Ur Rehman, Asif, Mahmood, Muhammad Arif, Ansari, Peyman, Pitir, Fatih, Salamci, Metin Uymaz, Popescu, Andrei C., and Mihailescu, Ion N.

Subjects
ALLOY powders, COMPUTATIONAL fluid dynamics, HYDRODYNAMICS, MARANGONI effect, POWDERS, ALLOYS, ELECTROHYDRAULIC effect, LASER deposition
Abstract

Powder spattering and splashing in the melt pool are common phenomena during Laser-based Powder Bed Fusion (LPBF) of metallic materials having high fluidity. For this purpose, analytical and computational fluid dynamics (CFD) models have been deduced for the LPBF of AlSi10Mg alloy. The single printed layer's dimensions were estimated using primary operating conditions for the analytical model. In CFD modelling, the volume of fluid and discrete element modelling techniques were applied to illustrate the splashing and spatter phenomena, providing a novel hydrodynamics CFD model for LPBF of AlSi10Mg alloy. The computational results were compared with the experimental analyses. A trial-and-error method was used to propose an optimized set of parameters for the LPBF of AlSi10Mg alloy. Laser scanning speed, laser spot diameter and laser power were changed. On the other hand, the powder layer thickness and hatch distance were kept constant. Following on, 20 samples were fabricated using the LPBF process. The printed samples' microstructures were used to select optimized parameters for achieving defect-free parts. It was found that the recoil pressure, vaporization, high-speed vapor cloud, Marangoni flow, hydraulic pressure and buoyancy are all controlled by the laser-material interaction time. As the laser-AlSi10Mg material interaction period progresses, the forces presented above become dominant. Splashing occurs due to a combination of increased recoil pressure, laser-material interaction time, higher material's fluidity, vaporization, dominancy of Marangoni flow, high-speed vapor cloud, hydraulic pressure, buoyancy, and transformation of keyhole from J-shape to reverse triangle-shape that is a tongue-like protrusion in the keyhole. In the LPBF of AlSi10Mg alloy, only the conduction mode melt flow has been determined. For multi-layers printing of AlSi10Mg alloy, the optimum operating conditions are laser power = 140 W, laser spot diameter = 180 µm, laser scanning speed = 0.6 m/s, powder layer thickness = 50 µm and hatch distance = 112 µm. These conditions have been identified using sample microstructures. [ABSTRACT FROM AUTHOR]

Published
2021
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22. Keyhole Formation by Laser Drilling in Laser Powder Bed Fusion of Ti6Al4V Biomedical Alloy: Mesoscopic Computational Fluid Dynamics Simulation versus Mathematical Modelling Using Empirical Validation.

Author

Ur Rehman, Asif, Mahmood, Muhammad Arif, Pitir, Fatih, Salamci, Metin Uymaz, Popescu, Andrei C., and Mihailescu, Ion N.

Subjects
COMPUTATIONAL fluid dynamics, LATENT heat of fusion, LASER drilling, THERMAL resistance, SPECIFIC heat, POWDERS
Abstract

In the laser powder bed fusion (LPBF) process, the operating conditions are essential in determining laser-induced keyhole regimes based on the thermal distribution. These regimes, classified into shallow and deep keyholes, control the probability and defects formation intensity in the LPBF process. To study and control the keyhole in the LPBF process, mathematical and computational fluid dynamics (CFD) models are presented. For CFD, the volume of fluid method with the discrete element modeling technique was used, while a mathematical model was developed by including the laser beam absorption by the powder bed voids and surface. The dynamic melt pool behavior is explored in detail. Quantitative comparisons are made among experimental, CFD simulation and analytical computing results leading to a good correspondence. In LPBF, the temperature around the laser irradiation zone rises rapidly compared to the surroundings in the powder layer due to the high thermal resistance and the air between the powder particles, resulting in a slow travel of laser transverse heat waves. In LPBF, the keyhole can be classified into shallow and deep keyhole mode, controlled by the energy density. Increasing the energy density, the shallow keyhole mode transforms into the deep keyhole mode. The energy density in a deep keyhole is higher due to the multiple reflections and concentrations of secondary reflected beams within the keyhole, causing the material to vaporize quickly. Due to an elevated temperature distribution in deep keyhole mode, the probability of pores forming is much higher than in a shallow keyhole as the liquid material is close to the vaporization temperature. When the temperature increases rapidly, the material density drops quickly, thus, raising the fluid volume due to the specific heat and fusion latent heat. In return, this lowers the surface tension and affects the melt pool uniformity. [ABSTRACT FROM AUTHOR]

Published
2021
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23. Real-Time Defects Analyses Using High-Speed Imaging during Aluminum Magnesium Alloy Laser Welding.

Author

Mihai, Sabin, Chioibasu, Diana, Mahmood, Muhammad Arif, Duta, Liviu, Leparoux, Marc, and Popescu, Andrei C.

Subjects
LASER welding, YTTERBIUM, ALUMINUM-magnesium alloys, ALUMINUM alloys, YTTRIUM aluminum garnet, ALUMINUM alloying, MAGNESIUM alloys
Abstract

In this study a continuous wave Ytterbium-doped Yttrium Aluminum Garnet (Yb: YAG) disk laser has been used for welding of AlMg3 casted alloy. A high-speed imaging camera has been employed to record hot vapor plume features during the process. The purpose was to identify a mechanism of pores detection in real-time based on correlations between metallographic analyses and area/intensity of the hot vapor in various locations of the samples. The pores formation and especially the position of these pores had to be kept under control in order to weld thick samples. Based on the characterization of the hot vapor, it has been found that the increase of the vapor area that exceeded a threshold value (18.5 ± 1 mm2) was a sign of pores formation within the weld seam. For identification of the pores' locations during welding, the monitored element was the hot vapor intensity. The hot vapor core spots having a grayscale level reaching 255 was associated with the formation of a local pore. These findings have been devised based on correlation between pores placement in welds cross-section microscopy images and the hot vapor plume features in those respective positions. [ABSTRACT FROM AUTHOR]

Published
2021
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24. Mesoscopic Computational Fluid Dynamics Modelling for the Laser-Melting Deposition of AISI 304 Stainless Steel Single Tracks with Experimental Correlation: A Novel Study.

Author

Ur Rehman, Asif, Mahmood, Muhammad Arif, Pitir, Fatih, Salamci, Metin Uymaz, Popescu, Andrei C., and Mihailescu, Ion N.

Subjects
SELECTIVE laser melting, STAINLESS steel, LASER beams, SURFACE tension, COMPUTATIONAL fluid dynamics, STREAMING video & television
Abstract

For laser-melting deposition (LMD), a computational fluid dynamics (CFD) model was developed using the volume of fluid and discrete element modeling techniques. A method was developed to track the flow behavior, flow pattern, and driving forces of liquid flow. The developed model was compared with experimental results in the case of AISI 304 stainless steel single-track depositions on AISI 304 stainless steel substrate. A close correlation was found between experiments and modeling, with a deviation of 1–3%. It was found that the LMD involves the simultaneous addition of powder particles that absorb a significant amount of laser energy to transform their phase from solid to liquid, resulting in conduction-mode melt flow. The bubbles within the melt pool float at a specific velocity and escape from the melt pool throughout the deposition process. The pores are generated if the solid front hits the bubble before escaping the melt pool. Based on the simulations, it was discovered that the deposited layer's counters took the longest time to solidify compared to the overall deposition. The bubbles strived to leave through the contours in an excess quantity, but became stuck during solidification, resulting in a large degree of porosity near the contours. The stream traces showed that the melt flow adopted a clockwise vortex in front of the laser beam and an anti-clockwise vortex behind the laser beam. The difference in the surface tension between the two ends of the melt pool induces "thermocapillary or Benard–Marangoni convection" force, which is insignificant compared to the selective laser melting process. After layer deposition, the melt region, mushy zone, and solidified region were identified. When the laser beam irradiates the substrate and powder particles are added simultaneously, the melt adopts a backwards flow due to the recoil pressure and thermocapillary or Benard–Marangoni convection effect, resulting in a negative mass flow rate. This study provides an in-depth understanding of melt pool dynamics and flow pattern in the case of LMD additive manufacturing technique. [ABSTRACT FROM AUTHOR]

Published
2021
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25. A State-of-the-Art Review on Integral Transform Technique in Laser–Material Interaction: Fourier and Non-Fourier Heat Equations.

Author

Oane, Mihai, Mahmood, Muhammad Arif, and Popescu, Andrei C.

Subjects
ORDINARY differential equations, PARTIAL differential equations, ELECTRON beams, ATTOSECOND pulses, INTEGRAL transforms, LASER beams
Abstract

Heat equations can estimate the thermal distribution and phase transformation in real-time based on the operating conditions and material properties. Such wonderful features have enabled heat equations in various fields, including laser and electron beam processing. The integral transform technique (ITT) is a powerful general-purpose semi-analytical/numerical method that transforms partial differential equations into a coupled system of ordinary differential equations. Under this category, Fourier and non-Fourier heat equations can be implemented on both equilibrium and non-equilibrium thermo-dynamical processes, including a wide range of processes such as the Two-Temperature Model, ultra-fast laser irradiation, and biological processes. This review article focuses on heat equation models, including Fourier and non-Fourier heat equations. A comparison between Fourier and non-Fourier heat equations and their generalized solutions have been discussed. Various components of heat equations and their implementation in multiple processes have been illustrated. Besides, literature has been collected based on ITT implementation in various materials. Furthermore, a future outlook has been provided for Fourier and non-Fourier heat equations. It was found that the Fourier heat equation is simple to use but involves infinite speed heat propagation in comparison to the non-Fourier heat equation and can be linked with the Two-Temperature Model in a natural way. On the other hand, the non-Fourier heat equation is complex and involves various unknowns compared to the Fourier heat equation. Fourier and Non-Fourier heat equations have proved their reliability in the case of laser–metallic materials, electron beam–biological and –inorganic materials, laser–semiconducting materials, and laser–graphene material interactions. It has been identified that the material properties, electron–phonon relaxation time, and Eigen Values play an essential role in defining the precise results of Fourier and non-Fourier heat equations. In the case of laser–graphene interaction, a restriction has been identified from ITT. When computations are carried out for attosecond pulse durations, the laser wavelength approaches the nucleus-first electron separation distance, resulting in meaningless results. [ABSTRACT FROM AUTHOR]

Published
2021
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26. 3D Printing at Micro-Level: Laser-Induced Forward Transfer and Two-Photon Polymerization.

Author

Mahmood, Muhammad Arif and Popescu, Andrei C.

Subjects
*THREE-dimensional printing, *PRINT materials, *MECHANICAL properties of condensed matter, *SHOCK waves, *POLYMERIZATION, *MICROFLUIDICS
Abstract

Laser-induced forward transfer (LIFT) and two-photon polymerization (TPP) have proven their abilities to produce 3D complex microstructures at an extraordinary level of sophistication. Indeed, LIFT and TPP have supported the vision of providing a whole functional laboratory at a scale that can fit in the palm of a hand. This is only possible due to the developments in manufacturing at micro- and nano-scales. In a short time, LIFT and TPP have gained popularity, from being a microfabrication innovation utilized by laser experts to become a valuable instrument in the hands of researchers and technologists performing in various research and development areas, such as electronics, medicine, and micro-fluidics. In comparison with conventional micro-manufacturing methods, LIFT and TPP can produce exceptional 3D components. To gain benefits from LIFT and TPP, in-detail comprehension of the process and the manufactured parts' mechanical–chemical characteristics is required. This review article discusses the 3D printing perspectives by LIFT and TPP. In the case of the LIFT technique, the principle, classification of derivative methods, the importance of flyer velocity and shock wave formation, printed materials, and their properties, as well as various applications, have been discussed. For TPP, involved mechanisms, the difference between TPP and single-photon polymerization, proximity effect, printing resolution, printed material properties, and different applications have been analyzed. Besides this, future research directions for the 3D printing community are reviewed and summarized. [ABSTRACT FROM AUTHOR]

Published
2021
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27. Current Research in Pulsed Laser Deposition.

Author

Duta, Liviu and Popescu, Andrei C.

Subjects
PULSED laser deposition, OSSEOINTEGRATION, IRON oxides, ORGANIC light emitting diodes, BIOMATERIALS, ALUMINUM nitride films, LASER deposition
Abstract

Over the last years, an increasing research interest was observed in the field of PLD synthesis of oxides and nitrides. When compared to other plasma-assisted deposition methods, such as plasma spraying or plasma enhanced chemical vapor deposition, the Pulsed Laser Deposition (PLD) technique stands as a simple, versatile, rapid, and cost-effective approach for the fabrication of high-quality structures from a wide range of materials [1,2]. One should note that, in the dedicated literature, there are studies on the in vivo testing of CaP-based coatings (especially HA) synthesized by numerous physical vapor deposition methods, but only few of them addressed the PLD technique. An important aspect that should be mentioned is related to the targets' preparation for PLD synthesis of iron-doped indium oxide films. [Extracted from the article]

Published
2021
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28. Thermal Nonlinear Klein–Gordon Equation for Nano-/Micro-Sized Metallic Particle–Attosecond Laser Pulse Interaction.

Author

Oane, Mihai, Mahmood, Muhammad Arif, Popescu, Andrei C., Bănică, Alexandra, Ristoscu, Carmen, Mihăilescu, Ion N., and Schneider, Christof

Subjects
KLEIN-Gordon equation, LASER pulses, NONLINEAR equations, ATTOSECOND pulses, ATOMIC scattering, ULTRASHORT laser pulses, LASER beams
Abstract

In this study, a rigorous analytical solution to the thermal nonlinear Klein–Gordon equation in the Kozłowski version is provided. The Klein–Gordon heat equation is solved via the Zhukovsky "state-of-the-art" mathematical techniques. Our study can be regarded as an initial approximation of attosecond laser–particle interaction when the prevalent phenomenon is photon–electron interaction. The electrons interact with the laser beam, which means that the nucleus does not play a significant role in temperature distribution. The particle is supposed to be homogenous with respect to thermophysical properties. This theoretical approach could prove useful for the study of metallic nano-/micro-particles interacting with attosecond laser pulses. Specific applications for Au "nano" particles with a 50 nm radius and "micro" particles with 110, 130, 150, and 1000 nm radii under 100 attosecond laser pulse irradiation are considered. First, the cross-section is supposed to be proportional to the area of the particle, which is assumed to be a perfect sphere of radius R or a rotation ellipsoid. Second, the absorption coefficient is calculated using a semiclassical approach, taking into account the number of atoms per unit volume, the classical electron radius, the laser wavelength, and the atomic scattering factor (10 in case of Au), which cover all the basic aspects for the interaction between the attosecond laser and a nanoparticle. The model is applicable within the 100–2000 nm range. The main conclusion of the model is that for a range inferior to 1000 nm, a competition between ballistic and thermal phenomena occurs. For values in excess of 1000 nm, our study suggests that the thermal phenomena are dominant. Contrastingly, during the irradiation with fs pulses, this value is of the order of 100 nm. This theoretical model's predictions could be soon confirmed with the new EU-ELI facilities in progress, which will generate pulses of 100 as at a 30 nm wavelength. [ABSTRACT FROM AUTHOR]

Published
2021
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29. Use of X-ray Computed Tomography for Assessing Defects in Ti Grade 5 Parts Produced by Laser Melting Deposition.

Author

Chioibasu, Diana, Mihai, Sabin, Mahmood, Muhammad Arif, Lungu, Mihail, Porosnicu, Ioana, Sima, Adrian, Dobrea, Cosmin, Tiseanu, Ion, and Popescu, Andrei C.

Subjects
COMPUTED tomography, LASER deposition, SCIENTIFIC literature, DENTAL metallurgy, PRINTMAKING
Abstract

Laser Melting Deposition (LMD) is a metal printing technique that allows for the manufacturing of large objects by Directed Energy Deposition. Due to its versatility in variation of parameters, the possibility to use two or more materials, to create alloys in situ or produce multi-layer structures, LMD is still being scientifically researched and is still far from industrial maturity. The structural testing of obtained samples can be time consuming and solutions that can decrease the samples analysis time are constantly proposed in the scientific literature. In this manuscript we present a quality improvement study for obtaining defect-free bulk samples of Ti6Al4V under X-Ray Computed Tomography (XCT) by varying the hatch spacing and distance between planes. Based on information provided by XCT, the experimental conditions were changed until complete elimination of porosity. Information on the defects in the bulk of the samples by XCT was used for feedback during parameters tuning in view of complete removal of pores. The research time was reduced to days instead of weeks or months of samples preparation and analysis by destructive metallographic techniques. [ABSTRACT FROM AUTHOR]

Published
2020
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30. In Vivo Assessment of Bone Enhancement in the Case of 3D-Printed Implants Functionalized with Lithium-Doped Biological-Derived Hydroxyapatite Coatings: A Preliminary Study on Rabbits.

Author

Duta, Liviu, Neamtu, Johny, Melinte, Razvan P., Zureigat, Oana A., Popescu-Pelin, Gianina, Chioibasu, Diana, Oktar, Faik N., and Popescu, Andrei C.

Subjects
HYDROXYAPATITE coating, BONES, PULSED laser deposition, HYDROXYAPATITE, METAL coating, SCANNING electron microscopy, SURFACE coatings
Abstract

We report on biological-derived hydroxyapatite (HA, of animal bone origin) doped with lithium carbonate (Li-C) and phosphate (Li-P) coatings synthesized by pulsed laser deposition (PLD) onto Ti6Al4V implants, fabricated by the additive manufacturing (AM) technique. After being previously validated by in vitro cytotoxicity tests, the Li-C and Li-P coatings synthesized onto 3D Ti implants were preliminarily investigated in vivo, by insertion into rabbits' femoral condyles. The in vivo experimental model for testing the extraction force of 3D metallic implants was used for this study. After four and nine weeks of implantation, all structures were mechanically removed from bones, by tensile pull-out tests, and coatings' surfaces were investigated by scanning electron microscopy. The inferred values of the extraction force corresponding to functionalized 3D implants were compared with controls. The obtained results demonstrated significant and highly significant improvement of functionalized implants' attachment to bone (p-values ≤0.05 and ≤0.00001), with respect to controls. The correct placement and a good integration of all 3D-printed Ti implants into the surrounding bone was demonstrated by performing computed tomography scans. This is the first report in the dedicated literature on the in vivo assessment of Li-C and Li-P coatings synthesized by PLD onto Ti implants fabricated by the AM technique. Their improved mechanical characteristics, along with a low fabrication cost from natural, sustainable resources, should recommend lithium-doped biological-derived materials as viable substitutes of synthetic HA for the fabrication of a new generation of metallic implant coatings. [ABSTRACT FROM AUTHOR]

Published
2020
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31. Three-Jet Powder Flow and Laser–Powder Interaction in Laser Melting Deposition: Modelling Versus Experimental Correlations.

Author

Mahmood, Muhammad Arif, Popescu, Andrei C., Oane, Mihai, Ristoscu, Carmen, Chioibasu, Diana, Mihai, Sabin, and Mihailescu, Ion N.

Subjects
POWDERS, TEMPERATURE distribution, LASER deposition, BOILING-points, LASER beams, ENERGY density, COMPUTER simulation
Abstract

Powder flow and temperature distribution are recognized as essential factors in the laser melting deposition (LMD) process, which affect not only the layer formation but also its characteristics. In this study, two mathematical models were developed. Initially, the three-jet powder flow in the Gaussian shape was simulated for the LMD process. Next, the Gaussian powder flow was coaxially added along with the moving laser beam to investigate the effect of powder flow on temperature distribution at the substrate. The powder particles' inflight and within melt-pool heating times were controlled to avoid vapors or plasma formation due to excessive heat. Computations were carried out via MATLAB software. A high-speed imaging camera was used to monitor the powder stream distribution, experimentally, while temperature distribution results were compared with finite element simulations and experimental analyses. A close correlation was observed among analytical computation, numerical simulations, and experimental results. An investigation was conducted to investigate the effect of the focal point position on powder stream distribution. It was found that the focal point position plays a key role in determining the shape of the powder stream, such that an increment in the distance from the focus point will gradually transform the powder stream from the Gaussian to Transition, and from the Transition to Annular streams. By raising the powder flow rate, the attenuation ratio prevails in the LMD process, hence, decreasing the laser energy density arriving at the substrate. The computations indicate that, if the particle's heating temperature surpasses the boiling point, a strong possibility exists for vapors and plasma formation. Consequently, an excessive amount of laser energy is absorbed by the produced vapors and plasma, thus impeding the deposition process. [ABSTRACT FROM AUTHOR]

Published
2020
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32. Metal Matrix Composites Synthesized by Laser-Melting Deposition: A Review.

Author

Mahmood, Muhammad Arif, Popescu, Andrei C., and Mihailescu, Ion N.

Subjects
*METALLIC composites, *TENSILE strength, *RAPID prototyping, *MECHANICAL properties of metals, *WEAR resistance
Abstract

Metal matrix composites (MMCs) present extraordinary characteristics, including high wear resistance, excellent operational properties at elevated temperature, and better chemical inertness as compared to traditional alloys. These properties make them prospective candidates in the fields of aerospace, automotive, heavy goods vehicles, electrical, and biomedical industries. MMCs are challenging to process via traditional manufacturing techniques, requiring high cost and energy. The laser-melting deposition (LMD) has recently been used to manufacture MMCs via rapid prototyping, thus, solving these drawbacks. Besides the benefits mentioned above, the issues such as lower ultimate tensile strength, yield strength, weak bonding between matrix and reinforcements, and cracking are still prevalent in parts produced by LMD. In this article, a detailed analysis is made on the MMCs manufactured via LMD. An illustration is presented on the LMD working principle, its classification, and dependent and independent process parameters. Moreover, a brief comparison between the wire and powder-based LMDs has been summarized. Ex- and in-situ MMCs and their preparation techniques are discussed. Besides this, various matrices available for MMCs manufacturing, properties of MMCs after printing, possible complications and future research directions are reviewed and summarized. [ABSTRACT FROM AUTHOR]

Published
2020
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33. Non-Fourier Estimate of Electron Temperature in Case of Femtosecond Laser Pulses Interaction with Metals.

Author

Bucă, Anca M., Oane, Mihai, Mahmood, Muhammad Arif, Mihăilescu, Ion N., Popescu, Andrei C., Sava, Bogdan A., and Ristoscu, Carmen

Subjects
ELECTRON temperature, THERMAL electrons, FEMTOSECOND pulses, THERMAL conductivity, LASER pulses, ULTRASHORT laser pulses, HEAT equation
Abstract

This work is devoted to the electron temperature variation in metals through interaction with femtosecond laser pulses. Our study was inspired by the last mathematical breakthroughs regarding the exact analytical solutions of the heat equation in the case of flash laser-matter interaction. To this purpose, the classical Anisimov's two temperature model was extended via the 3D telegraph Zhukovsky equation. Based upon this new approach, the computational plots of electron thermal fields during the first laser pulse interaction with a gold surface were inferred. It is shown that relaxation times and coupling factors over electron thermal conductivities (g/K) govern the interaction between the laser pulse and metal sample during the first picoseconds. The lower the factor g/K, the higher the electron temperature becomes. In contrast, the lower the relaxation time, the lower the electron temperature. [ABSTRACT FROM AUTHOR]

Published
2020
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34. Animal Origin Bioactive Hydroxyapatite Thin Films Synthesized by RF-Magnetron Sputtering on 3D Printed Cranial Implants.

Author

Chioibasu, Diana, Duta, Liviu, Popescu-Pelin, Gianina, Popa, Nicoleta, Milodin, Nichita, Iosub, Stefana, Balescu, Liliana Marinela, Catalin Galca, Aurelian, Claudiu Popa, Adrian, Oktar, Faik N., Stan, George E., and Popescu, Andrei C.

Subjects
THIN films, HYDROXYAPATITE, OSSEOINTEGRATION, MAGNETRON sputtering, RADIO frequency, PRINT materials, SKULL fractures
Abstract

Ti6Al4V cranial prostheses in the form of patterned meshes were 3D printed by selective laser melting in an argon environment; using a CO2 laser source and micron-sized Ti6Al4V powder as the starting material. The size and shape of prostheses were chosen based on actual computer tomography images of patient skull fractures supplied in the framework of a collaboration with a neurosurgery clinic. After optimizations of scanning speed and laser parameters, the printed material was defect-free (as shown by metallographic analyses) and chemically homogeneous, without elemental segregation or depletion. The prostheses were coated by radio-frequency magnetron sputtering (RF-MS) with a bioactive thin layer of hydroxyapatite using a bioceramic powder derived from biogenic resources (Bio-HA). Initially amorphous, the films were converted to fully-crystalline form by applying a post-deposition thermal-treatment at 500 °C/1 h in air. The X-ray diffraction structural investigations indicated the phase purity of the deposited films composed solely of a hexagonal hydroxyapatite-like compound. On the other hand, the Fourier transform infrared spectroscopic investigations revealed that the biological carbonatation of the bone mineral phase was well-replicated in the case of crystallized Bio-HA RF-MS implant coatings. The in vitro acellular assays, performed in both the fully inorganic Kokubo's simulated body fluid and the biomimetic organic–inorganic McCoy's 5A cell culture medium up to 21 days, emphasized both the good resistance to degradation and the biomineralization capacity of the films. Further in vitro tests conducted in SaOs-2 osteoblast-like cells showed a positive proliferation rate on the Bio-HA RF-MS coating along with a good adhesion developed on the biomaterial surface by elongated membrane protrusions. [ABSTRACT FROM AUTHOR]

Published
2019
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35. Lithium-Doped Biological-Derived Hydroxyapatite Coatings Sustain In Vitro Differentiation of Human Primary Mesenchymal Stem Cells to Osteoblasts.

Author

Florian, Paula E., Duta, Liviu, Grumezescu, Valentina, Popescu-Pelin, Gianina, Popescu, Andrei C., Oktar, Faik N., Evans, Robert W., and Roseanu Constantinescu, Anca

Subjects
HYDROXYAPATITE coating, PULSED laser deposition, OSTEOBLASTS, DRUG coatings, EXTRACELLULAR matrix, MESENCHYMAL stem cells, SURFACE coatings, CELL adhesion
Abstract

This study is focused on the adhesion and differentiation of the human primary mesenchymal stem cells (hMSC) to osteoblasts lineage on biological-derived hydroxyapatite (BHA) and lithium-doped BHA (BHA:LiP) coatings synthesized by Pulsed Laser Deposition. An optimum adhesion of the cells on the surface of BHA:LiP coatings compared to control (uncoated Ti) was demonstrated using immunofluorescence labelling of actin and vinculin, two proteins involved in the initiation of the cell adhesion process. BHA:LiP coatings were also found to favor the differentiation of the hMSC towards an osteoblastic phenotype in the presence of osteoinductive medium, as revealed by the evaluation of osteoblast-specific markers, osteocalcin and alkaline phosphatase. Numerous nodules of mineralization secreted from osteoblast cells grown on the surface of BHA:LiP coatings and a 3D network-like organization of cells interconnected into the extracellular matrix were evidenced. These findings highlight the good biocompatibility of the BHA coatings and demonstrate that the use of lithium as a doping agent results in an enhanced osteointegration potential of the synthesized biomaterials, which might therefore represent viable candidates for future in vivo applications. [ABSTRACT FROM AUTHOR]

Published
2019
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36. Current Status on Pulsed Laser Deposition of Coatings from Animal-Origin Calcium Phosphate Sources.

Author

Duta, Liviu and Popescu, Andrei C.

Subjects
PULSED laser deposition, CALCIUM phosphate, SCIENTIFIC literature, SURFACE coatings, THIN films testing, THIN films
Abstract

The aim of this paper is to present the current status on animal-origin hydroxyapatite (HA) coatings synthesized by Pulsed Laser Deposition (PLD) technique for medical implant applications. PLD as a thin film synthesis method, although limited in terms of surface covered area, still gathers interest among researchers due to its advantages such as stoichiometric transfer, thickness control, film adherence, and relatively simple experimental set-up. While animal-origin HA synthesized by bacteria or extracted from animal bones, eggshells, and clams was tested in the form of thin films or scaffolds as a bioactive agent before, the reported results on PLD coatings from HA materials extracted from natural sources were not gathered and compared until the present study. Since natural apatite contains trace elements and new functional groups, such as CO32− and HPO42− in its complex molecules, physical-chemical results on the transfer of animal-origin HA by PLD are extremely interesting due to the stoichiometric transfer possibilities of this technique. The points of interest of this paper are the origin of HA from various sustainable resources, the extraction methods employed, the supplemental functional groups, and ions present in animal-origin HA targets and coatings as compared to synthetic HA, the coatings' morphology function of the type of HA, and the structure and crystalline status after deposition (where properties were superior to synthetic HA), and the influence of various dopants on these properties. The most interesting studies published in the last decade in scientific literature were compared and morphological, elemental, structural, and mechanical data were compiled and interpreted. The biological response of different types of animal-origin apatites on a variety of cell types was qualitatively assessed by comparing MTS assay data of various studies, where the testing conditions were possible. Antibacterial and antifungal activity of some doped animal-origin HA coatings was also discussed. [ABSTRACT FROM AUTHOR]

Published
2019
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