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1. Light-driven C–H activation mediated by 2D transition metal dichalcogenides

   Li, Jingang; Zhang, Di; Guo, Zhongyuan; Chen, Zhihan; Jiang, Xi; Larson, Jonathan M; Zhu, Haoyue; Zhang, Tianyi; Gu, Yuqian; Blankenship, Brian W; et al (July 2024, Nature communications)

   C–H bond activation enables the facile synthesis of new chemicals. While C–H activation in short-chain alkanes has been widely investigated, it remains largely unexplored for long-chain organic molecules. Here, we report light-driven C–H activation in complex organic materials mediated by 2D transition metal dichalcogenides (TMDCs) and the resultant solid-state synthesis of luminescent carbon dots in a spatially-resolved fashion. We unravel the efficient H adsorption and a lowered energy barrier of C–C coupling mediated by 2D TMDCs to promote C–H activation and carbon dots synthesis. Our results shed light on 2D materials for C–H activation in organic compounds for applications in organic chemistry, environmental remediation, and photonic materials. 

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2. Light-driven C–H activation mediated by 2D transition metal dichalcogenides

   Li, Jingang; Zhang, Di; Guo, Zhongyuan; Chen, Zhihan; Jiang, Xi; Larson, Jonathan M; Zhu, Haoyue; Zhang, Tianyi; Gu, Yuqian; Blankenship, Brian W; et al (July 2024, Nature communications)

   C–H bond activation enables the facile synthesis of new chemicals. While C–H activation in short-chain alkanes has been widely investigated, it remains largely unexplored for long-chain organic molecules. Here, we report light-driven C–H activation in complex organic materials mediated by 2D transition metal dichalcogenides (TMDCs) and the resultant solid-state synthesis of luminescent carbon dots in a spatially-resolved fashion. We unravel the efficient H adsorption and a lowered energy barrier of C–C coupling mediated by 2D TMDCs to promote C–H activation and carbon dots synthesis. Our results shed light on 2D materials for C–H activation in organic compounds for applications in organic chemistry, environmental remediation, and photonic materials. 

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3. Quantum photonics and lightwave electronics

   https://doi.org/10.1088/2053-1583/ae2b82  

   Ren, Wencai; Boggild, Peter; Redwing, Joan M; Novoselov, Konstantin S; Sun, Luzhao; Qi, Yue; Jia, Kaicheng; Liu, Zhongfan; Burton, Oliver; Alexander-Webber, Jack Allen; et al (December 2025, 2D Materials)

   NA (Ed.)

   Abstract The advent of 2D materials has revolutionized condensed matter physics and materials science, offering unprecedented opportunities to explore exotic physical phenomena, engineer novel functionalities, and address critical technological challenges across diverse fields. Over the past two decades, the exploration of 2D materials has expanded beyond graphene, encompassing a vast library of atomically thin crystals and their heterostructures. These materials exhibit extraordinary electronic, optical, thermal, mechanical, and chemical properties, and hold promise for breakthroughs in electronics, optoelectronics, quantum technologies, energy storage, catalysis, thermal management, filtration and separation, and beyond. Many exciting new physics and phenomena continue to emerge, while select 2D materials, such as graphene, h-BN, and the semiconducting transition metal dichalcogenides (TMDCs), are transitioning from laboratory-scale demonstrations to industrial applications. In this context, a holistic understanding of synthesis, structure-property relationships, integration, and performance optimization is essential. This roadmap reviews the multifaceted challenges and opportunities in 2D materials research, focusing on the synthesis, properties and applications of representative systems including graphene and its derivatives, TMDCs, MXenes as well as their heterostructures and moiré systems. 

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4. Mechanistic Exploration of Visible Light-Activated Carbon/TiO2 Hybrid Dots Damaging Bacterial Cells

   https://doi.org/10.3390/app12199633  

   Adcock, Audrey F.; Liang, Weixiong; Okonjo, Peter A.; Dong, Xiuli; Sheriff, Kirkland; Wang, Ping; Ferguson, Isaiah S.; Hwu, Shiou-Jyh; Sun, Ya-Ping; Yang, Liju (October 2022, Applied Sciences)

   The carbon/TiO2 hybrid dots (C/TiO2-Dots) are structurally TiO2 nanoparticles (in the order of 25 nm in diameter from commercially available colloidal TiO2 samples) surface-attached by nanoscale carbon domains with organic moieties, thus equivalent to hybrids of individual TiO2 nanoparticles each decorated with many carbon dots. These hybrid dots with exposure to visible light exhibit potent antibacterial properties, similar to those found in neat carbon dots with the same light activation. The results from the use of established scavengers for reactive oxygen species (ROS) to “quench” the antibacterial activities, an indication for shared mechanistic origins, are also similar. The findings in experiments on probing biological consequences of the antibacterial action suggest that the visible light-activated C/TiO2-Dots cause significant damage to the bacterial cell membrane, resulting in higher permeability, with the associated oxidative stress leading to lipid peroxidation, inhibiting bacterial growth. The induced bacterial cell damage could be observed more directly in the transmission electron microscopy (TEM) imaging. Opportunities for the further development of the hybrid dots platform for a variety of antibacterial applications are discussed. 

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5. An Organometallic Umpolung Approach for Iron‐Mediated Propargylic C−H Etherification

   https://doi.org/10.1002/anie.202413017  

   Xia, Yue; Zhu, Jin; Durham, Austin C; Wang, Yi‐Ming (December 2024, Angewandte Chemie International Edition)

   Abstract Propargylic ethers serve as useful intermediates for the synthesis of a variety of complex targets. However, propargylic substitution of prefunctionalized alkyne starting materials remains the dominant method for the synthesis of propargyl ethers, while direct etherification of simple alkynes via propargylic C−H functionalization remains largely underreported. Herein, we report an organometallic umpolung approach for iron‐mediated C−H propargylic etherification. A telescopic protocol for iron‐mediated C−H deprotonation followed by mild oxidative coupling with alcohols enabled the use of simple or functionalized alkynes for the expedient synthesis of propargylic ethers with excellent functional group compatibility, chemoselectivity and regioselectivity. 

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