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1. Contact Angle Dynamics during the Evaporation of Water from Hydrophilic and Hydrophobic Graphene Surfaces

   Chakraborty, Partha P.; Das, Suprem R.; Derby, Melanie M. (September 2018, http://mnf2018.me.gatech.edu/abstracts.php)

   For this experimental study on evaporation of water from graphene, two graphene samples with different thickness and microstructure were used. Figure 1 shows the representative optical and scanning electron microscope (SEM) images of the two samples. Sample 1, shown in Figure 1a-b, is a 3 to 4 atomic layer of continuous graphene sheet grown on copper substrate via chemical vapor deposition (CVD) and was subsequently transferred to a quartz substrate using a wet chemical method reported previously [5]. The graphene thickness is at 1.2 nm to 1.4 nm, as measured by Atomic Force Microscopy. Sample 2, shown in Figure 1c-d, represents an inkjet-printed reduced graphene oxide on silicon and subsequently treated with a direct pulsed laser writing (DPLW) process for surface 3D-nanostructuring. The layer thickness is between 6 µm and 7 µm. 

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2. Characterization of Three-Section AlGaInAs Multiple Quantum-Well Mode-locked Lasers for Space Applications

   https://doi.org/10.1364/CLEO_AT.2024.ATh3O.5  

   Huang, Di; Colin, Bryant; Arnold, Kellen P; Zhang, Enxia; Weiss, Sharon M; Reed, Robert A; Delfyett, Peter J (January 2024, Optica Publishing Group)

   We report a quantum-well-intermixing-free three-section mode-locked laser diode at 1580nm, featuring 1.70 psec pulse width. The fixed-point frequency analysis shows four different laser parameters conducive for compensating repetition rate and carrier frequency variations in space environment. 

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3. Fabrication of hierarchical sapphire nanostructures using ultrafast laser induced morphology change

   https://doi.org/10.1088/1361-6528/adab7c  

   Cheung, Joshua; Chien, Kun-Chieh; Sokalski, Peter; Shi, Li; Chang, Chih-Hao (January 2025, Nanotechnology)

   Abstract Sapphire is an attractive material that stands to benefit from surface functionalization effects stemming from micro/nanostructures. Here we investigate the use of ultrafast lasers for fabricating sapphire nanostructures by exploring the relationship between irradiation parameters, morphology change, and selective etching. In this approach a femtosecond laser pulse is focused on the substrate to change the crystalline morphology to amorphous or polycrystalline, which is characterized by examining different vibrational modes using Raman spectroscopy. The irradiated regions are removed using a subsequent hydrofluoric acid etch. Laser confocal measurements quantify the degree of selective etching. The results indicate a threshold laser pulse intensity required for selective etching. This process was used to fabricate hierarchical sapphire nanostructures over large areas with enhanced hydrophobicity, with an apparent contact angle of 140 degrees, and a high roll-off angle, characteristic of the rose petal effect. Additionally, the structures have high broadband diffuse transmittance of up to 81.8% with low loss, with applications in optical diffusers. Our findings provide new insights into the interplay between the light-matter interactions, where Raman shifts associated with different vibrational modes can predict selective etching. These results advance sapphire nanostructure fabrication, with applications in infrared optics, protective windows, and consumer electronics. 

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4. Rigorous prediction of Raman intensity from multi-layer films

   https://doi.org/10.1364/OE.403705  

   Velson, Nathan_Van; Zobeiri, Hamidreza; Wang, Xinwei (November 2020, Optics Express)

   In the Raman probing of multilayer thin film materials, the intensity of the measured Raman scattered light will be impacted by the thickness of the thin film layers. The Raman signal intensity will vary non-monotonically with thickness due to interference from the multiple reflections of both the incident laser light and the Raman scattered light of thin film interfaces. Here, a method for calculating the Raman signal intensity from a multilayer thin film system based on the transfer matrix method with a rigorous treatment of the Raman signal generation (discontinuity) is presented. This calculation methodology is valid for any thin film stack with an arbitrary number of layers with arbitrary thicknesses. This approach is applied to several thin film material systems, including silicon-on-sapphire thin films, graphene on Si with a SiO₂capping layer, and multilayer MoS₂with the presence of a gap between layers and substrate. Different applications where this method can be used in the Raman probing of thin film material properties are discussed. 

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5. IMPROVED PERFORMANCE OF PASSIVE LAYER-FREE CURVED PMUT ARRAY

   Huang, Chichen; Khandare, Shubham; Kothapalli, Sri-Rajasekhar; Tadigadapa, Srinivas (June 2024, Proceeding of the Solid Sensors, Actuators and Microsystems Workshop 2024, Hilton Head)

   Chan, Jenna F; Rajaraman, Swaminathan (Ed.)

   We have successfully demonstrated a novel, passive layer-free, curved piezoelectric micromachined ultrasound transducer (PMUT) array, using a sacrificial curved glass template and 30% scandium-doped aluminum nitride (Sc-AlN) as the active layer. The PMUTs were fabricated using a curved, suspended borosilicate glass template created via a chip-scale glass-blowing technique, onto which electrodes and the piezoelectric layer were deposited. The glass layer was thereafter selectively removed. We characterized the performance of a 13 × 13 curved PMUT (cPMUT) array using an electrical impedance analyzer, a Laser Doppler Vibrometer (LDV), and hydrophone pressure measurements. Our results reveal a device resonance frequency of approximately 1.8 MHz in air, with LDV analysis indicating a significantly enhanced low-frequency response of 1.68 nm/V—a fivefold improvement over conventional curved PMUTs with a passive layer. Additionally, acoustic characterization in water showed that this array generates an acoustic pressure of approximately 80 kPa at a 4.4 mm focal distance, with a beam width of 5 mm, and achieves a spatial peak pulse average intensity (ISPPA) of 216 mW/cm2 when driven off-resonance. Furthermore, we demonstrate 20-degree steering capability using our data acquisition system. These advancements highlight significant potential for enhancing the precision and efficacy of medical imaging and therapeutic applications, particularly in ultrasonic diagnostics and treatments. 

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