Towards High-Repetition-Rate Intense Terahertz Source With Metal Wire-Based Plasma

Zhang, Dongdong; Bai, Y.; Zeng, Yushan; Ding, Yingying; Li, Zhongpeng; Zhou, Chuliang; Leng, Yuxin; Song, Liwei; Tian, Ye; Li, Ruxin

doi:10.1109/jphot.2022.3140872

Cited by 15 publications

(7 citation statements)

References 37 publications

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“…For the above parameters the pulse given by ( 9) is nearly a single cycle pulse. Such pulse shapes are rather typical for modern experiments [23,33,34]. Also, it is important that the plasma channel radius is much greater than the seed THz pulse wavelength λ = 2πc/ω 0 .…”

Section: D Modelmentioning

confidence: 96%

“…At present, a number of methods to produce subcycle unipolar pulse in different frequency ranges from THz to UV have been proposed [1][2][3][4][18][19][20][21][22][23][24]. In particular, in [22], the possibility to transform the single-cycle THz pulse to the unipolar one during the process of its propagation in the extended nonequilibrium xenon plasma channel with a peak-like electron velocity distribution function (EVDF) was demonstrated.…”

Section: Introductionmentioning

confidence: 99%

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On the Possibility of Intense Unipolar THz Pulses Formation in Nonhomogeneous Nonequilibrium Nitrogen Plasma Channels

2023

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We developed a 3D, fully self-consistent model for analysis of the ultrashort THz unipolar pulse formation accompanied by its amplification in a nonequilibrium plasma channel induced in nitrogen by a femtosecond UV laser pulse. The model is based on a self-consistent numerical solution of the second-order wave equation in cylindrical geometry and the kinetic Boltzmann equation for the electron velocity distribution function (EVDF) at different points of the spatially inhomogeneous nonequilibrium plasma channel. Rapid relaxation of the electron velocity distribution function in the plasma channel results in the amplification of the leading front of the THz pulse only, while its trailing edge is not amplified or even absorbed, which gives rise to the possibility of the formation of pulses with a high degree of unipolarity. The evolution of the unipolar pulse after its transfer from the channel to open free space is analyzed in detail.

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Section: D Modelmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

On the Possibility of Intense Unipolar THz Pulses Formation in Nonhomogeneous Nonequilibrium Nitrogen Plasma Channels

2023

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“…The electric area of the pulse as an integral of the electric field strength over pulse duration is S T (r) = ˆE (r, t) dt (1) and was first introduced in [1]. Recent progress in ultrashort pulse generation with a broad frequency band [2][3][4][5][6][7] has made the problem of generation and propagation of electromagnetic pulses with nonzero area (or quasiunipolar pulses) in different media again actual. The nonzero value of the electric pulse area means that the pulse contains a static component of the electric field.…”

Section: Introductionmentioning

confidence: 99%

Propagation of electromagnetic pulses with nonzero area in dissipative media

Bogatskaya,

Volkova,

Popov

2023

Laser Phys. Lett.

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The propagation of ultrashort electromagnetic pulses with a nonzero electric area in dielectric and conducting media is studied in the frame of a unidirectional propagation model. General solutions for the electric pulse area are obtained for different types of media with a linear response to the external field. It is shown that the evolution of the electric area of the pulse is dramatically different for conducting and non-conducting media. In the case of dielectrics, where the current induced by an external field arises from the polarization of bound electrons, the electric pulse area is an invariant of pulse propagation in spite of the dissipation process. For media with free charge carriers (plasma or semiconductors), the electric pulse area decreases with time due to Joule heating of the media by the static component of the field.

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“…High-intensity ultrafast laser facilities provide laser pulses with ultra-high peak power within a few femtoseconds to picoseconds, which create unique and extreme laboratory conditions that can accelerate and collide intense beams of elementary particles [1][2][3] , actuate nuclear reactions [4][5][6] , heat matter at conditions found in stars [7,8] or even create matter out of the empty vacuum [9][10][11] . The progress of highintensity ultrafast lasers promotes the development of a wide variety of fields, including high-field laser physics [12,13] , laser ignition devices [14,15] , the generation of hard X-rays [16,17] , atomic physics [18,19] , particle acceleration [1,20] , attosecond science [21,22] and the generation of intense terahertz sources [23][24][25] . Thanks to the development of chirped pulse amplification (CPA) and optical parametric chirped pulse amplification (OPCPA) in recent decades, super-intense ultrashort lasers have been significantly promoted in many laboratories and have aroused the extensive interest of researchers [26,27] .…”

Section: Introductionmentioning

confidence: 99%

Timing fluctuation correction for the front end of a 100-PW laser

Liu

Wang

et al. 2023

High Pow Laser Sci Eng

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The development of high-intensity ultrafast laser facilities provides the possibility to create novel physical phenomena and matter states. The timing fluctuation of the laser pulses is crucial for pump–probe experiments, which is one of the vital means to observe the ultrafast dynamics driven by intense laser pulses. In this paper, we demonstrate the timing fluctuation characterization and control of the front end of a 100-PW laser that is composed of a high-contrast optical parametric amplifier (seed) and a 200-TW optical parametric chirped pulse amplifier (preamplifier). By combining the timing jitter measurement with a feedback system, the laser seed and preamplifier are synchronized to the reference with timing fluctuations of 1.82 and 4.48 fs, respectively. The timing system will be a key prerequisite for the stable operation of 100-PW laser facilities and provide the basis for potential pump–probe experiments performed on the laser.

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Towards High-Repetition-Rate Intense Terahertz Source With Metal Wire-Based Plasma

Cited by 15 publications

References 37 publications

On the Possibility of Intense Unipolar THz Pulses Formation in Nonhomogeneous Nonequilibrium Nitrogen Plasma Channels

On the Possibility of Intense Unipolar THz Pulses Formation in Nonhomogeneous Nonequilibrium Nitrogen Plasma Channels

Propagation of electromagnetic pulses with nonzero area in dissipative media

Timing fluctuation correction for the front end of a 100-PW laser

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