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   Das, S.; Tang, Y. L.; Hong, Z.; Gonçalves, M. A.; McCarter, M. R.; Klewe, C.; Nguyen, K. X.; Gómez-Ortiz, F.; Shafer, P.; Arenholz, E.; et al (April 2019, Nature)
2. Room-temperature optomechanical squeezing

   https://doi.org/10.1038/s41567-020-0877-x  

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3. University of Rochester room impulse response dataset

   https://doi.org/10.60593/ur.d.26801089.v3  

   Rutowski, Jenna; DiPassio, Tre; Thompson, Benjamin R; Heilemann, Michael C; Bocko, Mark F (October 2024, University of Rochester)

   The dataset includes impulse responses recorded from 14 different rooms. Each room has unique acoustic properties, providing a wide range of RT60, clarity, and EDT values. The recordings are in 48kHz, 32bit, mono WAV files. The dataset is organized by room, with each subfolder containing the impulse responses specific to that room, as well as a general layout of each room and plots of acoustic data.This dataset supports Estimating direction of arrival in reverberant environments for wake-word detection using a single structural vibration sensor, published in the Journal of the Acoustical Society of America, Vol. 156, Iss. 4, October, 2024.If you plan to download this dataset, we would appreciate it very much if you could fill out the Google form at https://forms.gle/jnuP2dYRK3CPmXQG6. This will help us understand the usage and impacts of this dataset. Your feedback will also help us improve any future extensions of this work. 

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4. There Is Plenty of Room All-Around

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5. Room temperature 3D carbon microprinting

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   Torres-Davila, Fernand E.; Chagoya, Katerina L.; Blanco, Emma E.; Shahzad, Saqib; Shultz-Johnson, Lorianne R.; Mogensen, Mirra; Gesquiere, Andre; Jurca, Titel; Rochdi, Nabil; Blair, Richard G.; et al (March 2024, Nature Communications)

   Abstract Manufacturing custom three-dimensional (3D) carbon functional materials is of utmost importance for applications ranging from electronics and energy devices to medicine, and beyond. In lieu of viable eco-friendly synthesis pathways, conventional methods of carbon growth involve energy-intensive processes with inherent limitations of substrate compatibility. The yearning to produce complex structures, with ultra-high aspect ratios, further impedes the quest for eco-friendly and scalable paths toward 3D carbon-based materials patterning. Here, we demonstrate a facile process for carbon 3D printing at room temperature, using low-power visible light and a metal-free catalyst. Within seconds to minutes, this one-step photocatalytic growth yields rod-shaped microstructures with aspect ratios up to ~500 and diameters below 10 μm. The approach enables the rapid patterning of centimeter-size arrays of rods with tunable height and pitch, and of custom complex 3D structures. The patterned structures exhibit appealing luminescence properties and ohmic behavior, with great potential for optoelectronics and sensing applications, including those interfacing with biological systems. 

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