廣東
中國化學會第35屆學術年會即將于4月11日在中國重慶啟幕。會議聚焦“賦能化學·新質未來”,匯聚全國化學領域頂尖學者共探學科前沿。4月13日下午2點,Wiley將在科學會堂西區2MF科學1舉行“Angewandte Symposium”論壇,德國化學會(GDCh)執行理事Tom Kinzel、中國化學會(CCS)秘書長范青華研究員將蒞臨現場,為論壇致開幕辭。
同時,論壇特邀吳驪珠院士、馮小明院士、田禾院士以及陸俊教授、林歆怡教授將帶來精彩的學術報告, 分享化學領域最新研究成果與創新見解。
會議預報名與編輯面對面環節預報名同步開啟(詳細日程與報告人介紹請見下文)
編輯面對面:頂刊主編一對一交流,精準助力論文發表
支持期刊:Angewandte Chemie, Advanced Materials
時間:4月12日、4月13日10:30-11:30
報名方式:通過上述預報名鏈接,填寫論文標題、上傳研究摘要并留存聯系方式,鎖定與Angewandte Chemie 和 Advanced Materials 主編面對面交流的寶貴機會,深度探討文章寫作、投稿技巧、期刊選題等核心問題。
論壇區域示意圖
展位區域示意圖
會議預報名與編輯面對面環節預報名同步開啟
https://uao.so/pct20d7f7b
大會同期,Wiley 還將在會場及展位舉辦多項精彩活動,包括Advanced Chemical Engineering創刊儀式,Angewandte Chemie、Advanced Synthesis& Catalysis及ChemistryEurope青年科學家獎頒獎儀式,以及備受期待的 Wiley 編輯面對面環節。我們還為現場與會者精心準備了豐富精美的 Wiley 期刊周邊紀念品,誠邀各位老師、同學蒞臨Wiley C17展位交流互動,共赴這場化學學術盛宴!
學術報告搶先看:
1
吳驪珠
中國科學院理化技術研究所
題目:Artificial Photosynthesis for Chemical Transformation
面向化學轉化的人工光合作用
Abstract: Inspired by the ability of natural photosynthesis to convert solar energy into chemical energy, the scientific community recognized the potential of light-driven reactions (photochemistry) as a powerful approach to chemical synthesis. From the high energy intermediate generated by photoinduced excitation of organic molecules, unique reaction manifolds can be accesses that are generally unavailable to conventional thermal pathways. Thus photochemical reactions considerably enrich the synthetic repertoire of modern organic chemists. Our group has long engaged in the photochemistry research related to the photoinduced energy transfer, electron transfer and chemical transformation. In this presentation, we will compile several stories to illustrate photochemical approaches that may be useful in the design of artificial photosynthetic systems for effective chemical transformation.
2
馮小明
四川大學
題目:Visible Light Induced Asymmetric Reactions Enabled by Chiral N,N'-Dioxide?Metal Complexes
手性 N,N'- 二氧化物 - 金屬配合物介導的可見光誘導不對稱反應
Abstract: The chiral N,N'-dioxide amide scaffold developed by the Feng group functions not only as an organocatalyst but also as a privileged chiral ligand. By coordinating with main-group, transition, or rare-earth metals, it forms well-defined Lewis acids known as Feng catalysts. These catalysts exhibit unique electronic and steric properties and have been successfully employed in more than 80 distinct classes of organic transformations.[1]
In recent years, the merger of chiral N,N'-dioxide?metal complex catalysis with photocatalysis has emerged as a powerful platform for enabling a range of unprecedented asymmetric transformations.[2] The possible reaction mechanisms as well as the roles of Feng catalysts were elucidated based on experimental and computational studies.
3
田禾
華東理工大學
題目:Multicolour Luminescence of Single Polycyclic Fluorophore based on Vibration-Induced Emission (VIE)
基于振動誘導發光(VIE)的單一多環熒光分子多色發光
Abstract: Herein, we demonstrate that a single polycyclic π-scaffold can undergo stepwise multistage excited-state structural evolution along the bent, planar, and twisted conformers, which coexist to produce intrinsic multiple fluorescence emissions. By installation a methyl or trifluoromethyl group on the ortho-site of N, N’-diphenyl-dihydrodibenzo [a,c] phenazine (DPAC), the enhanced steric effects change the fluorescence emission of DPAC from a dominant red band to well-resolved triple bands. Key molecular design strategies for VIE-active compounds are highlighted, revealing how the interplay of steric hindrance and electronic properties modulates excited-state energies and facilitates color tuning from blue to red. Advanced spectroscopy and theoretical studies are employed to explore the link between molecular conformation and emission properties. This lecture aims to stimulate broad interest across diverse fields, expanding both the scope of VIE research and the development of advanced functional materials. The results provide the proof of concept that the bent, planar, and twisted emissive states can coexist in the S1 PES of a polycyclic π-skeleton, which greatly expand the fundamental understanding of the excited-state structural relaxation.
4
陸俊
浙江大學
題目:Li-oxygen Battery: From Open System to Close System
鋰 - 氧電池:從開放體系到封閉體系
Abstract: To meet the high-energy requirement that can enable the 40-miles electric drive Plug in Hybrid Electric Vehicle (P-HEVs), long range electric vehicle (EV) and smart grid, it is necessary to develop very high energy and high power cathodes and anodes that when combined in a battery system must offer 5,000 charge-depleting cycles, 15 years calendar life as well as excellent safety characteristics. These challenging requirements make it difficult for conventional cathode materials to be adopted in P-HEVs and EVs. Metal-air batteries, specifically Li-air battery, have large theoretical energy density about 2-10 times higher than those of lithium-ion batteries, and are frequently advocated as the solution toward next-generation electrochemical energy storage for applications including electric vehicles or grid energy storage. In this talk, we summarize the recent discovery on developing the Li-O2 battery, particularly highlighting the strategy how to move this system from an open to a close configuration.
5
林歆怡
南洋理工大學
題目:Converging Nanotechnology and Artificial Intelligence in SERS Molecular Detection
人工智能與納米技術協同推進 SERS 分子檢測研究
Abstract: Nanomaterial-based sensors (“nanosensors”) are attractive detection tool to detect multiple disease biomarkers swiftly and at point-of-care. These nanosensors make use nanometer-sized particles with unique physical, optical, and electrical properties to induce enhanced output signals in response to the detection and/or changes in concentrations of analytes. In this talk, I will discuss my group’s effort in using one of the nanosensors, surface-enhanced Raman scattering (SERS) nanosensors for various biomedical applications. SERS utilizes metallic nanoparticles such as Ag and Au to harness incoming light excitation, concentrate surface plasmon resonances, and boost the Raman vibrational signatures of biomarkers for ultrasensitive detection. Firstly, I will discuss various SERS platform fabrication strategies to bestow desirable chemoselectivity and increase target analyte/biomarker affinity to achieve higher detection sensitivity and selectivity. I will also highlight various emerging research strategies which utilize machine learning algorithms for rapid on-site prediction of disease infection. Specifically, how chemometrics and machine learning algorithms can transform the assimilation and interpretation of complex spectral data in biological samples by discerning more patterns hidden within the data, to achieve high throughput data analysis, sensitivity, and disease prediction. Collectively, these advances underscore the potential of SERS nanosensors and hybrid analytical strategies to address longstanding challenges in biomarker sensing and to accelerate innovation in biomedical diagnostics.
威立(Wiley)是權威內容與科研智慧領域的全球領導者,致力于推動科學探索、創新發現與學習發展。兩個多世紀以來,我們始終立于學術生態體系的中心,將悠久的出版傳承與人工智能驅動的平臺深度融合,重塑知識的發現、獲取與應用方式。從獨立研究員、莘莘學子到世界500 強企業的研發團隊,威立始終助力將先進的科學突破轉化為切實的社會實踐。從知識到影響力 —— 我們正在重新定義科學與求知領域的無限可能。
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