A theory of multiphoton photoemission is derived to explain the experimentally observed monotonic decrease with the wavelength in the electron yield of TiO_(2) nanoparticles(NPs)by as large as four orders of magnitude...A theory of multiphoton photoemission is derived to explain the experimentally observed monotonic decrease with the wavelength in the electron yield of TiO_(2) nanoparticles(NPs)by as large as four orders of magnitude.It is found that the fitting parameter corresponds to the energy position of Ti3d e_(g) and t_(2g) states,and the derived theory is a novel diagnostic of excited states in the conduction band,very importantly,applicable to individual NPs.The difference between four-photon slope NPs and three-photon slope NPs is attributed to the difference in defect density.The success of the theory in solving the puzzling result shows that thermal emission from high-lying levels may dominate over direct multiphoton ionization in solids when the photon number larger than four is required.展开更多
The comprehensive capture of near field spatiotemporal information of surface plasmon polaritons(SPPs)is a prerequisite for revealing their physical nature.In this study,we first performed an independent,spatiotempora...The comprehensive capture of near field spatiotemporal information of surface plasmon polaritons(SPPs)is a prerequisite for revealing their physical nature.In this study,we first performed an independent,spatiotemporal imaging of the out-of-plane and in-plane components of SPP near fields in a femtosecond light-excited trench using an obliquely incident time-resolved photoemission electron microscopy(TR-PEEM).We did the capture by imaging of the interference patterns induced by a superposition of the p-or s-polarized probe light,with the out-plane or in-plane components of SPP near-fields,under the noncollinear excitation mode.The method may be used to reconstruct a 3D SPP spatiotemporal field.Moreover,we demonstrated that the fringe shift of the in-terference patterns between the captured in plane and out-of plane components of the SPP field in PEEM images corresponds to the 1/4 fringe period,which is attributed toπ/2 out of phase of the out-of plane and in-plane near-field components of SPP.The resulting TR-PEEM images are supported by a classical wave mode and FDTD simulations.Essentially,the measuredπ/2 phase difference between the in-plane and out-of plane components of the SPP indicated a rotating field component in the propagation plane,i.e,that the SPP exhibits an elliptically polarized electric field in the propagation plane.The experimental results presented herein provide direct evidence of SPP having the inherent attributes of transverse spin angular momentum.展开更多
Coupling effect of chemical composition and physical structure is a key factor to construct superaerophobic electrodes.Almost all reports about superaerophobic electrodes were aimed at precisely controlling morphology...Coupling effect of chemical composition and physical structure is a key factor to construct superaerophobic electrodes.Almost all reports about superaerophobic electrodes were aimed at precisely controlling morphology of loaded materials(constructing specific structure)and ignored the due role of substrate.Nevertheless,in this work,by using high precision and controllable femtosecond laser,hierarchical micro-nano structures with superaerophobic properties were constructed on the surface of silicon substrate(fs-Si),and such special super-wettability could be successfully inherited to subsequent self-supporting electrodes through chemical synthesis.Femtosecond laser processing endowed electrodes with high electrochemical surface area,strong physical structure,and remarkable superaerophobic efficacy.As an unconventional processing method,the reconstructed morphology of substrate surface bears the responsibility of superaerophobicity,thus liberating the structural constraints on loaded materials.Since this key of coupling effect is transferred from the loaded materials to substrate,we provided a new general scheme for synthesizing superaerophobic electrodes.The successful introduction of femtosecond laser will open a new idea to synthesize self-supporting electrodes for gas-involving reactions.展开更多
Ultrafast spatiotemporal control of a surface plasmon polariton(SPP)launch direction is a prerequisite for ultrafast information processing in plasmonic nanocircuit components such as ultrafast on–off of plasmonic sw...Ultrafast spatiotemporal control of a surface plasmon polariton(SPP)launch direction is a prerequisite for ultrafast information processing in plasmonic nanocircuit components such as ultrafast on–off of plasmonic switching and information recording.Here we realize for the first time,to the best of our knowledge,ultrafast spatiotemporal control of the preferential launch direction of an SPP at the nano-femtosecond scale via a plasmonic nano directional coupler.The spatiotemporal switching of the SPP field was revealed using time-resolved photoemission electron microscopy(TR-PEEM).Experimental results show that the extinction ratio of the SPP directional coupler can be substantially optimized by properly selecting the amplitude and time delay of the two incident light pulses in the experiment.More importantly,we demonstrate a solution for the launch direction of the SPP field,switched in a plasmonic nano directional coupler on the femtosecond timescale,by adjusting the instantaneous polarization state of the excitation light.The TR-PEEM images are supported by finite-difference time-domain(FDTD)simulations.We believe the results of this study can be used to develop high-speed,miniaturized signal processing systems.展开更多
It is highly desirable to flexibly and actively manipulate the dephasing time of a plasmon in many potential applications;however,this remains a challenge.In this work,by using femtosecond time-resolved photoemission ...It is highly desirable to flexibly and actively manipulate the dephasing time of a plasmon in many potential applications;however,this remains a challenge.In this work,by using femtosecond time-resolved photoemission electron microscopy,we experimentally demonstrated that the Fano resonance mode in the asymmetric nanorod dimer can greatly extend the dephasing time of a femtosecond plasmon,whereas the non-Fano resonance results in a smaller dephasing time due to the large radiative damping,and flexible manipulation of the dephasing time can be realized by adjusting one of the nanorods in the Fano asymmetric dimer.Interestingly,it was found that plasmon resonance wavelengths both appeared red-shifted as the length of the upper or lower nanorods increased individually,but the dephasing time varied.Furthermore,it also indicated that the dephasing time can be prolonged with a smaller ascending rate by increasing the length of both the nanorods simultaneously while keeping the dimer asymmetry.Meanwhile,the roles of radiative and nonradiative damping in dephasing time are unveiled in the process of nanorod length variation.These results are well supported by numerical simulations and calculations.展开更多
基金Project supported by the National Natural Science Foundation of China(Grant Nos.91850109,11474040,61605017,and 61775021)the“111”Project of China(Grant No.D17017).
文摘A theory of multiphoton photoemission is derived to explain the experimentally observed monotonic decrease with the wavelength in the electron yield of TiO_(2) nanoparticles(NPs)by as large as four orders of magnitude.It is found that the fitting parameter corresponds to the energy position of Ti3d e_(g) and t_(2g) states,and the derived theory is a novel diagnostic of excited states in the conduction band,very importantly,applicable to individual NPs.The difference between four-photon slope NPs and three-photon slope NPs is attributed to the difference in defect density.The success of the theory in solving the puzzling result shows that thermal emission from high-lying levels may dominate over direct multiphoton ionization in solids when the photon number larger than four is required.
基金supported by the National Natural Science Foundation ofChina (Grant Nos. 60978014,61178022 and 11074027)the Basic Research Fund from Sci. & Tech. Department of Jilin Province (Grant Nos.20100521,20100168 and 20111812)
基金National Natural Science Foundation of China(91850109,61775021,11474040)Education Department of Jilin Province(JJKH20181104KJ,JJKH20190549KJ,JJKH20190555KJ)+1 种基金“111”Project of China(D17017)Changchun University of Science and Technology(XQNJJ-2018-02).
文摘The comprehensive capture of near field spatiotemporal information of surface plasmon polaritons(SPPs)is a prerequisite for revealing their physical nature.In this study,we first performed an independent,spatiotemporal imaging of the out-of-plane and in-plane components of SPP near fields in a femtosecond light-excited trench using an obliquely incident time-resolved photoemission electron microscopy(TR-PEEM).We did the capture by imaging of the interference patterns induced by a superposition of the p-or s-polarized probe light,with the out-plane or in-plane components of SPP near-fields,under the noncollinear excitation mode.The method may be used to reconstruct a 3D SPP spatiotemporal field.Moreover,we demonstrated that the fringe shift of the in-terference patterns between the captured in plane and out-of plane components of the SPP field in PEEM images corresponds to the 1/4 fringe period,which is attributed toπ/2 out of phase of the out-of plane and in-plane near-field components of SPP.The resulting TR-PEEM images are supported by a classical wave mode and FDTD simulations.Essentially,the measuredπ/2 phase difference between the in-plane and out-of plane components of the SPP indicated a rotating field component in the propagation plane,i.e,that the SPP exhibits an elliptically polarized electric field in the propagation plane.The experimental results presented herein provide direct evidence of SPP having the inherent attributes of transverse spin angular momentum.
基金the National Natural Science Foundation of China(Nos.21601018,51976015,51902029,61605017,and 51573023)the Science and Technology Development Planning Project of Jilin Province(Nos.20200201534JC,20200201250JC,20190103035JH,and 20200201234JC)+2 种基金Jilin Association for Science and Technology(No.QT202003)the Science and Technology Research Planning Project of the Education Department of Jilin Province(Nos.JJKH20210801KJ and JJKH20200745KJ)Project of Education Department in Jilin Province(Nos.20190586KJ and 20190552KJ).
文摘Coupling effect of chemical composition and physical structure is a key factor to construct superaerophobic electrodes.Almost all reports about superaerophobic electrodes were aimed at precisely controlling morphology of loaded materials(constructing specific structure)and ignored the due role of substrate.Nevertheless,in this work,by using high precision and controllable femtosecond laser,hierarchical micro-nano structures with superaerophobic properties were constructed on the surface of silicon substrate(fs-Si),and such special super-wettability could be successfully inherited to subsequent self-supporting electrodes through chemical synthesis.Femtosecond laser processing endowed electrodes with high electrochemical surface area,strong physical structure,and remarkable superaerophobic efficacy.As an unconventional processing method,the reconstructed morphology of substrate surface bears the responsibility of superaerophobicity,thus liberating the structural constraints on loaded materials.Since this key of coupling effect is transferred from the loaded materials to substrate,we provided a new general scheme for synthesizing superaerophobic electrodes.The successful introduction of femtosecond laser will open a new idea to synthesize self-supporting electrodes for gas-involving reactions.
基金National Natural Science Foundation of China(91850109,61775021,12004052,62005022,11474040)Education Department of Jilin Province(JJKH20181104KJ,JJKH20190549KJ,JJKH20190555KJ)+1 种基金Changchun University of Science and Technology(XQNJJ-2018-02)“111”Project of China(D17017).
文摘Ultrafast spatiotemporal control of a surface plasmon polariton(SPP)launch direction is a prerequisite for ultrafast information processing in plasmonic nanocircuit components such as ultrafast on–off of plasmonic switching and information recording.Here we realize for the first time,to the best of our knowledge,ultrafast spatiotemporal control of the preferential launch direction of an SPP at the nano-femtosecond scale via a plasmonic nano directional coupler.The spatiotemporal switching of the SPP field was revealed using time-resolved photoemission electron microscopy(TR-PEEM).Experimental results show that the extinction ratio of the SPP directional coupler can be substantially optimized by properly selecting the amplitude and time delay of the two incident light pulses in the experiment.More importantly,we demonstrate a solution for the launch direction of the SPP field,switched in a plasmonic nano directional coupler on the femtosecond timescale,by adjusting the instantaneous polarization state of the excitation light.The TR-PEEM images are supported by finite-difference time-domain(FDTD)simulations.We believe the results of this study can be used to develop high-speed,miniaturized signal processing systems.
基金National Natural Science Foundation of China(12004052,61775021,62005022,91850109)111 Project(D17017)+1 种基金Jilin Provincial Key Laboratory of Ultrafast and Extreme Ultraviolet Optics(YDZJ202102CXJD028)Ministry of Education Key Laboratory for Cross-Scale Micro and Nano Manufacturing,Changchun University of Science and Technology.
文摘It is highly desirable to flexibly and actively manipulate the dephasing time of a plasmon in many potential applications;however,this remains a challenge.In this work,by using femtosecond time-resolved photoemission electron microscopy,we experimentally demonstrated that the Fano resonance mode in the asymmetric nanorod dimer can greatly extend the dephasing time of a femtosecond plasmon,whereas the non-Fano resonance results in a smaller dephasing time due to the large radiative damping,and flexible manipulation of the dephasing time can be realized by adjusting one of the nanorods in the Fano asymmetric dimer.Interestingly,it was found that plasmon resonance wavelengths both appeared red-shifted as the length of the upper or lower nanorods increased individually,but the dephasing time varied.Furthermore,it also indicated that the dephasing time can be prolonged with a smaller ascending rate by increasing the length of both the nanorods simultaneously while keeping the dimer asymmetry.Meanwhile,the roles of radiative and nonradiative damping in dephasing time are unveiled in the process of nanorod length variation.These results are well supported by numerical simulations and calculations.
