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1. Upper Pulse Energy Limit of Narrowband THz Generation

   https://doi.org/10.1364/CLEO_SI.2023.SF3I.4  

   Green, Natalie K.; Rader, Claire; Nielson, Megan F.; Johnson, Jeremy A. (January 2023, CLEO 2023)

   We generate tunable narrowband THz radiation using BNA bonded to sapphire in tandem with a chirp and delay technique. Using a Ti:Sapphire laser, we test the limits of intense THz generation (0.1 to 5 THz). 

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2. hu.MAP3.0: Atlas of human protein complexes by integration of > 25,000 proteomic experiments

   https://doi.org/10.1101/2024.10.11.617930  

   Fischer, Samantha N; Claussen, Erin R; Kourtis, Savvas; Sdelci, Sara; Orchard, Sandra; Hermjakob, Henning; Kustatscher, Georg; Drew, Kevin (October 2024, bioRxiv)

   Abstract Macromolecular protein complexes carry out most functions in the cell including essential functions required for cell survival. Unfortunately, we lack the subunit composition for all human protein complexes. To address this gap we integrated >25,000 mass spectrometry experiments using a machine learning approach to identify > 15,000 human protein complexes. We show our map of protein complexes is highly accurate and more comprehensive than previous maps, placing ∼75% of human proteins into their physical contexts. We globally characterize our complexes using protein co-variation data (ProteomeHD.2) and identify co-varying complexes suggesting common functional associations. Our map also generates testable functional hypotheses for 472 uncharacterized proteins which we support using AlphaFold modeling. Additionally, we use AlphaFold modeling to identify 511 mutually exclusive protein pairs in hu.MAP3.0 complexes suggesting complexes serve different functional roles depending on their subunit composition. We identify expression as the primary way cells and organisms relieve the conflict of mutually exclusive subunits. Finally, we import our complexes to EMBL-EBI’s Complex Portal (https://www.ebi.ac.uk/complexportal/home) as well as provide complexes through our hu.MAP3.0 web interface (https://humap3.proteincomplexes.org/). We expect our resource to be highly impactful to the broader research community. 

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3. A high‐resolution model of the grapevine leaf morphospace predicts synthetic leaves

   https://doi.org/10.1002/ppp3.10561  

   Chitwood, Daniel_H; Torres‐Lomas, Efrain; Hadi, Ebi_S; Peterson, Wolfgang_L_G; Fischer, Mirjam_F; Rogers, Sydney_E; He, Chuan; Acierno, Michael_G_F; Azumaya, Shintaro; Benjamin, Seth_Wayne; et al (August 2024, PLANTS, PEOPLE, PLANET)

   Societal Impact StatementGrapevine leaves are emblematic of the strong visual associations people make with plants. Leaf shape is immediately recognizable at a glance, and therefore, this is used to distinguish grape varieties. In an era of computationally enabled machine learning‐derived representations of reality, we can revisit how we view and use the shapes and forms that plants display to understand our relationship with them. Using computational approaches combined with time‐honored methods, we can predict theoretical leaves that are possible, enabling us to understand the genetics, development, and environmental responses of plants in new ways. SummaryGrapevine leaves are a model morphometric system. Sampling over 10,000 leaves using dozens of landmarks, the genetic, developmental, and environmental basis of leaf shape has been studied and a morphospace for the genusVitispredicted. Yet, these representations of leaf shape fail to capture the exquisite features of leaves at high resolution.We measure the shapes of 139 grapevine leaves using 1672 pseudo‐landmarks derived from 90 homologous landmarks with Procrustean approaches. From hand traces of the vasculature and blade, we have derived a method to automatically detect landmarks and place pseudo‐landmarks that results in a high‐resolution representation of grapevine leaf shape. Using polynomial models, we create continuous representations of leaf development in 10Vitisspp.We visualize a high‐resolution morphospace in which genetic and developmental sources of leaf shape variance are orthogonal to each other. Using classifiers,Vitis vinifera,Vitisspp., rootstock and dissected leaf varieties as well as developmental stages are accurately predicted. Theoretical eigenleaf representations sampled from across the morphospace that we call synthetic leaves can be classified using models.By predicting a high‐resolution morphospace and delimiting the boundaries of leaf shapes that can plausibly be produced within the genusVitis, we can sample synthetic leaves with realistic qualities. From an ampelographic perspective, larger numbers of leaves sampled at lower resolution can be projected onto this high‐resolution space, or, synthetic leaves can be used to increase the robustness and accuracy of machine learning classifiers. 

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4. Effect of Pt and Ru-based catalysts on the electrochemical hydrodeoxygenation of phenol to cyclohexane

   https://doi.org/10.1039/D4CY00634H  

   Page, Jeffrey R; Pophali, Amol; Kim, Taejin; Lopez-Ruiz, Juan A; Bliznakov, Stoyan; Valla, Julia A (July 2024, Catalysis Science & Technology)

   PtRuC offers the opportunity to electrochemically convert bio-oils to drop-in biofuels and platform chemicals. Here we demonstrate the concept using phenol to cyclohexane as a model reaction. 

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5. Finite elasticity of the vertex model and its role in rigidity of curved cellular tissues

   https://doi.org/10.1039/D3SM00874F  

   Hernandez, Arthur; Staddon, Michael F.; Moshe, Michael; Marchetti, M. Cristina (October 2023, Soft Matter)

   Using a mean field approach and simulations, we study the non-linear mechanical response of the vertex model (VM) of biological tissue to compression and dilation. 

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