Ghost imaging in the time domain allows for reconstructing fast temporal objects using a slow photodetector.The technique involves correlating random or pre-programmed probing temporal intensity patterns with the inte...Ghost imaging in the time domain allows for reconstructing fast temporal objects using a slow photodetector.The technique involves correlating random or pre-programmed probing temporal intensity patterns with the integrated signal measured after modulation by the temporal object.However,the implementation of temporal ghost imaging necessitates ultrafast detectors or modulators for measuring or pre-programming the probing intensity patterns,which are not available in all spectral regions especially in the mid-infrared range.Here,we demonstrate a frequency downconversion temporal ghost imaging scheme that enables to extend the operation regime to arbitrary wavelengths regions where fast modulators and detectors are not available.The approach modulates a signal with temporal intensity patterns in the near-infrared and transfers the patterns to an idler via difference-frequency generation in a nonlinear crystal at a wavelength where the temporal object can be retrieved.As a proof-of-concept,we demonstrate computational temporal ghost imaging in the mid-infrared with operating wavelength that can be tuned from 3.2 to 4.3μm.The scheme is flexible and can be extended to other regimes.Our results introduce new possibilities for scan-free pump-probe imaging and the study of ultrafast dynamics in spectral regions where ultrafast modulation or detection is challenging such as the mid-infrared and THz regions.展开更多
基金supported by National Natural Science Foundation of China (62375189,62311530045,62005186,U22A2090,62075144)Sichuan Outstanding Youth Science and Technology Talents (2022JDJQ0031)+1 种基金Engineering Featured Team Fund of Sichuan University (2020SCUNG105)the Research Council of Finland (320165,356243 and 333949).
文摘Ghost imaging in the time domain allows for reconstructing fast temporal objects using a slow photodetector.The technique involves correlating random or pre-programmed probing temporal intensity patterns with the integrated signal measured after modulation by the temporal object.However,the implementation of temporal ghost imaging necessitates ultrafast detectors or modulators for measuring or pre-programming the probing intensity patterns,which are not available in all spectral regions especially in the mid-infrared range.Here,we demonstrate a frequency downconversion temporal ghost imaging scheme that enables to extend the operation regime to arbitrary wavelengths regions where fast modulators and detectors are not available.The approach modulates a signal with temporal intensity patterns in the near-infrared and transfers the patterns to an idler via difference-frequency generation in a nonlinear crystal at a wavelength where the temporal object can be retrieved.As a proof-of-concept,we demonstrate computational temporal ghost imaging in the mid-infrared with operating wavelength that can be tuned from 3.2 to 4.3μm.The scheme is flexible and can be extended to other regimes.Our results introduce new possibilities for scan-free pump-probe imaging and the study of ultrafast dynamics in spectral regions where ultrafast modulation or detection is challenging such as the mid-infrared and THz regions.
