Binary Solvent Regulated Architecture of Ultra-Microporous Hydrogen-Bonded Organic Frameworks with Tunable Polarization for Highly-Selective Gas Separation

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rel="alternate" hreflang="en" href="https://www.peeref.com/works/23283692" > <span>English</span> </a> <a rel="alternate" hreflang="zh" href="https://www.peeref.com/zh/works/23283692" > <span>中文</span> </a> </div> </li> </ul> </ul> </div> </nav> <main> <div id="top-info-banner" class="container-fluid mb-0"> <div class="container"> <div class="d-flex align-items-center" style="margin-top: 30px;"> <span class="text-white"> <strong class="f18">☆</strong> <span class="f16">4.8</span> </span> <span class="mx-3"></span> <span class="tag">Article</span> </div> <h1 class="title title-for-article"> Binary Solvent Regulated Architecture of Ultra-Microporous Hydrogen-Bonded Organic Frameworks with Tunable Polarization for Highly-Selective Gas Separation </h1> <div class="help-links-left"> <p class="pub-info"> ANGEWANDTE CHEMIE-INTERNATIONAL EDITION (2022) </p> </div> </div> </div> <div id="article-sticky-navbar"> <div class="container"> <div class="d-flex justify-content-between flex-wrap 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href="https://www.peeref.com/zh/journals/534/angewandte-chemie-international-edition"> ANGEWANDTE CHEMIE-INTERNATIONAL EDITION </a> </h5> <span> 卷 61, 期 13, 页码 - </span> </div> </div> <div class="mb-3 pb-3"> <h4 class="mt-0">出版社</h4> <div class="f16"> <h5 class="title f16 text-primary"> WILEY-V C H VERLAG GMBH </h5> <div class="my-2"> DOI: 10.1002/anie.202116483 </div> </div> </div> <div class="mb-3 pb-3"> <h4 class="mt-0">关键词</h4> <div class="f16"> CO2 Separation; Hydrogen-Bonded Organic Frameworks; Polarization; Selectivity; Ultra-micropores </div> </div> <div class="mb-3 pb-3"> <h4 class="mt-0">类别</h4> <div class="f16"> <span class="d-block"> <a href="https://www.peeref.com/zh/works/list?category=Chemistry%2C+Multidisciplinary" target="_blank" class="text-dark btn btn-link p-0 text-left"> Chemistry, Multidisciplinary </a> </span> </div> </div> <div class="mb-3 pb-3"> <h4 class="mt-0">资金</h4> <div class="f16"> <ol class=""> <li>National Natural Science Foundation of China [21922604]</li> </ol> </div> </div> </div> <div class="f15 panel-box rounded shadow-none border"> <h4 class="mt-0 text-center">向作者/读者索取更多资源</h4> <div class="requests"> <div class="requests-item"> <div class="icon"> <img src="https://peeref-open.s3.amazonaws.com/images/file.png" alt=""> </div> <h4>Protocol</h4> <p> <a href="https://www.peeref.com/zh/works/23283692/resource" class="btn btn-outline-primary btn-sm"> 社区支持 </a> </p> </div> <div class="requests-item"> <div class="icon"> <img src="https://peeref-open.s3.amazonaws.com/images/experiment.png" alt=""> </div> <h4>Reagent</h4> <p> <a href="https://www.peeref.com/zh/works/23283692/resource" class="btn btn-outline-primary btn-sm"> 社区支持 </a> </p> </div> </div> </div> </div> <div class="col-md-8 px-0 pl-md-3"> <div id="article-summary-panel" class="mb-4"> <ul class="nav nav-tabs" style="list-style: none; padding-left: 0;"> <li class="active"> <a href="#ai_summary" data-toggle="tab" class="summary-tab mx-0 f16 text-dark"> <strong>智能总结</strong> <strong class="text-danger ml-1"><i>New</i></strong> </a> </li> <li class=""> <a href="#raw_abstract" data-toggle="tab" class="abstract-tab mx-0 f16 text-dark"> <strong>摘要</strong> </a> </li> </ul> <div class="tab-content border border-top-0"> <div id="ai_summary" class="tab-pane active"> <div class="summary-panel panel-box mb-0 rounded shadow-none"> <div class="f16">A binary solvent synthetic strategy is proposed to construct molecule-based hydrogen-bonded organic frameworks (HOFs) with permanent ultra-micropores and surface polarization. The activated HOFs showed highly selective separation of CO2/N-2 under ambient temperature and pressure, making them potentially useful for gas separation applications.</div> </div> </div> <div id="raw_abstract" class="tab-pane "> <div class="abstract-panel panel-box mb-0 rounded shadow-none"> <div class="f16">A binary solvent synthetic strategy is proposed for the construction of C-2-symmetric molecule-based hydrogen-bonded organic frameworks (HOFs) with permanent ultra-micropores and surface polarization derived from tunable coplanar open oxygen atoms. The activated HOFs BTBA-1 a and PTBA-1 a show highly selective separation of CO2/N-2 with a record high ideal adsorbed solution theory (IAST) selectivity >2000 under ambient temperature and pressure.</div> </div> </div> </div> </div> <div class="f15 panel-box rounded shadow-none border"> <h4 class="mt-0 heading-count">作者</h4> <div class="mb-3"> <article-authors tid="23283692" list="[{"name":"Xiaojun Ding","sequence":1},{"name":"Zeyu Liu","sequence":2},{"name":"Yusheng Zhang","sequence":3},{"name":"Gang Ye","sequence":4},{"name":"Jianfeng Jia","sequence":5},{"name":"Jing Chen","sequence":6}]" verified="[]" page="work" ></article-authors> </div> <div class="alert alert-warning mb-0"> <h5 class="mt-0 bg-warning text-dark px-3 rounded d-inline-block"> 我是这篇论文的作者 </h5> <div class="font-weight-bold f13"> 点击您的名字以认领此论文并将其添加到您的个人资料中。 </div> </div> </div> <div class="f15 panel-box rounded shadow-none border"> <h4 class="mt-0 heading-count">评论</h4> <div class="d-flex flex-wrap flex-md-nowrap"> <div class="flex-grow-1"> <h4 class="f16"> 主要评分 <a href="javascript:;" data-toggle="tooltip" data-placement="right" title="主要评分表示论文的整体质量水平。"> <i class="ivu-icon ivu-icon-md-help-circle f18 ml-2"></i> </a> </h4> <div class="d-flex flex-wrap flex-md-nowrap align-items-center alert mb-0"> <div class="d-flex align-items-center justify-content-center"> <Rate disabled allow-half value="4.8" style="font-size: 28px;"></Rate> <strong class="f20 m-3" style="color: #f5a623;">4.8</strong> </div> <div class="text-muted mx-4"> 评分不足 </div> </div> <h4 class="f16"> 次要评分 <a href="javascript:;" data-toggle="tooltip" data-placement="right" title="次要评分独立反映论文的优点或缺点。"> <i class="ivu-icon ivu-icon-md-help-circle f18 ml-2"></i> </a> </h4> <div class="d-flex flex-wrap flex-md-nowrap alert"> <div class="d-flex flex-shrink-0 align-items-center mr-3"> <h5 class="my-0">新颖性</h5> <strong class="mx-4">-</strong> </div> <div class="d-flex flex-shrink-0 align-items-center mr-3"> <h5 class="my-0">重要性</h5> <strong class="mx-4">-</strong> </div> <div class="d-flex flex-shrink-0 align-items-center mr-3"> <h5 class="my-0">科学严谨性</h5> <strong class="mx-4">-</strong> </div> </div> </div> <div class="flex-shrink-0"> <div class="border bg-light py-2 px-4"> <h5 class="mb-1">评价这篇论文</h5> <Rate class="f24" @on-change="function(value){ location.href='https://www.peeref.com/zh/works/23283692/comments?rating='+value }"></Rate> </div> </div> </div> </div> <div id="collection" class="f15 panel-box rounded shadow-none border"> <h4 class="mt-0 heading-count">推荐</h4> <div class="my-3"> <ul class="nav nav-pills border-bottom pb-3" style="list-style: none; padding-left: 0;"> <li class="active"> <a href="#articles_from_related" data-toggle="tab" class="mx-0 f15"> <strong>相关</strong> </a> </li> <li class=""> <a href="#articles_from_authors" data-toggle="tab" class="mx-0 f15"> <strong>来自同一作者</strong> </a> </li> <li class=""> <a href="#articles_from_journal" data-toggle="tab" class="mx-0 f15"> <strong>来自同一期刊</strong> </a> </li> </ul> <div class="tab-content"> <div id="articles_from_related" class="tab-pane active"> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84196639" class="text-dark hover-underline">A Grafting Hydrogen-bonded Organic Framework for Benchmark Selectivity of C2H2/CO2 Separation under Ambient Conditions</a> </h4> <p class="text-ellipsis-2">Furong Yuan, Yunbin Li, Zhen Yuan, Lu Li, Chenxin Chen, Lei He, Hongyu Lin, Xi Fan, Banglin Chen, Shengchang Xiang, Zhangjing Zhang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study synthesized two isomorphic HOFs, HOF-FJU-99 and HOF-FJU-100, with different pore environments through a grafting approach. HOF-FJU-100 has a microporous structure, showing excellent stability and ultrahigh selectivity for C2H2/CO2 mixtures, with a selectivity value of 201, which is the benchmark of all previously reported HOFs. Single crystal X-ray diffraction analysis shows that there are multiple hydrogen bonding interactions between C2H2 molecules and the framework, and in situ gas-carrier powder X-ray diffraction analysis emphasizes the adaptability of the pore structure, which dynamically adjusts its orientation in response to C2H2, thereby achieving efficient and specific separation. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84196639/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84277534" class="text-dark hover-underline">Precisely Constructing Molecular Junctions in Hydrogen-Bonded Organic Frameworks for Efficient Artificial Photosynthetic CO2 Reduction</a> </h4> <p class="text-ellipsis-2">Yaqin Zhang, Ping Li, Peng Cui, Xunliang Hu, Chang Shu, Ruixue Sun, Mengjie Peng, Bien Tan, Xiaoyan Wang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A molecular junction-type porphyrin-based crystalline photocatalyst (Ni-TCPP-TPyP) was successfully fabricated via self-assembly. It achieved efficient conversion of CO2 to CO without using sacrificial agents, with a production rate higher than that of single-component photocatalysts and most organic photocatalysts. The study also revealed the promoting effect of molecular junction formation on photogenerated charge separation and transport, providing new insights for the design of efficient artificial photocatalysts. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84277534/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/25770731" class="text-dark hover-underline">Hierarchical Assembly of a Micro- and Macroporous Hydrogen-Bonded Organic Framework with Tailored Single-Crystal Size</a> </h4> <p class="text-ellipsis-2">Christopher A. Halliwell, Sandra E. Dann, Jesus Ferrando-Soria, Felix Plasser, Keith Yendall, Enrique Ramos-Fernandez, Mark R. J. Elsegood, Antonio Fernandez, Goran T. Vladisavljevie</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> In this study, a hydrogen-bonded organic framework with hierarchical porosity was reported, and the crystal size could be controlled in a single step. The hierarchical porosity was used for the co-recognition of molecular species and microparticles. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/25770731/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Review </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Inorganic & Nuclear </span> </div> <h4> <a href="https://www.peeref.com/zh/works/81690211" class="text-dark hover-underline">Hydrogen-bonded organic framework: Construction and gas separation application</a> </h4> <p class="text-ellipsis-2">Meng Zhao, Lanlan Sun, Yun Yang, Xue-Song Gu, Chang-Jiang-Sheng Lai</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/2055.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This review focuses on the research progress of hydrogen-bonded organic frameworks (HOFs) in gas adsorption and membrane separation. HOFs are a class of crystalline porous materials synthesized through intermolecular hydrogen bonding interactions, with solution processibility and customizable microstructure, showing great potential in low-carbon and energy-efficient separation technologies. The article discusses the relationship between the microstructure of HOFs and their separation efficiency, and systematically summarizes the construction strategies, structural characteristics, and physical property parameters of HOFs. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">COORDINATION CHEMISTRY REVIEWS</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/81690211/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/25243219" class="text-dark hover-underline">An Ultramicroporous Hydrogen-Bonded Organic Framework Exhibiting High C2H2/CO2 Separation</a> </h4> <p class="text-ellipsis-2">Yisi Yang, Hao Zhang, Zhen Yuan, Jia-Qi Wang, Fahui Xiang, Liangji Chen, Fangfang Wei, Shengchang Xiang, Banglin Chen, Zhangjing Zhang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> In this study, an ultramicroporous hydrogen-bonded organic framework material was developed for efficient separation of C2H2 from CO2, showing strong affinity and high selectivity. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/25243219/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83209604" class="text-dark hover-underline">Assembly-Dissociation-Reconstruction Synthesis of Covalent Organic Framework Membranes with High Continuity for Efficient CO2 Separation</a> </h4> <p class="text-ellipsis-2">Hao Zhang, Tianci Shao, Zeliang Cheng, Junchao Dong, Ziyang Wang, Haicheng Jiang, Xu Zhao, Terence Xiaoteng Liu, Guangshan Zhu, Xiaoqin Zou</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study presents a unique approach, assembly-dissociation-reconstruction, for fabricating COF membranes for CO2/N-2 separation. The COF nanosheets can be orderly reconstructed into a crack-free membrane with high crystallinity, open pores, and strong affinity for CO2 adsorption, resulting in efficient CO2 separation. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83209604/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/23282923" class="text-dark hover-underline">Metallization-Prompted Robust Porphyrin-Based Hydrogen-Bonded Organic Frameworks for Photocatalytic CO2 Reduction</a> </h4> <p class="text-ellipsis-2">Qi Yin, Eugeny Alexandrov, Duan-Hui Si, Qian-Qian Huang, Zhi-Bin Fang, Yuan Zhang, An-An Zhang, Wei-Kang Qin, Yu-Lin Li, Tian-Fu Liu, Davide M. Proserpio</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study successfully prepared a series of metalloporphyrinic hydrogen-bonded organic frameworks (HOFs) with high surface area and excellent stability by introducing a transition metal which caused noticeable changes on noncovalent interaction, orbital overlap, and molecular geometry. These metalloporphyrinic HOFs were then used as photocatalysts for the photoreduction of CO2 to CO. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/23282923/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Materials Science, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/81832882" class="text-dark hover-underline">Partitioning of pore space in hydrogen-bonded organic frameworks for enhanced CO2 photoreduction</a> </h4> <p class="text-ellipsis-2">Zi-Xiang Wang, Ying Zou, Zhi-Bin Fang, Jin-Lin Li, Yafeng Li, An-An Zhang, Tian-Fu Liu</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/10207.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study designs a stable and efficient photocatalyst based on HOFs for CO2 photoreduction in pure water. By introducing 1,3,6,8-tetra(4-carboxyphenyl)pyrene (H(4)TBAPy) molecules, the structural stability and electron transport efficiency of HOF are improved, thereby enhancing the catalytic activity. This work provides a new idea for designing high-performance HOF photocatalysts. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">SCIENCE CHINA-MATERIALS</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/81832882/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Engineering, Chemical </span> </div> <h4> <a href="https://www.peeref.com/zh/works/81649056" class="text-dark hover-underline">Reticular syntheses of hydrogen-bonded organic frameworks based on pyrazole tetramers with tunable electrostatic potential for enhanced C2H2/ CO2 separation</a> </h4> <p class="text-ellipsis-2">Jiali Huang, Hang Chen, Yunbin Li, Hao Zhang, Cong Xu, Shengchang Xiang, Banglin Chen, Zhangjing Zhang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/7478.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study realizes the reticular synthesis of three isostructural HOFs with tunable pore environments by using hydrogen bond tetramers to connect pyrazole monomers, and explores their separation performance for C2H2/CO2 mixtures. Among them, HOF-FJU-47a shows better separation performance, and the electrostatic potential of its pore surface is complementary to C2H2. Dynamic breakthrough experiments confirm that HOF-FJU-47a can achieve excellent C2H2/CO2 separation performance. Theoretical calculations further reveal the multiple host-guest interactions between C2H2 and the framework of HOF-FJU-47a. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">SEPARATION AND PURIFICATION TECHNOLOGY</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/81649056/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/28201617" class="text-dark hover-underline">Multivariate Hydrogen-Bonded Organic Frameworks with Tunable Permanent Porosities for Capture of a Mustard Gas Simulant</a> </h4> <p class="text-ellipsis-2">Xiang Yu Gao, Yao Wang, Enyu Wu, Chen Wang, Bin Li, Yaming Zhou, Banglin Chen, Peng Li</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A series of isoreticular multivariate hydrogen-bonded organic frameworks (MTV-HOFs) were successfully synthesized, which exhibited tunable hydrophobicity and the ability to capture a mustard gas simulant. This work is an important advance in the development of porous molecular materials for various applications. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/28201617/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Biochemistry & Molecular Biology </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82630607" class="text-dark hover-underline">Three-Dimensional Hydrogen-Bonded Porous Metal-Organic Framework for Natural Gas Separation with High Selectivity</a> </h4> <p class="text-ellipsis-2">Wenyan Dan, Guangfeng Wei, Xiangdong Fang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/5991.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A 3D hydrogen-bonded MOF, TJU-Dan-5, was synthesized by solvothermal reaction. It shows moderate hydrogen uptake and high selectivity for C2H6 adsorption. Molecular model calculation reveals the interaction between C2H6 and the pore walls. This work provides a strategy for constructing 3D hydrogen-bonded MOFs with potential in natural gas purification. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">MOLECULES</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82630607/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/28178054" class="text-dark hover-underline">Boosting Photocatalytic Hydrogen Evolution Through Local Charge Polarization in Chemically Bonded Single-Molecule Junctions Between Ketone Molecules and Covalent Organic Frameworks</a> </h4> <p class="text-ellipsis-2">Kaihui Huang, Junxian Bai, Rongchen Shen, Xiuzhi Li, Chaochao Qin, Peng Zhang, Xin Li</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/208.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Through molecular engineering, the incorporation of polar ketone molecules induces local charge polarization within the two-dimensional Substoichiometric COFs, significantly improving the performance of photocatalytic hydrogen evolution. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ADVANCED FUNCTIONAL MATERIALS</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/28178054/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/33632122" class="text-dark hover-underline">Preferential CO2 adsorption by an ultra-microporous zinc-aminotriazolato-acetate MOF</a> </h4> <p class="text-ellipsis-2">Piyush Singh, Himan Dev Singh, Abhijith Hari Menon, Ramanathan Vaidhyanathan</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/1634.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Ultramicroporous MOFs allow for the close packing of functional groups, directly influencing the interactions between guests and the framework. MOFs with pores lined by both methyl and amine groups have potential as highly efficient sorbents for humid CO2. However, the complexity of their structure hinders their full utilization, even in a simple zinc-triazolato-acetate layered-pillared MOF. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">CHEMICAL COMMUNICATIONS</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/33632122/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/25770928" class="text-dark hover-underline">Hydrogen-Bonded Organic Framework Ultrathin Nanosheets for Efficient Visible-Light Photocatalytic CO2 Reduction</a> </h4> <p class="text-ellipsis-2">Baoqiu Yu, Ting Meng, Xu Ding, Xiaolin Liu, Hailong Wang, Baotong Chen, Tianyu Zheng, Wen Li, Qingdao Zeng, Jianzhuang Jiang</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/534.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Post-modification and sonication method were used to prepare ultrathin HOF-25-Ni organic framework nanosheets with a thickness of 4.4 nm. Experimental data confirmed the successful immobilization of Ni atoms on the crystalline framework. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/25770928/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 "> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Engineering, Chemical </span> </div> <h4> <a href="https://www.peeref.com/zh/works/28510563" class="text-dark hover-underline">Carbon molecular sieve membranes derived from hydrogen-bonded organic frameworks for CO2/CH4 separation</a> </h4> <p class="text-ellipsis-2">Shuo Liu, Zixi Kang, Lili Fan, Xuting Li, Bingchen Zhang, Yang Feng, Hongyan Liu, Weidong Fan, Rongming Wang, Daofeng Sun</p> <div class="d-flex mb-3"> <div class="flex-shrink-0 d-none d-sm-block"> <img src="https://peeref-open.s3.amazonaws.com/storage/images/covers/4816.jpg" alt="" class="border mr-3" width="100"> </div> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A new type of CMS membrane derived from a crystalline porous hydrogen-bonded organic framework membrane (HCMS) was reported for the first time. By controlling the pyrolysis temperature, the CO2/CH4 separation performance of the HCMS membrane was optimized, showing remarkable selectivity and excellent separation stability. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">JOURNAL OF MEMBRANE SCIENCE</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/28510563/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> </div> <div id="articles_from_authors" class="tab-pane "> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Multidisciplinary Sciences </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82171334" class="text-dark hover-underline">Supramolecular polynuclear clusters sustained cubic hydrogen bonded frameworks with octahedral cages for reversible photochromism</a> </h4> <p class="text-ellipsis-2">Xiaojun Ding, Jing Chen, Gang Ye</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This work constructs supramolecular porous crystalline frameworks with tailor-made architectures from advanced secondary building units and expands the framework topology of HOFs by shaping SSBUs. The framework contains octahedral cages that can encapsulate halogens and achieve fast, broadband photochromic effects. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">NATURE COMMUNICATIONS</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82171334/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Rheumatology </span> </div> <h4> <a href="https://www.peeref.com/zh/works/27255864" class="text-dark hover-underline">Plasma proteomic profiling reveals KRT19 could be a potential biomarker in patients with anti-MDA5+dermatomyositis</a> </h4> <p class="text-ellipsis-2">Panpan Zhang, Mengdi Li, Yuqi Zhang, Chaofeng Lian, Jinlei Sun, Yujie He, Wenlu Hu, Limei Wang, Tianfang Li, Shengyun Liu, Yusheng Zhang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study aimed to investigate the immune response-related protein profiling in the plasma of patients with idiopathic inflammatory myopathies (IIMs), especially anti-MDA5+ dermatomyositis (DM). Through Olink proteomics, 46 differentially expressed proteins were detected in IIM patients, including 12 upregulated and 34 downregulated proteins. The immune response-related protein profiling significantly altered in anti-MDA5+ DM patients, with increased levels of LAMP3, HSD11B1, and KRT19, and decreased levels of SH2D1A, ITGA11, TRIM21, CD28, ITGB6, and HEXIM1. KRT19 showed potential as a biomarker for anti-MDA5+ DM patients. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">CLINICAL RHEUMATOLOGY</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/27255864/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Immunology </span> </div> <h4> <a href="https://www.peeref.com/zh/works/27777479" class="text-dark hover-underline">Type 1 interferon signature in peripheral blood mononuclear cells and monocytes of idiopathic inflammatory myopathy patients with different myositis-specific autoantibodies</a> </h4> <p class="text-ellipsis-2">Mengdi Li, Yusheng Zhang, Wenzhe Zhang, Jinlei Sun, Rui Liu, Zhou Pan, Panpan Zhang, Shengyun Liu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> The type I interferon (IFN-I) pathway is remarkably activated in patients with inflammatory myopathy, especially in those with anti-melanoma differentiation-associated gene 5 (MDA5) antibodies. Abnormal expression of monocyte subsets and cytokines may contribute to the activation of the IFN signature. The IFN-related genes are correlated with laboratory parameters and helpful for diagnosis of inflammatory myopathy. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">FRONTIERS IN IMMUNOLOGY</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/27777479/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Physical </span> </div> <h4> <a href="https://www.peeref.com/zh/works/26455841" class="text-dark hover-underline">Hydrogen-Bonded Organic Frameworks: Structural Design and Emerging Applications</a> </h4> <p class="text-ellipsis-2">Xiaojun Ding, Yi Xie, Qiang Gao, Yilin Luo, Jing Chen, Gang Ye</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Constructing well-organized organic frameworks with tailor-made functionalities has the potential to enhance multi-domain applications. Hydrogen bonding is a type of weak intermolecular interaction, different from covalent bonding or metal-ligand coordination. Hydrogen-bonded organic frameworks (HOFs) assembled using hydrogen bonding have the advantage of decomposing and regenerating, improving processability and expanding applicability. This paper summarizes the basic building concepts of HOFs, including feasible hydrogen bonded motifs, effective molecular structures, and their emerging applications. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">CHEMPHYSCHEM</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/26455841/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/27633809" class="text-dark hover-underline">Charge-Assisted Hydrogen-Bonded Organic Frameworks with Inorganic Ammonium Regulated Switchable Open Polar Sites</a> </h4> <p class="text-ellipsis-2">Xiaojun Ding, Yilin Luo, Wei Wang, Tongyang Hu, Jing Chen, Gang Ye</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study presents a new approach of using inorganic ammonium cations as hydrogen bond donors to regulate the assembly of carboxylic tectons and build robust hydrogen-bonded frameworks. The resulting frameworks exhibit permanent ultra-micropores and open oxygen sites, with diverse pore architectures achieved by bridging different building blocks with tetrahedral NH4+. The activated porous PTBA·NH4·DMF demonstrates remarkable selective sorption of CO2 over N2 and H2. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">SMALL</span> (2023) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/27633809/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Environmental Sciences </span> </div> <h4> <a href="https://www.peeref.com/zh/works/35176697" class="text-dark hover-underline">Amplified role of potential HONO sources in O3 formation in North China Plain during autumn haze aggravating processes</a> </h4> <p class="text-ellipsis-2">Jingwei Zhang, Chaofan Lian, Weigang Wang, Maofa Ge, Yitian Guo, Haiyan Ran, Yusheng Zhang, Feixue Zheng, Xiaolong Fan, Chao Yan, Kaspar R. Daellenbach, Yongchun Liu, Markku Kulmala, Junling An</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Co-occurrences of high concentrations of PM2.5 and ozone (O-3) have been frequently observed in haze-aggravating processes in the North China Plain (NCP) over the past few years. The key sources of nitrous acid (HONO) enhancing O-3 during haze-aggravating processes remain unclear. This study explores the potential impact of nitrate photolysis (Phot(nitrate)) on O-3 formation and finds that it contributes significantly to the enhanced O-3 concentrations during hazy days, especially at higher altitudes. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ATMOSPHERIC CHEMISTRY AND PHYSICS</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/35176697/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Inorganic & Nuclear </span> </div> <h4> <a href="https://www.peeref.com/zh/works/24637497" class="text-dark hover-underline">Probing the Difference in the Complexation of Trivalent Actinides and Lanthanides with a Tridentate N,O-Hybrid Ligand: Spectroscopy, Thermodynamics, and Coordination Modes</a> </h4> <p class="text-ellipsis-2">Hong Cao, Pingping Wei, Ning Pu, Yusheng Zhang, Yanqiu Yang, Zhipeng Wang, Taoxiang Sun, Jing Chen, Chao Xu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> The complexation behavior of trivalent actinides and lanthanides with functional ligands was investigated. The results showed that the binding strength of Am(III) with DMAPA is slightly stronger than Nd(III). The complexation of Nd(III) with DMAPA is mainly entropy-driven, while the complexation of Am(III) with DMAPA is influenced by covalency. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">INORGANIC CHEMISTRY</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/24637497/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Engineering, Environmental </span> </div> <h4> <a href="https://www.peeref.com/zh/works/26167223" class="text-dark hover-underline">Weakened Gas-to-Particle Partitioning of Oxygenated Organic Molecules in Liquified Aerosol Particles</a> </h4> <p class="text-ellipsis-2">Wei Ma, Feixue Zheng, Yusheng Zhang, Xin Chen, Junlei Zhan, Chenjie Hua, Boying Song, Zongcheng Wang, Jiali Xie, Chao Yan, Markku Kulmala, Yongchun Liu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Aqueous-phase chemistry plays an important role in the formation of secondary organic aerosols (SOA), but the mechanism of interaction between aerosol physics and chemistry is not well understood. In this study, continuous measurements of gas and particle-phase composition were conducted to understand the physicochemical processes related to SOA formation. It was found that aqueous-phase oligomerization from methylglyoxal was a probable path of SOA formation. At high aerosol water content, gas-to-particle partitioning was weakened, leading to low OA mass fraction at high relative humidity. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ENVIRONMENTAL SCIENCE & TECHNOLOGY LETTERS</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/26167223/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Applied </span> </div> <h4> <a href="https://www.peeref.com/zh/works/22255253" class="text-dark hover-underline">Polar interaction of polymer host-solvent enables stable solid electrolyte interphase in composite lithium metal anodes</a> </h4> <p class="text-ellipsis-2">Peng Shi, Ze-Yu Liu, Xue-Qiang Zhang, Xiang Chen, Nan Yao, Jin Xie, Cheng-Bin Jin, Ying-Xin Zhan, Gang Ye, Jia-Qi Huang, Stephens E. Ifan, Titirici Maria-Magdalena, Qiang Zhang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> The study proposes a strategy of utilizing the interaction between a polar polymer host and solvent molecules to achieve a stable SEI and uniform Li deposition in a working battery. The composite Li anode with a PAN host demonstrates improved cycling performance and provides new guidance for designing practical composite Li anodes. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">JOURNAL OF ENERGY CHEMISTRY</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/22255253/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Cell Biology </span> </div> <h4> <a href="https://www.peeref.com/zh/works/23260144" class="text-dark hover-underline">Receptor for advanced glycation end products aggravates cognitive deficits in type 2 diabetes through binding of C-terminal AAs 2-5 to mitogen-activated protein kinase kinase 3 (MKK3) and facilitation of MEKK3-MKK3-p38 module assembly</a> </h4> <p class="text-ellipsis-2">Xiao-Yan Zhou, Chang-Jiang Ying, Bin Hu, Yu-Sheng Zhang, Tian Gan, Yan-Dong Zhu, Nan Wang, An-An Li, Yuan-Jian Song</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study explores the precise mechanisms underlying neuronal loss and behavioral dysfunction caused by RAGE in hyperglycemia. The study finds that RAGE binds with MKK3 and this binding is necessary for the assembly of the MEKK3-MKK3-p38 signaling module. Additionally, the activation of p38 MAPK/NF-kappa B signaling depends on the interaction between RAGE and MKK3 mediated by the C-terminal RAGE amino acids 2-5. Disruption of the RAGE-MKK3 conjugation through mutation improves synaptic plasticity and alleviates behavioral deficits. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">AGING CELL</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/23260144/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/24856449" class="text-dark hover-underline">Two-Photon 3D Printing in Metal-Organic Framework Single Crystals</a> </h4> <p class="text-ellipsis-2">Yusheng Zhang, Yuming Su, Yi Zhao, Zhiye Wang, Cheng Wang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study demonstrates the technology of two-photon polymerization inside a metal-organic framework crystal. Complex microstructures are built in the porous crystal to create a hybrid of crystal and microstructure. The metal-organic framework can be removed by acid treatment to release the printed structure. This technology has potential applications in MOF sensor device fabrication and data storage. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">SMALL</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/24856449/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Environmental Sciences </span> </div> <h4> <a href="https://www.peeref.com/zh/works/24928618" class="text-dark hover-underline">Experimental Analysis of Atmospheric Ducts and Navigation Radar Over-the-Horizon Detection</a> </h4> <p class="text-ellipsis-2">Li-Feng Huang, Cheng-Guo Liu, Hong-Guang Wang, Qing-Lin Zhu, Li-Jun Zhang, Jie Han, Yu-Sheng Zhang, Qian-Nan Wang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study investigates the relationship between navigation radar's over-the-horizon detection, atmospheric ducts, and evaporation ducts through experiments and model simulations. The results indicate that lower atmospheric ducts can lead to long-range over-the-horizon detection, while evaporation ducts only result in weak over-the-horizon detection. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">REMOTE SENSING</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/24928618/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 "> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Physical </span> </div> <h4> <a href="https://www.peeref.com/zh/works/24533961" class="text-dark hover-underline">Engineering the Dynamic Hydrogen Bonds in π-Stacked Supramolecular Assemblies for Hierarchical Nanocrystal Formation</a> </h4> <p class="text-ellipsis-2">Yanqi Liu, Zeyu Liu, Jianfeng Jia, Gang Ye, Yi Xie, Wei Wang, Jing Chen, Tongyang Hu, Krzysztof Matyjaszewski</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study presents a novel class of crystalline polyphenol assemblies regulated by the interplay of pi-pi stacking and reconfigurable hydrogen bonds. The structured reorganization of these assemblies resulted in low-dimensional nanocrystals with flexible and multifunctional properties. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">CHEMISTRY OF MATERIALS</span> (2022) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/24533961/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> </div> <div id="articles_from_journal" class="tab-pane "> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82924247" class="text-dark hover-underline">Regulating the Solvation Structure in Polymer Electrolytes for High-Voltage Lithium Metal Batteries</a> </h4> <p class="text-ellipsis-2">Yuncong Liu, Zhekai Jin, Zeyu Liu, Hao Xu, Furong Sun, Xue-Qiang Zhang, Tao Chen, Chao Wang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study proposes a new strategy to design polymer electrolytes for high-energy-density lithium metal batteries by regulating ion-dipole interactions. The strategy reduces the Li+-polymer interaction and enhances the anion-polymer interaction by combining specific interactions in the polymer electrolyte, resulting in a polymer electrolyte with a high lithium-ion transfer number and a wide electrochemical window. This electrolyte is compatible with both lithium metal anode and high-voltage NCM cathode, enabling stable cycling. This study provides a new idea for the design of polymer electrolytes for lithium metal batteries. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82924247/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83065320" class="text-dark hover-underline">Cu1-Fe Dual Sites for Superior Neutral Ammonia Electrosynthesis from Nitrate</a> </h4> <p class="text-ellipsis-2">Biao Zhou, Linghao Yu, Weixing Zhang, Xupeng Liu, Hao Zhang, Jundi Cheng, Ziyue Chen, Meiqi Li, Yanbiao Shi, Falong Jia, Yi Huang, Lizhi Zhang, Zhihui Ai</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study constructed a Cu-1-Fe dual-site catalyst for electrochemical NO3RR, achieving efficient NO3- removal and NH3 selectivity. The catalyst enhanced the adsorption of NO3- on Fe sites and the activation of water on single-atom Cu sites, reducing the energy barrier of the reaction and improving the reaction efficiency. This work provides a new strategy for the electrocatalytic synthesis of NH3 from NO3- and a sustainable approach for the treatment of neutral nitrate wastewater. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83065320/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84363210" class="text-dark hover-underline">Confinement Synthesis of Atomic Copper-Anchored Polymeric Carbon Nitride in Crystalline UiO-66-NH2 for High-Performance CO2-to-CH3OH Photocatalysis</a> </h4> <p class="text-ellipsis-2">Xingbing Liu, Changyan Zhu, Mengying Li, Hongzhu Xing, Siyang Zhu, Xin Liu, Guangshan Zhu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study reports a confinement synthesis method of polymeric carbon nitride incorporated with copper single atoms inside crystalline UiO-66-NH2, which combines the advantages of heterojunction photocatalysis and single-atom catalysis to achieve high-performance conversion of carbon dioxide to methanol. The study shows that the doping of copper single atoms and the formation of type-II heterojunction are the reasons for the generation of methanol. This study provides new ideas for the design of high-performance photocatalysts for the conversion of carbon dioxide to fuels at the atomic scale. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84363210/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83158369" class="text-dark hover-underline">Oxygen Vacancies Trigger Rapid Charge Transport Channels at the Engineered Interface of S-Scheme Heterojunction for Boosting Photocatalytic Performance</a> </h4> <p class="text-ellipsis-2">Di Zu, Yiran Ying, Qi Wei, Pei Xiong, Mortuza Saleque Ahmed, Zezhou Lin, Molly Meng-Jung Li, Mingjie Li, Zhihang Xu, Gao Chen, Liqi Bai, Sixuan She, Yuen Hong Tsang, Haitao Huang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A novel S-scheme photocatalyst WO3-Ov/In2S3 with Ovs at the heterointerface is designed. Ovs optimize the microscopic environment and electronic structure of the heterointerface, trigger additional charge transfer paths, improve charge separation efficiency, and have a synergistic effect on the thermodynamic and kinetic parameters of the S-scheme photocatalyst. This work provides new insights into regulating the dynamics of photogenerated carriers and helps design efficient S-scheme photocatalysts. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83158369/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83146493" class="text-dark hover-underline">Rare Earth Single-Atom Catalysis for High-Performance Li-S Full Battery with Ultrahigh Capacity</a> </h4> <p class="text-ellipsis-2">Rong Zhou, Yongqiang Ren, Weixin Li, Meng Guo, Yinan Wang, Haixin Chang, Xin Zhao, Wei Hu, Guowei Zhou, Shaonan Gu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Sm SACs can enhance the catalytic conversion of polysulfides and the uniform deposition of lithium in Li-S batteries, improving battery performance. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83146493/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84221232" class="text-dark hover-underline">Photoredox-Catalyzed [3+2] annulation of Aromatic Amides with Olefins via Iminium Intermediates</a> </h4> <p class="text-ellipsis-2">Zhanyong Tang, Zhenying Yao, Yueyang Yu, Jialin Huang, Xiaoqiang Ma, Xingda Zhao, Zhe Chang, Depeng Zhao</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This research reports the first example of a photoredox-catalyzed radical-type [3+2] annulation reaction of aromatic amides with olefins. The reaction generates iminium radicals via photocatalysis, which then undergoes cycloaddition with olefins to afford iminium products with excellent functional group tolerance. This method provides a new approach for the synthesis of nitrogen-containing heterocyclic compounds. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84221232/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83084973" class="text-dark hover-underline">Boosting Solar-Driven CO2 Conversion to Ethanol via Single-Atom Catalyst with Defected Low-Coordination Cu-N2 Motif</a> </h4> <p class="text-ellipsis-2">Hainan Shi, Yan Liang, Jungang Hou, Haozhi Wang, Zhenghao Jia, Jiaming Wu, Fei Song, Hong Yang, Xinwen Guo</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A high-performance carbon nitride supported Cu single-atom catalyst with a defective low-coordination Cu-N-2 motif is reported. This catalyst exhibits superior photocatalytic activity for CO2 reduction to ethanol, with high ethanol production rate and selectivity. The superior photoactivity of Cu-N-2-V stems from its defective Cu-N-2 configuration, which enhances electron delocalization. The hollow microstructure of the catalyst also promotes light adsorption and charge separation efficiency. This study also elucidates the C-C coupling reaction path and reveals the valence state change of partial Cu species during the CO2 photoreduction reaction. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83084973/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84740264" class="text-dark hover-underline">Idealizing Air-Processed Perovskite Film Competitive by Surface Lattice Etching-Reconstruction for High-Efficiency Solar Cells</a> </h4> <p class="text-ellipsis-2">Hui Li, Jialong Duan, Chenlong Zhang, Naimin Liu, Linzheng Ma, Xingxing Duan, Jie Dou, Qiyao Guo, Benlin He, Yuanyuan Zhao, Qunwei Tang</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A strategy is proposed to simultaneously remove the surface defect layer and solidify the surface by soaking the air-fabricated perovskite film in a low-polar organic ester at an elevated temperature, triggering an in situ dynamic surface lattice disassemble and reconstruction process. This method can harden the soft surface and release the lattice tensile stress, which is beneficial to minimizing the interfacial recombination and improving the structural stability. This study provides a promising way to overcome the processing conditions limit in the advancement of perovskite-based optoelectronic devices. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84740264/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83067658" class="text-dark hover-underline">Amorphous FeSnOx Nanosheets with Hierarchical Vacancies for Room-Temperature Sodium-Sulfur Batteries</a> </h4> <p class="text-ellipsis-2">Wu Sun, Junyu Hou, Yunlei Zhou, Tianke Zhu, Qunyao Yuan, Shaolei Wang, Farid Manshaii, Changsheng Song, Xingyu Lei, Xiaoyan Wu, Hern Kim, Yi Yu, Chuanxiao Xiao, Hongjun Zhang, Yun Song, Dalin Sun, Binbin Jia, Guangmin Zhou, Jie Zhao</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This paper introduces a multifunctional layer for room-temperature sodium-sulfur batteries, which is composed of amorphous two-dimensional iron tin oxide nanosheets with hierarchical vacancies. This layer can solve the problems of polysulfide dissolution, slow sulfur conversion kinetics, and sodium dendrite growth in the battery. The multifunctional layer has the characteristics of ultra-light, ultra-thin, and ultra-robust, which can significantly improve the performance of the battery. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83067658/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/84377475" class="text-dark hover-underline">Designing Cooperative Ion Transport Pathway in Ultra-Thin Solid-State Electrolytes toward Practical Lithium Metal Batteries</a> </h4> <p class="text-ellipsis-2">Guo Feng, Qianyi Ma, Dan Luo, Tingzhou Yang, Yihang Nie, Zhuoyi Zheng, Leixin Yang, Shibin Li, Qingying Li, Mingliang Jin, Xin Wang, Zhongwei Chen</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study designs an ultrathin solid-state electrolyte with a long-range cooperative ion transport path by impregnating PVDF-HFP into the pores of a fluorinated covalent organic framework (CF3-COF), improving ionic conductivity and stability. The electrolyte also enhances mechanical strength and flexibility, ensuring uniform lithium deposition and inhibiting dendrite growth. The NCM523/Li pouch cell using this electrolyte has high capacity and long cycle life. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/84377475/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82985610" class="text-dark hover-underline">Glycol Monomethyl Ether-Substituted Carbazolyl Hole-Transporting Material for Stable Inverted Perovskite Solar Cells with Efficiency of 25.52 %</a> </h4> <p class="text-ellipsis-2">Hui Zhou, Weilin Wang, Yuwei Duan, Rui Sun, Yong Li, Zhuang Xie, Dongfang Xu, Meizi Wu, Youliang Wang, Hongxiang Li, Qunping Fan, Yang Peng, Yao Yao, Chentong Liao, Qiang Peng, Shengzhong Liu, Zhike Liu</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A novel hole-transporting material, [4-(3,6-glycol monomethyl ether-9H-carbazol-9-yl) butyl]phosphonic acid (GM-4PACz), is synthesized by introducing glycol monomethyl ether (GM) side chains at the carbazolyl unit. This material promotes the spreading of perovskite, has a well-matched energy band with perovskite, suppresses defects, and releases the residual stress at the buried interface of inverted perovskite solar cells (IPSCs). As a result, GM-4PACz-based IPSCs achieve a high efficiency of 25.52% and excellent operational stability. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82985610/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82986184" class="text-dark hover-underline">Efficient Neutral H2O2 Electrosynthesis from Favorable Reaction Microenvironments via Porous Carbon Carrier Engineering</a> </h4> <p class="text-ellipsis-2">Lingyan Jing, Wenyi Wang, Qiang Tian, Yan Kong, Xieshu Ye, Hengpan Yang, Qi Hu, Chuanxin He</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> This study designs a model catalyst composed of Pd nanoparticles supported on mesoporous carbon spheres for efficient electrocatalytic synthesis of hydrogen peroxide in neutral electrolytes. The catalyst exhibits approximately 95% selectivity at near-zero overpotential and achieves an outstanding H2O2 yield in a flow cell device. The study also demonstrates that mesoporous carbon supports promote O-2 enrichment and local pH elevation, establishing a favorable microenvironment for 2e(-) ORR. In addition, density functional theory calculations reveal that the strong interaction between Pd nanoparticles and carbon supports optimizes the adsorption of OOH* at the carbon edge, ensuring a highly active 2e(-) process. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82986184/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83891167" class="text-dark hover-underline">Azobenzene-Bridged Covalent Organic Frameworks Boosting Photocatalytic Hydrogen Peroxide Production from Alkaline Water: One Atom Makes a Significant Improvement</a> </h4> <p class="text-ellipsis-2">Hui-Hui Sun, Zhi-Bei Zhou, Yubin Fu, Qiao-Yan Qi, Zhen-Xue Wang, Shunqi Xu, Xin Zhao</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A novel photoactive azobenzene-bridged 2D COF (COF-TPT-Azo) shows an excellent photocatalytic H2O2 production rate up to 1498 μmol g-1 h-1 at pH = 11, which is 7.9 times higher than that of its corresponding imine-linked 2D COF (COF-TPT-TPA), although only one atom is different in the two 2D COFs (-N=N- vs. -C=N-). COF-TPT-Azo exhibits much narrower band gap, enhanced charge transport, and prompt photoactivity, which benefits from its azo linkages. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83891167/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 border-bottom"> <div> <span class="d-inline-block badge badge-blue"> Article </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/82985574" class="text-dark hover-underline">Amorphous MnRuOx Containing Microcrystalline for Enhanced Acidic Oxygen-Evolution Activity and Stability</a> </h4> <p class="text-ellipsis-2">Jingjing Zhang, Liangliang Xu, Xiaoxuan Yang, Song Guo, Yifei Zhang, Yang Zhao, Gang Wu, Gao Li</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> A hybrid MnRuOx catalyst with amorphous/crystalline heterostructure was developed, which showed high activity and stability in the oxygen evolution reaction. The heterostructure provided abundant defects and active sites, facilitating OH- adsorption and conversion. The catalyst performed well under various operating conditions and is promising to replace Ir in water electrolyzers. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/82985574/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> <div class="my-4 "> <div> <span class="d-inline-block badge badge-blue"> Review </span> <span class="d-inline-block badge badge-cyan"> Chemistry, Multidisciplinary </span> </div> <h4> <a href="https://www.peeref.com/zh/works/83123273" class="text-dark hover-underline">Enhancing the Cycle Life of Zinc-Iodine Batteries in Ionic Liquid-Based Electrolytes</a> </h4> <p class="text-ellipsis-2">Mega Kar, Cristina Pozo-Gonzalo</p> <div class="d-flex mb-3"> <div class="p-3 rounded bg-light-blue"> <strong>Summary:</strong> Aqueous Zn-I2 batteries have some problems, such as Zn dendrite formation, hydrogen evolution reaction, and polyiodide dissolution, which will affect the long cycle and durability of the battery. The study by Xiao et al. found that adding imidazolium-based ionic liquid to the aqueous electrolyte can improve these problems and improve the cycle life and performance of the battery. </div> </div> <div class="d-flex justify-content-between"> <p class="font-weight-bold"> <span class="text-primary">ANGEWANDTE CHEMIE-INTERNATIONAL EDITION</span> (2024) </p> <div class="flex-shrink-0"> <a class="btn btn-outline-primary btn-sm" href="https://www.peeref.com/zh/works/83123273/add-to-collection" target="_blank"> <strong>添加到收藏夹</strong> </a> </div> </div> </div> </div> </div> </div> </div> </div> </div> <div class="modal fade" id="export-citation" tabindex="-1"> <div class="modal-dialog"> <div class="modal-content"> <div class="modal-header"> <button type="button" class="close" data-dismiss="modal"><span>×</span></button> <h4 class="modal-title">导出引文 <b class="text-primary"></b></h4> </div> <div class="modal-body"> <div class="my-3 px-4 f16"> <form 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Binary Solvent Regulated Architecture of Ultra-Microporous Hydrogen-Bonded Organic Frameworks with Tunable Polarization for Highly-Selective Gas Separation - Peeref