Clusteroluminescence(CL)materials,as an emerging class of luminescent materials with unique photophysical properties,have received increasing attention owing to their great theoretical significance and potential for b...Clusteroluminescence(CL)materials,as an emerging class of luminescent materials with unique photophysical properties,have received increasing attention owing to their great theoretical significance and potential for biological applications.Although much progress has been made in the design,synthesis and application of CL materials,there is still a big challenge in the emission mechanism.So far,throughspace interaction has been proposed as the preliminary mechanism of the corresponding clusterizationtriggered emission(CTE)effect,but a systematic theory is still needed.This review summarizes the current mechanistic understanding of CL materials including organic/inorganic small molecules,and polymers with/without isolated aromatic structures.In addition,some strategies to achieve high quantum yield,adjustable emission color,and persistent room temperature phosphorescence in CL materials are also summarized.At last,a perspective of the mechanism and application of CL materials are demonstrated,which inspire the researchers working on the development of new kinds of functional materials.展开更多
Spiropolymers have gained a great deal of interest from both academic and industrial fields by virtue of their unique geometric structures and physical properties.Herein,we prepared a series of spirocopolymers through...Spiropolymers have gained a great deal of interest from both academic and industrial fields by virtue of their unique geometric structures and physical properties.Herein,we prepared a series of spirocopolymers through the catalyst-free four-component spiropolymerization of diisocyanides,activated alkynes,and two different kinds of monomers with reactive carbonyl groups.It is found that the polymerization reactivity of monomers,feeding modes,and feed ratios play significant roles in spirocopolymerization.Monomers with high reactivity and feeding reactive monomers first contribute to improving the molecular weights and yields of the polymers.The constructed copolymers have two different kinds of spiro structures,which is confirmed by the nuclear magnetic resonance.In addition,the spirocopolymers display the unique cluster-triggered emission and aggregation-induced emission properties,and their emission properties can be well-modulated by altering the ratio of comonomers.It is highly anticipated that this line of research will enrich the methodology of multi-component spiropolymerization,and provide a new insight into developing spiropolymers with various spiro structures and tunable properties.展开更多
基金the support of the National Natural Science Foundation of China(No.52003254)the support from the Fundamental Research Funds for the Central Universities(No.2021QNA4032)+5 种基金the Open Fund of Guangdong Provincial Key Laboratory of Luminescence from Molecular Aggregates,and South China University of Technology(No.2019B030301003)the support of Shenzhen Key laboratory of Functional Aggregate Materials(No.ZDSYS20211021111400001)the Science and Technology Plan of Shenzhen(Nos.JCYJ2021324134613038 and GJHZ20210705141810031)the support of the National Natural Science Foundation of China(No.52073172)the financial support of the National Science Foundation of the People’s Republic of China(Nos.51973190 and 21774108)Zhejiang Provincial Department of Science and Technology(No.2020R52006)。
文摘Clusteroluminescence(CL)materials,as an emerging class of luminescent materials with unique photophysical properties,have received increasing attention owing to their great theoretical significance and potential for biological applications.Although much progress has been made in the design,synthesis and application of CL materials,there is still a big challenge in the emission mechanism.So far,throughspace interaction has been proposed as the preliminary mechanism of the corresponding clusterizationtriggered emission(CTE)effect,but a systematic theory is still needed.This review summarizes the current mechanistic understanding of CL materials including organic/inorganic small molecules,and polymers with/without isolated aromatic structures.In addition,some strategies to achieve high quantum yield,adjustable emission color,and persistent room temperature phosphorescence in CL materials are also summarized.At last,a perspective of the mechanism and application of CL materials are demonstrated,which inspire the researchers working on the development of new kinds of functional materials.
基金supported by the National Natural Science Foundation of China(Nos.21875019,22175023,21975020 and 21975021)the National Key Research and Development Program of China(No.2018YFA0901800)+1 种基金College Students’Innovative Entrepreneurial Training Plan Program(No.BIT2022LH180)Beijing Institute of Technology Research Fund Program for Young Scholars.
文摘Spiropolymers have gained a great deal of interest from both academic and industrial fields by virtue of their unique geometric structures and physical properties.Herein,we prepared a series of spirocopolymers through the catalyst-free four-component spiropolymerization of diisocyanides,activated alkynes,and two different kinds of monomers with reactive carbonyl groups.It is found that the polymerization reactivity of monomers,feeding modes,and feed ratios play significant roles in spirocopolymerization.Monomers with high reactivity and feeding reactive monomers first contribute to improving the molecular weights and yields of the polymers.The constructed copolymers have two different kinds of spiro structures,which is confirmed by the nuclear magnetic resonance.In addition,the spirocopolymers display the unique cluster-triggered emission and aggregation-induced emission properties,and their emission properties can be well-modulated by altering the ratio of comonomers.It is highly anticipated that this line of research will enrich the methodology of multi-component spiropolymerization,and provide a new insight into developing spiropolymers with various spiro structures and tunable properties.
