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1. Nanoparticle Sintering Model: Simulation and Calibration Against Experimental Data

   https://doi.org/10.1115/1.4041668  

   Dibua, Obehi G.; Yuksel, Anil; Roy, Nilabh K.; Foong, Chee S.; Cullinan, Michael (December 2018, Journal of Micro and Nano-Manufacturing)

   One of the limitations of commercially available metal additive manufacturing (AM) processes is the minimum feature size most processes can achieve. A proposed solution to bridge this gap is microscale selective laser sintering (μ-SLS). The advent of this process creates a need for models which are able to predict the structural properties of sintered parts. While there are currently a number of good SLS models, the majority of these models predict sintering as a melting process which is accurate for microparticles. However, when particles tend to the nanoscale, sintering becomes a diffusion process dominated by grain boundary and surface diffusion between particles. As such, this paper presents an approach to model sintering by tracking the diffusion between nanoparticles on a bed scale. Phase field modeling (PFM) is used in this study to track the evolution of particles undergoing sintering. Changes in relative density are then calculated from the results of the PFM simulations. These results are compared to experimental data obtained from furnace heating done on dried copper nanoparticle inks, and the simulation constants are calibrated to match physical properties. 

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2. RAPID INTENSE PULSE LIGHT SINTERING OF COPPER SULPHIDE NANOPARTICLE FILMS

   Bansal, S.; Gao, Z.; Chang, C-H; Malhotra, R. (June 2017, 2017 12th International Manufacturing Science and Engineering Conference MSEC2017)

   Copper sulphide (CuxS, x=1 to 2) is a metal chalcogenide semiconductor that exhibits useful optical and electrical properties due to the presence of copper vacancies. This makes CuxS thin films useful for a number of applications including infrared absorbing coatings, solar cells, thin-film electronics, and as a precursor for CZTS (Copper Zinc Tin Sulphide) thin films. Post-deposition sintering of CuxS nanoparticle films is a key process that affects the film properties and hence determines its operational characteristics in the above applications. Intense pulse light (IPL) sintering uses visible broad-spectrum xenon light to rapidly sinter nanoparticle films over large-areas, and is compatible with methods such as roll-to-roll deposition for large-area deposition of colloidal nanoparticle films and patterns. This paper experimentally examines the effect of IPL parameters on sintering of CuxS thin films. As-deposited and sintered films are compared in terms of their crystal structure, as well as optical and electrical properties, as a function of the IPL parameters. 

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3. Rapid 3D Printing of Nanoporous Copper Powders via Micro-Clip

   https://doi.org/10.1115/MSEC2023-104610  

   Liu, Luyang; Kublik, Natalya; Azeredo, Bruno; Chen, Xiangfan (June 2023, ASME 2023 18th International Manufacturing Science and Engineering Conference)

   Abstract Three-dimensional (3D) printing of metal components through powder bed fusion, material extrusion, and vat photopolymerization, has attracted interest continuously. Particularly, extrusion-based and photopolymerization-based processes employ metal particle-reinforced polymer matrix composites (PMCs) as raw materials. However, the resolution for extrusion-based printing is limited by the speed-accuracy tradeoff. In contrast, photopolymerization-based processes can significantly improve the printing resolution, but the filler loading of the PMC is typically low due to the critical requirement on raw materials’ rheological properties. Herein, we develop a new metal 3D printing strategy by utilizing micro-continuous liquid interface printing (μCLIP) to print PMC resins comprising nanoporous copper (NP-Cu) powders. By balancing the need for higher filler loading and the requirements on rheological properties to enable printability for the μCLIP, the compositions of PMC resin were optimized. In detail, the concentration of the NP-Cu powders in the resins can reach up to 40 wt% without sacrificing the printability and printing speed (10 μm·s−1). After sintering, 3D copper structures with microscale features (470 ± 140 μm in diameter) manifesting an average resistivity of 150 kΩ·mm can be realized. In summary, this new strategy potentially benefits the rapid prototyping of metal components with higher resolution at faster speeds. 

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4. Additive manufacturing of high‐density silicon carbide ceramics through post‐processing spark plasma sintering

   https://doi.org/10.1111/ijac.15167  

   Xiang, Yuhui; Doran, Spencer; Chang, Tzu‐Yi; Wang, Zexiao; Sangkagoon, Smitanan; Yeung, Yun; Xue, Fei; Cheng, Tian‐Le; Zhao, Dong; Lian, Jie; et al (May 2025, International Journal of Applied Ceramic Technology)

   Abstract This research advances the field of additive manufacturing (AM) of silicon carbide (SiC) ceramics by integrating spark plasma sintering (SPS) to enhance material density, mechanical strength, and thermal properties. Traditional AM techniques struggle to achieve the high‐density SiC required for demanding applications, such as aerospace engineering, where high thermal conductivity and mechanical strength are paramount. Our study addresses these challenges by incorporating SPS as a post‐processing step, achieving near‐theoretical maximum densities and significantly reducing porosity, thereby resulting in outstanding thermal conductivity in SiC ceramics. We developed a specialized SiC ink optimized for 3D printing, ensuring structural integrity after deposition through tailored rheological properties. The application of SPS facilitates rapid, uniform sintering, essential for attaining superior density, mechanical properties, and thermal performance. Our experimental results, confirmed through scanning electron microscopy analysis, demonstrate significant microstructural properties, mechanical strength, and thermal conductivity, showcasing the effectiveness of integrating SPS in AM processes. This innovative approach not only expands the capabilities of AM in producing complex, high‐density ceramic structures but also broadens the potential applications of SiC in demanding environments. 

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5. Development of a Novel, All‐Aromatic High Tensile Modulus Liquid Crystalline Polyimide for Fused Filament Fabrication Applications

   https://doi.org/10.1002/adfm.202419148  

   Yu, Zhenning; Carrola, Mia; Zheng, Bingqian; Tan, Loon‐Seng; Asadi, Amir; Crouse, Christopher_A; Koerner, Hilmar (December 2024, Advanced Functional Materials)

   Abstract Polyimides (PIs), known for their thermal resistance, chemical stability, and mechanical properties, are often considered challenging materials to process, resulting in limited commercial availability of PIs for melt extrusion, injection molding, and fused filament fabrication (FFF). Currently, material and knowledge gaps prevent the ability to rapidly produce parts from PIs that can be used in high strength and elevated temperature applications. To address this, a novel, fully aromatic PI with thermotropic liquid crystalline properties (LCPI) is successfully synthesized. The synthesized LCPI exhibits better solvent tolerance and thermal stability than commercially available counterparts. The LC phase is confirmed by thermal analysis, wide angle X‐ray scattering, and polarized optical microscopy. Rheological behavior clearly demonstrates that the LC phase reduces melt viscosity. These properties enable the LCPI to be processed into both drawn fibers and filaments for FFF, which is demonstrated alongside an injection molding process. The properties of the printed parts rivaled those made with Ultem 1000, exhibiting an average elastic modulus of 4.16 GPa. The injection molding process resulted in tensile moduli as high as 8.59 GPa and tensile strengths as high as 124.70 MPa. The LCPI polymer demonstrates the desired properties required for aerospace applications via melt processing techniques. 

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