MAPbI_(3)perovskite has attracted widespread interests for developing low-cost near infrared semiconductor gain media.However,it faces the instability issue under operation conditions,which remains a critical challeng...MAPbI_(3)perovskite has attracted widespread interests for developing low-cost near infrared semiconductor gain media.However,it faces the instability issue under operation conditions,which remains a critical challenge.It is found that the instability of the MAPbI_(3)nanoplatelet laser comes from the thermal-induced degradation progressing from the surface defects towards neighboring regions.By using PbI_(2) passivation,the defect-initiated degradation is significantly suppressed and the nanoplatelet degrades in a layer-by-layer way,enabling the MAPbI_(3)laser to sustain for 4500 s(2.7×10^(7) pulses),which is nearly three times longer than that of the nanoplatelet laser without passivation.Meanwhile,the PbI_(2) passivated MAPbI_(3)nanoplatelet laser with the nanoplatelet cavity displays a maximum quality factor up to∼7800,the highest reported for all MAPbI_(3)nanoplatelet cavities.Furthermore,a high stability MAPbI_(3)nanoplatelet laser that can last for 8500 s(5.1×10^(7) pulses)is demonstrated based on a dual passivation strategy,by retarding the defect-initiated degradation and surface-initiated degradation simultaneously.This work provides in-depth insights for understanding the operating degradation of perovskite lasers,and the dual passivation strategy paves the way for developing high stability near infrared semiconductor laser media.展开更多
We report the synthesis of uniform-sized hexagonal ZnO nanocrystals by the thermolysis of Zn-oleate complex,which was prepared from the reaction of inexpensive and environmentally friendly reagents such as zinc nitrat...We report the synthesis of uniform-sized hexagonal ZnO nanocrystals by the thermolysis of Zn-oleate complex,which was prepared from the reaction of inexpensive and environmentally friendly reagents such as zinc nitrate and sodium oleate.Two organic compounds with different boiling points,octadecene and octylether,were selected as the medium for thermolysis of Zn-oleate complex.Under optimized reaction conditions,we were able to synthesize ZnO nanoparticles with the size being about 10 nm.X-ray diffraction and transmission electron micrograph(TEM) images confirmed the high crystallinity of the nanocrystals.展开更多
基金supported by the National Natural Science Foundation of China (U21A20496,61922060,62205235,62204157,61805172,12104334,62174117,and 61905173)the Graduate Innovation Project of Shanxi Province (2020BY117)+9 种基金the Key Research and Development (International Cooperation)Program of Shanxi Province (201803D421044)the Natural Science Foundation of Shanxi Province (20210302123154 and 20210302123169)Research Project Supported by Shanxi Scholarship Council of China (2021-033)Research Project Supported by Shanxi-Zheda Institute of Advanced Materials and Chemical Engineering (2021SX-FR008 and 2022SX-TD020)Introduction of Talents Special Project of Lvliang City (Rc2020206,Rc2020207)Transformation Cultivation Project of University Scientific and Technological Achievements of Shanxi Province (2020CG013)the Key Research and Development Program of Shanxi Province (202102150101007)the support from the Research Grants Council,University Grants Committee,Hong Kong,General Research Fund (12303920)SZ-HK-Macao Science and Technology Plan Project (SGDX2020110309540000)Guangdong Basic and Applied Basic Research Fund (2022A1515010020)。
基金Science and Technology Innovation Commission of Shenzhen(JCYJ20170811093453105,JCYJ20170818141519879)Shenzhen Nanshan District Pilotage Team Program(LHTD20170006)+5 种基金Natural Science Foundation of Guangdong Province(2018A030313401)Platform and Base Special Project of Shanxi Province(201805D131012-3)Henry Fok Education Foundation Young Teachers FundKey Research and Development(International Cooperation)Program of Shanxi Province(201803D421044)Transformation Cultivation Project of University Scientific and Technological Achievements of Shanxi Province(2020CG013)National Natural Science Foundation of China(61775156YC,61922060YC,61961136001ZH)。
文摘MAPbI_(3)perovskite has attracted widespread interests for developing low-cost near infrared semiconductor gain media.However,it faces the instability issue under operation conditions,which remains a critical challenge.It is found that the instability of the MAPbI_(3)nanoplatelet laser comes from the thermal-induced degradation progressing from the surface defects towards neighboring regions.By using PbI_(2) passivation,the defect-initiated degradation is significantly suppressed and the nanoplatelet degrades in a layer-by-layer way,enabling the MAPbI_(3)laser to sustain for 4500 s(2.7×10^(7) pulses),which is nearly three times longer than that of the nanoplatelet laser without passivation.Meanwhile,the PbI_(2) passivated MAPbI_(3)nanoplatelet laser with the nanoplatelet cavity displays a maximum quality factor up to∼7800,the highest reported for all MAPbI_(3)nanoplatelet cavities.Furthermore,a high stability MAPbI_(3)nanoplatelet laser that can last for 8500 s(5.1×10^(7) pulses)is demonstrated based on a dual passivation strategy,by retarding the defect-initiated degradation and surface-initiated degradation simultaneously.This work provides in-depth insights for understanding the operating degradation of perovskite lasers,and the dual passivation strategy paves the way for developing high stability near infrared semiconductor laser media.
文摘We report the synthesis of uniform-sized hexagonal ZnO nanocrystals by the thermolysis of Zn-oleate complex,which was prepared from the reaction of inexpensive and environmentally friendly reagents such as zinc nitrate and sodium oleate.Two organic compounds with different boiling points,octadecene and octylether,were selected as the medium for thermolysis of Zn-oleate complex.Under optimized reaction conditions,we were able to synthesize ZnO nanoparticles with the size being about 10 nm.X-ray diffraction and transmission electron micrograph(TEM) images confirmed the high crystallinity of the nanocrystals.
