Tailoring terahertz radiation by controlling tunnel photoionization events in gases

Babushkin, Ihar; Skupin, Stefan; Husakou, Anton; Köhler, Christian; Cabrera-Granado, E.; Bergé, Luc; Herrmann, Joachim

doi:10.1088/1367-2630/13/12/123029

Cited by 127 publications

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“…Recently, large-sized organic crystals were used to deliver THz pulses with GV=m electric field strength, and a conversion efficiency of about 1% was demonstrated [10]. The second method is based on focusing a femtosecond pulse together with its second harmonic into a gas cell and create a plasma [11][12][13][14][15][16][17][18][19][20][21][22][23][24]. In such two-color pump setup, free electrons produced by tunnel ionization acquire a nonzero drift velocity and generate a quasi-dc current which is responsible for THz emission [19].…”

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“…In such two-color pump setup, free electrons produced by tunnel ionization acquire a nonzero drift velocity and generate a quasi-dc current which is responsible for THz emission [19]. The mechanism underlying THz generation in gases is intrinsically related to the optically induced stepwise increase of the free electron density near the extrema of the ionizing optical field [15,16,22]. An easy explanation is that the Fourier transform of a steplike function in time has its maximum near the zero frequency.…”

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“…Boosting the THz yield is confirmed through comprehensive 3D computations that take all propagation effects into account. Selecting the first four Fourier harmonics of the sawtooth waveform already guarantees an impressive increase of the THz energy up to 5 μJ from a 300 μJ pump pulse.We start with the local current (LC) approximation [15], which neglects propagation effects. The free electron density ρðtÞ and current JðtÞ are governed by ∂ρðtÞ ∂t ¼ W½EðtÞ ½ρ 0 − ρðtÞ ;…”

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“…We start with the local current (LC) approximation [15], which neglects propagation effects. The free electron density ρðtÞ and current JðtÞ are governed by ∂ρðtÞ ∂t ¼ W½EðtÞ ½ρ 0 − ρðtÞ ; ð1Þ…”

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“…1(a)]. Assuming a small size of the plasma spot, E THz ðtÞ is evaluated by the low-frequency filtering of g∂ t JðtÞ, where g is a geometrical factor [15]. Ionization mostly happens near the extrema of EðtÞ.…”

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Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

et al. 2015

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Broadband ultrashort terahertz (THz) pulses can be produced using plasma generation in a noble gas ionized by femtosecond two-color pulses. Here we demonstrate that, by using multiple-frequency laser pulses, one can obtain a waveform which optimizes the free electron trajectories in such a way that they acquire the largest drift velocity. This allows us to increase the THz conversion efficiency to 2%, an unprecedented performance for THz generation in gases. In addition to the analytical study of THz generation using a local current model, we perform comprehensive 3D simulations accounting for propagation effects which confirm this prediction. Our results show that THz conversion via tunnel ionization can be greatly improved with well-designed multicolor pulses. DOI: 10.1103/PhysRevLett.114.183901 PACS numbers: 42.65.Re, 32.80.Fb, 52.50.Jm Ultrashort pulses in the terahertz (THz) range (from ∼0.1 to ∼30 THz) are extremely important for various timeresolved studies in molecular physics, chemistry, material sciences, and security applications [1][2][3][4][5][6][7][8]. One of the major challenges in this field is the development of THz emitters producing high peak intensities. So far, besides conventional devices such as antennas, photoconductive switches, etc., two main techniques have been explored for producing subps THz pulses with energies in the microjoule range. The first method is based on optical rectification in second-order nonlinear crystals [9]. Pumped by multi-mJ single color pulses, this technique requiring phase matching can generate THz pulses with 10 μJ energy, but the bandwidth is limited to a few THz. Recently, large-sized organic crystals were used to deliver THz pulses with GV=m electric field strength, and a conversion efficiency of about 1% was demonstrated [10]. The second method is based on focusing a femtosecond pulse together with its second harmonic into a gas cell and create a plasma [11][12][13][14][15][16][17][18][19][20][21][22][23][24]. In such two-color pump setup, free electrons produced by tunnel ionization acquire a nonzero drift velocity and generate a quasi-dc current which is responsible for THz emission [19]. The mechanism underlying THz generation in gases is intrinsically related to the optically induced stepwise increase of the free electron density near the extrema of the ionizing optical field [15,16,22]. An easy explanation is that the Fourier transform of a steplike function in time has its maximum near the zero frequency. Besides, critical for the generated THz energy is a pronounced asymmetry in time of the pump wave shape with respect to the field extrema, which dictates the electron drift velocity. This gas-based scheme for THz generation provides higher breakdown threshold and broader spectral ranges than the method involving crystals [11][12][13][17][18][19][20]. THz pulses in gases with high field strength > 1 GV=m were simulated in [16]; however, the highest reported THz energies (5 μJ) correspond to conversion efficiencies of about 10 −4 only.In this Let...

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Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

et al. 2015

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THz radiation generation via the interaction of two‐colour ultra‐short laser pulses with SO₂ and NH₃ gases

Gishini

Ganjovi

2017

Contrib. Plasma Phys

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In this work, using a two‐dimensional particle‐in‐cell Monte Carlo collision computation method, terahertz (THz) radiation generation via the interaction of two‐colour, ultra‐short, high‐power laser pulses with the polyatomic molecular gases sulphur dioxide (SO2) and ammonia (NH3) is examined. The influence of SO2 and NH3 pressures and two‐colour laser pulse parameters, i.e., pulse shape, pulse duration, and beam waist, on the THz radiation generation is studied. It is shown that the THz signal generation from SO2 and NH3 increases with the background gas pressure. It is seen that the THz emission intensity for both gases at higher laser pulse durations is higher. Moreover, for these polyatomic gases, the plasma current density increases with increase in the laser pulse beam waist. A more powerful THz radiation intensity with a larger time to peak of the plasma current density is observed for SO2 compared to NH3. In addition, many THz signals with small intensities are observed for both polyatomic gases. It is seen that for both SO2 and NH3 the generated THz spectral intensity is higher at higher gas pressures.

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Phase Evolution and THz Emission from a Femtosecond Laser Filament in Air

Liu

2014

Springer Series in Chemical Physics

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The recent progress in the study of waveform-controlled terahertz (THz) generation from air plasma at SIOM is reviewed. Carrier envelope phase (CEP) stabilized Infrared (center wavelength ∼1.8 μm) few-cycle laser pulses are produced through a home-built three-stage optical parametric amplifier (OPA) system pumped by a Ti:Sapphire laser amplifier and a hollow-fiber compressor filled with argon gas. By focusing the few-cycle pulses into the ambient air, THz radiation is generated from the produced filament. THz waveform can be controlled by varying the filament length and the CEP of driving laser pulses. Calculations using the photocurrent model and including the propagation effects well reproduce the experimental results, and the origins of various phase shifts in the filament are elucidated. Such waveformcontrolled THz emission is of great importance due to its potential application in THz sensing and coherent control of quantum systems. For the application of measuring the CEP of few-cycle laser pulses, the evolution of THz waveform generated in air plasma provides a sensitive probe to the variation of the initial CEP of propagating intense few-cycle pulses. The number and positions of the inversion of THz waveform are dependent on the initial CEP, which is near 0.5π constantly under varied input pulse energies when two inversions of THz waveform in air plasma become one. This provides a method of measuring the initial CEP in an accuracy that is only limited by the stability of the driving few-cycle pulses.

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Tailoring terahertz radiation by controlling tunnel photoionization events in gases

Cited by 127 publications

References 50 publications

Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

THz radiation generation via the interaction of two‐colour ultra‐short laser pulses with SO₂ and NH₃ gases

Phase Evolution and THz Emission from a Femtosecond Laser Filament in Air

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Tailoring terahertz radiation by controlling tunnel photoionization events in gases

Cited by 127 publications

References 50 publications

Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

Boosting Terahertz Generation in Laser-Field Ionized Gases Using a Sawtooth Wave Shape

THz radiation generation via the interaction of two‐colour ultra‐short laser pulses with SO2 and NH3 gases

Phase Evolution and THz Emission from a Femtosecond Laser Filament in Air

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THz radiation generation via the interaction of two‐colour ultra‐short laser pulses with SO₂ and NH₃ gases