High-precision optical frequency measurement serves as a cornerstone of modern science and technology,enabling advancements in fields ranging from fundamental physics to quantum information technologies.Obtaining prec...High-precision optical frequency measurement serves as a cornerstone of modern science and technology,enabling advancements in fields ranging from fundamental physics to quantum information technologies.Obtaining precise photon frequencies,especially in the ultraviolet or even extreme ultraviolet regimes,is a key goal in both light–matter interaction experiments and engineering applications.High-order harmonic generation(HHG)is an ideal light source for producing such photons.In this work,we propose an optical temporal interference model(OTIM)that establishes an analogy with multi-slit Fraunhofer diffraction(MSFD)to manipulate fine-frequency photon generation by exploiting the temporal coherence of HHG processes.Our model provides a unified physical framework for three distinct non-integer HHG generation schemes:single-pulse,shaped-pulse,and laser pulse train approaches,which correspond to single-MSFD-like,double-MSFD-like,and multi-MSFD-like processes,respectively.Arbitrary non-integer HHG photons can be obtained using our scheme.Our approach provides a new perspective for accurately measuring and controlling photon frequencies in fields such as frequency comb technology,interferometry,and atomic clocks.展开更多
Temporal interference(TI)is a form of stimulation that epitomizes an innovative and non-invasive approach for profound neuromodulation of the brain,a technique that has been validated in mice.Yet,the thin cranial bone...Temporal interference(TI)is a form of stimulation that epitomizes an innovative and non-invasive approach for profound neuromodulation of the brain,a technique that has been validated in mice.Yet,the thin cranial bone structure of mice has a marginal influence on the effect of the TI technique and may not effectively showcase its effectiveness in larger animals.Based on this,we carried out TI stimulation experiments on rats.Following the TI intervention,analysis of electrophysiological data and immunofluorescence staining indicated the generation of a stimulation focus within the nucleus accumbens(depth,8.5 mm)in rats.Our findings affirm the viability of the TI methodology in the presence of thick cranial bones,furnishing efficacious parameters for profound stimulation with TI administered under such conditions.This experiment not only sheds light on the intervention effects of TI deep in the brain but also furnishes robust evidence in support of its prospective clinical utility.展开更多
Transcranial temporal interference stimulation(tTIS)is a novel non-invasive neuromodulation technique with the potential to precisely target deep brain structures.This study explores the neural and behavioral effects ...Transcranial temporal interference stimulation(tTIS)is a novel non-invasive neuromodulation technique with the potential to precisely target deep brain structures.This study explores the neural and behavioral effects of tTIS on the superior colliculus(SC),a region involved in eye movement control,in mice.Computational modeling revealed that tTIS delivers more focused stimulation to the SC than traditional transcranial alternating current stimulation.In vivo experiments,including Ca^(2+)signal recordings and eye movement tracking,showed that tTIS effectively modulates SC neural activity and induces eye movements.A significant correlation was found between stimulation frequency and saccade frequency,suggesting direct tTIS-induced modulation of SC activity.These results demonstrate the precision of tTIS in targeting deep brain regions and regulating eye movements,highlighting its potential for neuroscientific research and therapeutic applications.展开更多
The real time domain interferometry for the photodetachment dynamics driven by the oscillating electric field has been studied for the first time. Both the geometry of the detached electron trajectories and the electr...The real time domain interferometry for the photodetachment dynamics driven by the oscillating electric field has been studied for the first time. Both the geometry of the detached electron trajectories and the electron probability density are shown to be different from those in the photodetachment dynamics in a static electric field. The influence of the oscillating electric field on the detached electron leads to a surprisingly intricate shape of the electron waves, and multiple interfering trajectories generate complex interference patterns in the electron probability density. Using the semiclassical open-orbit theory, we calculate the interference patterns in the time-dependent electron probability density for different electric field strengths, different frequencies and phases in the oscillating electric field. This method is universal, and can be extended to study the photoionization dynamics of the atoms in the time-dependent electric field. Our study can guide the future experimental researches in the photodetachment or photoionization microscopy of negative ions and atoms in the oscillating electric field.展开更多
Temporal interference(TI)stimulation is a non-invasive technique for electrically stimulating neurons at depth.1 It leverages the low-pass filtering properties of neural membranes,which render neurons more sensitive t...Temporal interference(TI)stimulation is a non-invasive technique for electrically stimulating neurons at depth.1 It leverages the low-pass filtering properties of neural membranes,which render neurons more sensitive to low-frequency oscillating fields compared with high-frequency fields(e.g.,R1 kHz).This approach generates a low-frequency modulated electric field—termed envelope modulation—by superimposing high-frequency currents with slightly different frequencies,applied via scalp electrodes.The characteristics of the envelope modulation are determined by the vector sum of the applied field vectors at a given point.By adjusting electrode positions and current ratios,the amplitude of the envelope modulation can be maximized at a point distant from the scalp,potentially reaching deep brain regions.展开更多
基金supported by the National Natural Science Foundation of China(Grant No.12304379)the Natural Science Foundation of Liaoning Province(Grant No.2024BS-269)the Guangdong Basic and Applied Basic Research Foundation(Grant No.025A1515011117)。
文摘High-precision optical frequency measurement serves as a cornerstone of modern science and technology,enabling advancements in fields ranging from fundamental physics to quantum information technologies.Obtaining precise photon frequencies,especially in the ultraviolet or even extreme ultraviolet regimes,is a key goal in both light–matter interaction experiments and engineering applications.High-order harmonic generation(HHG)is an ideal light source for producing such photons.In this work,we propose an optical temporal interference model(OTIM)that establishes an analogy with multi-slit Fraunhofer diffraction(MSFD)to manipulate fine-frequency photon generation by exploiting the temporal coherence of HHG processes.Our model provides a unified physical framework for three distinct non-integer HHG generation schemes:single-pulse,shaped-pulse,and laser pulse train approaches,which correspond to single-MSFD-like,double-MSFD-like,and multi-MSFD-like processes,respectively.Arbitrary non-integer HHG photons can be obtained using our scheme.Our approach provides a new perspective for accurately measuring and controlling photon frequencies in fields such as frequency comb technology,interferometry,and atomic clocks.
基金supported by the National Key Research and Development Program Project(2021YFC2400203)the Shaanxi Province Key Research and Development Program Project(2023-YBSF-120)+1 种基金the Shandong Provincial Natural Science Foundation(ZR2024QF287)the National Natural Science Foundation of China(31972907).
文摘Temporal interference(TI)is a form of stimulation that epitomizes an innovative and non-invasive approach for profound neuromodulation of the brain,a technique that has been validated in mice.Yet,the thin cranial bone structure of mice has a marginal influence on the effect of the TI technique and may not effectively showcase its effectiveness in larger animals.Based on this,we carried out TI stimulation experiments on rats.Following the TI intervention,analysis of electrophysiological data and immunofluorescence staining indicated the generation of a stimulation focus within the nucleus accumbens(depth,8.5 mm)in rats.Our findings affirm the viability of the TI methodology in the presence of thick cranial bones,furnishing efficacious parameters for profound stimulation with TI administered under such conditions.This experiment not only sheds light on the intervention effects of TI deep in the brain but also furnishes robust evidence in support of its prospective clinical utility.
基金supported by the National Natural Science Foundation of China(T2394533,32222036,82030038,and 62472206)the National Key Research and Development Program of China(2018YFA0701400)the Shenzhen Science and Technology Innovation Committee(2022410129,KJZD20230923115221044,and KCXFZ20201221173400001).
文摘Transcranial temporal interference stimulation(tTIS)is a novel non-invasive neuromodulation technique with the potential to precisely target deep brain structures.This study explores the neural and behavioral effects of tTIS on the superior colliculus(SC),a region involved in eye movement control,in mice.Computational modeling revealed that tTIS delivers more focused stimulation to the SC than traditional transcranial alternating current stimulation.In vivo experiments,including Ca^(2+)signal recordings and eye movement tracking,showed that tTIS effectively modulates SC neural activity and induces eye movements.A significant correlation was found between stimulation frequency and saccade frequency,suggesting direct tTIS-induced modulation of SC activity.These results demonstrate the precision of tTIS in targeting deep brain regions and regulating eye movements,highlighting its potential for neuroscientific research and therapeutic applications.
基金Project supported by the National Natural Science Foundation of China(Grant No.11374133)the Taishan Scholars Project of Shandong Province,China(Grant No.ts2015110055)
文摘The real time domain interferometry for the photodetachment dynamics driven by the oscillating electric field has been studied for the first time. Both the geometry of the detached electron trajectories and the electron probability density are shown to be different from those in the photodetachment dynamics in a static electric field. The influence of the oscillating electric field on the detached electron leads to a surprisingly intricate shape of the electron waves, and multiple interfering trajectories generate complex interference patterns in the electron probability density. Using the semiclassical open-orbit theory, we calculate the interference patterns in the time-dependent electron probability density for different electric field strengths, different frequencies and phases in the oscillating electric field. This method is universal, and can be extended to study the photoionization dynamics of the atoms in the time-dependent electric field. Our study can guide the future experimental researches in the photodetachment or photoionization microscopy of negative ions and atoms in the oscillating electric field.
基金supported by the National Natural Science Foundation of China(32322035,32171078,and 82060315)Guangxi Key Research and Development Program(AB22080053)。
文摘Temporal interference(TI)stimulation is a non-invasive technique for electrically stimulating neurons at depth.1 It leverages the low-pass filtering properties of neural membranes,which render neurons more sensitive to low-frequency oscillating fields compared with high-frequency fields(e.g.,R1 kHz).This approach generates a low-frequency modulated electric field—termed envelope modulation—by superimposing high-frequency currents with slightly different frequencies,applied via scalp electrodes.The characteristics of the envelope modulation are determined by the vector sum of the applied field vectors at a given point.By adjusting electrode positions and current ratios,the amplitude of the envelope modulation can be maximized at a point distant from the scalp,potentially reaching deep brain regions.
