Mechanoluminescent(ML)materials,which have the ability to convert mechanical energy to optical energy,have found huge promising applications such as in stress imaging and anti-counterfeiting.However,the main reported ...Mechanoluminescent(ML)materials,which have the ability to convert mechanical energy to optical energy,have found huge promising applications such as in stress imaging and anti-counterfeiting.However,the main reported ML phosphors are based on trap-related ones,thus hindering the practical applications due to the requirement of complex light pre-irradiation process.Here,a self-recoverable near infrared(NIR)ML material of Lali-xO:xCr^(3+)(x=0.2%,0.4%,0.6%,0.8%,1.0%,and 1.2%)has been developed.Based on the preheating method and corresponding ML performance analysis,the influences of residual carriers are eliminated and the detailed dynamic luminescence process analysis is realized.Systematic experiments are conducted to reveal the origin of the ML emissions,demonstrating that ML is dictated more by the non-centrosymmetric piezoelectric crystal characteristic.In general,this work has provided significant references for exploring more efficient NIR ML materials,which may provide potential applications in anti-counterfeiting and bio-stress sensing.展开更多
Optical temperature sensors,which can accurately detect temperature in biological systems,are crucial to the development of healthcare monitoring.To challenge the state-of-art technology,it is necessary to design sing...Optical temperature sensors,which can accurately detect temperature in biological systems,are crucial to the development of healthcare monitoring.To challenge the state-of-art technology,it is necessary to design single luminescence center doped materials with multi-wavelength emission for optical temperature sensors with more modes and higher resolution.Here,an Er^(3+)single-doped KYF4 nanocrystals glass ceramic with an obvious thermochromic phenomenon is reported for thefirst time,which shows a different temperature-dependent green,red,and near-infrared luminescence behavior based on thermal disturbance model.In addition,Er^(3+)single-doped GCfiber was drawn and fabricated into multi-mode opticalfiber temperature sensor,which has superior measured temperature resolution(<0.5℃),excellent detection limit(0.077℃),and high correlation coefficient(R^(2))of 0.99997.More importantly,this sensor can monitor temperature in different scenarios with great environmental interference resistance and repeatability.These results indicate that our sensor shows great promise as a technology for environmental and healthcare monitoring,and it provides a route for the design of opticalfiber temperature sensors with multi-mode and high resolution.展开更多
基金We gratefully acknowledge the financial support from the National Natural Science Foundation of China(No.52202003)Guangdong Basic and Applied Basic Research Foundation(No.2023A1515011893)+1 种基金State Key Laboratory of Powder Metallurgy,Central South University,Changsha,China(No.Sklpm-KF-27)Guangzhou Basic and Applied Basic Research Foundation(No.SL2022A04J00746)。
文摘Mechanoluminescent(ML)materials,which have the ability to convert mechanical energy to optical energy,have found huge promising applications such as in stress imaging and anti-counterfeiting.However,the main reported ML phosphors are based on trap-related ones,thus hindering the practical applications due to the requirement of complex light pre-irradiation process.Here,a self-recoverable near infrared(NIR)ML material of Lali-xO:xCr^(3+)(x=0.2%,0.4%,0.6%,0.8%,1.0%,and 1.2%)has been developed.Based on the preheating method and corresponding ML performance analysis,the influences of residual carriers are eliminated and the detailed dynamic luminescence process analysis is realized.Systematic experiments are conducted to reveal the origin of the ML emissions,demonstrating that ML is dictated more by the non-centrosymmetric piezoelectric crystal characteristic.In general,this work has provided significant references for exploring more efficient NIR ML materials,which may provide potential applications in anti-counterfeiting and bio-stress sensing.
基金support from National Natural Science Foundation of China(No.62122028,62235014,52202003,11974123 and 61675071)Guangdong Basic and Applied Basic Research Foundation(No.2023A1515011893 and 2023B1515040018)+2 种基金The Key R&D Program of Guangzhou(No.202007020003)Local Innovative and Research Teams Project of Guangdong Pearl River Talents Program(No.2017BT01X137)Guangdong Key Research and Development Program(No.2018B090904001).
文摘Optical temperature sensors,which can accurately detect temperature in biological systems,are crucial to the development of healthcare monitoring.To challenge the state-of-art technology,it is necessary to design single luminescence center doped materials with multi-wavelength emission for optical temperature sensors with more modes and higher resolution.Here,an Er^(3+)single-doped KYF4 nanocrystals glass ceramic with an obvious thermochromic phenomenon is reported for thefirst time,which shows a different temperature-dependent green,red,and near-infrared luminescence behavior based on thermal disturbance model.In addition,Er^(3+)single-doped GCfiber was drawn and fabricated into multi-mode opticalfiber temperature sensor,which has superior measured temperature resolution(<0.5℃),excellent detection limit(0.077℃),and high correlation coefficient(R^(2))of 0.99997.More importantly,this sensor can monitor temperature in different scenarios with great environmental interference resistance and repeatability.These results indicate that our sensor shows great promise as a technology for environmental and healthcare monitoring,and it provides a route for the design of opticalfiber temperature sensors with multi-mode and high resolution.
