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1. Retaining high fracture toughness in aged polymer Composite/Adhesive joints through optimization of plasma surface treatment

   https://doi.org/10.1016/j.compositesa.2023.107835  

   Aliheidari, Nahal; Ameli, Amir (January 2024, Composites Part A: Applied Science and Manufacturing)

   A response surface methodology was used to analyze the flow rate, power, and time factors of plasma surface treatment. Surface free energy (SFE) of treated glass fiber-reinforced composites showed a strong quadratic dependence on flow rate, power, and time, with significant interaction between time and power. Optimized factors predicted a maximum SFE of 78.63 mN/m, which matched well with the measured value of 77.42 mN/m, accounting for 2.46 times increase in SFE against untreated case. Moreover, with plasma treatment, the SFE’s polar component became dominant (99%) as also confirmed with FTIR spectroscopy. Fracture toughness testing of fresh and aged adhesive joints proved a more stable interface for plasma-treated specimens due to the covalent bonds facilitated by the functional groups formed during the treatment. Consequently, the fracture toughness of the plasma-treated specimens did not drop after seawater immersion, while that for the untreated and sand-treated specimens showed about a 15% drop. 

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2. High-Performance Nanoplasmonic Enhanced Indium Oxide—UV Photodetectors

   https://doi.org/10.3390/cryst13040689  

   Li, Eric Y.; Zhou, Andrew F.; Feng, Peter X. (April 2023, Crystals)

   In this paper, high-performance UV photodetectors have been demonstrated based on indium oxide (In2O3) thin films of approximately 1.5–2 μm thick, synthesized by a simple and quick plasma sputtering deposition approach. After the deposition, the thin-film surface was treated with 4–5 nm-sized platinum (Pt) nanoparticles. Then, titanium metal electrodes were deposited onto the sample surface to form a metal–semiconductor–metal (MSM) photodetector of 50 mm2 in size. Raman scattering spectroscopy and scanning electron microscope (SEM) were used to study the crystal structure of the synthesized In2O3 film. The nanoplasmonic enhanced In2O3-based UV photodetectors were characterized by various UV wavelengths at different radiation intensities and temperatures. A high responsivity of up to 18 A/W was obtained at 300 nm wavelength when operating at 180 °C. In addition, the fabricated prototypes show a thermally stable baseline and excellent repeatability to a wide range of UV lights with low illumination intensity when operating at such a high temperature. 

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3. Effect of oxygen and fluorine plasma surface treatment of silicon‐incorporated diamond‐like carbon coatings on cellular responses of mouse fibroblasts

   https://doi.org/10.1111/ijac.14107  

   Riley, Parand_R; Yang, Kai‐Hung; Liu, Yizhong; Skoog, Shelby_A; Narayan, Jagdish; Narayan, Roger_J (June 2022, International Journal of Applied Ceramic Technology)

   Abstract The surface chemistry of silicon‐incorporated diamond‐like carbon (Si‐DLC) was tailored utilizing oxygen and fluorine plasma treatments. Successful anchoring of oxygen and fluorine functional groups to the surface of Si‐DLC was verified using X‐ray photoelectron spectroscopy. The impact of surface modification of Si‐DLC on hydrophobicity was correlated with the viability of L929 mouse fibroblasts. The confocal microscopy and viability results indicated that oxygen‐treated Si‐DLC showed increased cell viability compared to untreated Si‐DLC and fluorine‐treated Si‐DLC samples 5 days after seeding. The increased cell viability was correlated with the conversion of the hydrophobic surface of Si‐DLC into a hydrophilic surface by oxygen plasma treatment. 

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4. Optimizing noncontact oxygen‐plasma treatment to improve the performance of a top‐down nanofabricated surface enhanced Raman spectroscopy substrate with structurally responsive, high‐aspect‐ratio nanopillar array

   https://doi.org/10.1002/jrs.6050  

   Chevalier, Robert_B; Dwyer, Jason_R (December 2020, Journal of Raman Spectroscopy)

   Abstract Our use of a commercially available monolithic surface enhanced Raman spectroscopy substrate based on metallized arrays of nanopillars has been hindered by the structured and variable background spectrum found in as‐supplied substrates. We identify surface contamination—at minimum from the shipping container—as the root cause of the variability and observed that our cleaning protocol could enhance the spectral performance but could also significantly degrade it in some cases. These uniquely nanostructured substrates offer on‐demand hot spot formation by solvent‐evaporation‐induced nanopillar leaning, so that oxygen‐plasma treatment was used as a noncontact method to preserve this capability. Suitable plasma cleaning conditions produced less structured background spectra and yielded higher signal intensities. Detrimental plasma power and exposure durations could yield significantly cleaner background spectra but at the significant cost of response to analyte. Scanning electron micrographs showed the plasma could alter the surface morphology. Optimization of oxygen‐plasma settings must therefore balance favorable effects such as contaminant removal, improved substrate wetting, and signal enhancement with deleterious effects such as structural damage to the substrate. 

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5. A reaction mechanism for plasma electrolysis of AgNO ₃ forming silver nanoclusters and nanoparticles

   https://doi.org/10.1063/5.0127568  

   Raisanen, Astrid L.; Mueller, Chelsea M.; Chaudhuri, Subhajyoti; Schatz, George C.; Kushner, Mark J. (November 2022, Journal of Applied Physics)

   In plasma-driven solution electrolysis (PDSE), gas-phase plasma-produced species interact with an electrolytic solution to produce, for example, nanoparticles. An atmospheric pressure plasma jet (APPJ) directed onto a liquid solution containing a metallic salt will promote reduction of metallic ions in solution, generating metallic clusters that nucleate to form nanoparticles. In this article, results from a computational investigation are discussed of a PDSE process in which a radio-frequency APPJ sustained in helium impinges on a silver nitrate solution, resulting in growth of silver nanoparticles. A reaction mechanism was developed and implemented in a global plasma chemistry model to predict nanoparticle growth. To develop the reaction mechanism, density functional theory was used to generate probable silver growth pathways up to Ag 9 . Neutral clusters larger than Ag 9 were classified as nanoparticles. Kinetic reaction rate coefficients for thermodynamically favorable growth pathways were estimated based on an existing, empirically determined base reaction mechanism for smaller Ag particle interactions. These rates were used in conjunction with diffusion-controlled reaction rate coefficients that were calculated for other Ag species. The role of anions in reduction of Ag n ions in forming nanoparticles is also discussed. Oxygen containing impurities or admixtures to the helium, air entrainment into the APPJ, and dissociation of saturated water vapor above the solution can produce additional reactive oxygen species in solution, resulting in the production of anions and [Formula: see text] in particular. For a given molarity, delivering a sufficient fluence of reducing species will produce similar nanoparticle densities and sizes for all applied power levels. Comparisons are made to alternate models for nanoparticle formation, including charged nanoparticles and use of direct current plasmas. 

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