Terahertz radiation generation via beating of Hermite-Cosh-Gaussian laser beams in a plasma: effect of tapered wiggler magnetic field

I. Hosako, N. Sekine, M. Patrashin, S. Saito, K. Fukunaga, Y. Kasai, P. Baron, T. Seta, J. Mendrok, S. Ochiai, H. Yasuda, At the dawn of a new era in terahertz technology. Proc. IEEE 95(8), 1611–1623 (2007)

Article  Google Scholar 

M.C. Hoffmann, K.-L. Yeh, J. Hebling, K. Nelson, Efficient terahertz generation by optical rectification at 1035 nm. Opt. Expr. 15, 11706–11713 (2007)

Article  ADS  Google Scholar 

X. Lü, B. Röben, V. Pistore, K. Biermann, E. Luna, M. Wienold, H.W. Hübers, J.R. Wubs, J.P.H. van Helden, P. Gellie, L. Chrottke, Terahertz quantum-cascade lasers: from design to applications. IEEE Trans. Terahertz Sci. Technol. (2024). https://doi.org/10.1109/TTHZ.2024.3415501

Article  Google Scholar 

S. Lepeshov, A. Gorodetsky, A. Krasnok, E. Rafailov, P. Belov, Enhancement of terahertz photoconductive antenna operation by optical nanoantennas. Laser Photon. Rev. 11(1), 1600199 (2017)

Article  ADS  Google Scholar 

Y. Liu, K. Zhong, A. Wang, M. Zhou, S. Li, L. Gao, Z. Zhang, Optical terahertz sources based on difference frequency generation in nonlinear crystals. Crystals 12(7), 936 (2022)

Article  Google Scholar 

C. Sir Tori, Bridge for the terahertz gap. Nature 417(6885), 132 (2002)

Article  ADS  Google Scholar 

H.A. Hafez, X. Chai, A. Ibrahim, S. Mondal, D. Férachou, X. Ropagnol, T. Ozaki, Intense terahertz radiation and their applications. J. Opt. 18(093004), 48 (2016)

Google Scholar 

M. Gezimati, G. Singh, Advances in terahertz technology for cancer detection applications. Opt. Quant. Electron. 55(2), 151 (2023)

Article  Google Scholar 

H. Tian, G. Huang, F. Xie, W. Fu, X. Yang, THz biosensing applications for clinical laboratories: bottlenecks and strategies. Trac-Trend. Anal. Chem. 163, 117057 (2023)

Article  Google Scholar 

Y. Jiang, G. Li, H. Ge, F. Wang, L. Li, X. Chen, M. Lu, Y. Zhang, Machine learning and application in terahertz technology: a review on achievements and future challenges. IEEE Access. 10, 53761–53776 (2022)

Article  Google Scholar 

M. Danciu, T. Alexa-Stratulat, C. Stefanescu, G. Dodi, B.I. Tamba, C.T. Mihai, G.D. Stanciu, A. Luca, I.A. Spiridon, L.B. Ungureanu, V. Ianole, Terahertz spectroscopy and imaging: a cutting-edge method for diagnosing digestive cancers. J. Mater. 12(9), 1519 (2019)

Article  ADS  Google Scholar 

A.K. Pramanik, H.S. Ghotra, N. Kant, J. Rajput, Efficient electron acceleration by using Hermite-Cosh-Gaussian laser beam in vacuum. Laser Phys. Lett. 19(7), 075301 (2022)

Article  ADS  Google Scholar 

H. Hamster, A. Sullivan, S. Gordon, W. White, R.W. Falcone, Sub picosecond electromagnetic pulses from intense laser-plasma interaction. Phys. Rev. Lett. 71(17), 2725 (1993)

Article  ADS  Google Scholar 

A. Belafhal, M. Ibnchaikh, Propagation properties of Hermite-cosh-Gaussian laser beams. Opt. Commun. 186(4), 269–276 (2000)

Article  ADS  Google Scholar 

S. Yu, H. Guo, X. Fu, W. Hu, Propagation properties of elegant Hermite–cosh-Gaussian laser beams. Opt. Commun. 204(1–6), 59–66 (2002)

Article  ADS  Google Scholar 

A.T. Valkunde, S.D. Patil, B.D. Vhanmore, T.U. Urunkar, K.M. Gavade, M.V. Takale, V.J. Fulari, Analytical investigation on domain of decentered parameter for self-focusing of Hermite-cosh-Gaussian laser beam in collisional plasma. Phys. Plasmas 25(3), 033103 (2018)

Article  ADS  Google Scholar 

K.M. Gavade, T.U. Urunkar, B.D. Vhanmore, A.T. Valkunde, M.V. Takale, S.D. Patil, Self-focusing of Hermite–cosh–Gaussian laser beams in a plasma under a weakly relativistic and ponderomotive regime. J. Appl. Spectrosc. 87, 499–504 (2020)

Article  ADS  Google Scholar 

H. K. Midha, V. Sharma, N. Kant, V. Thakur. Exploring nonlinear effects in terahertz generation with Hermite–Gaussian chirp pulses under static magnetic fields. J. Opt. 1–9 (2024)

H.K. Midha, V. Sharma, N. Kant, V. Thakur, Enhanced THz generation by Hermite-cosh-Gaussian chirped laser in static magnetized plasma. Appl. Phys. B 130(7), 130 (2024)

Article  Google Scholar 

A.K. Malik, H.K. Malik, U. Stroth, Terahertz radiation generation by beating of two spatial-Gaussian lasers in the presence of a static magnetic field. Phys. Rev. E 85(1), 016401 (2012)

Article  ADS  Google Scholar 

V. Thakur, S. Kumar. Terahertz generation in ripple density hot plasma under the influence of static magnetic field. J. Opt. (2024)

A. Mehta, J. Rajput, N. Kant, Effect of frequency-chirped laser pulses on terahertz radiation generation in magnetized plasma. Laser Phys. 29(1), 095405 (2019)

Article  ADS  Google Scholar 

A. Mehta, N. Kant. Terahertz radiation generation driven by the frequency chirped laser pulse in magneto-active plasma. SPIE Proc. In Terahertz, RF, Millimeter, and Submillimeter-Wave Technology and Applications XII 10917, 81–89 (2019)

T.U. Urunkar, S.D. Patil, A.T. Valkunde, B.D. Vhanmore, K.M. Gavade, M.V. Takale, Effect of critical beam radius on self-focusing of cosh-Gaussian laser beams in collisionless magnetized plasma. Commun. Theor. Phys. 70(2), 220 (2018)

Article  ADS  Google Scholar 

T.U. Urunkar, S.D. Patil, A.T. Valkunde, B.D. Vhanmore, K.M. Gavade, M.V. Takale, On the exploration of graphical and analytical investigation of effect of critical beam power on self-focusing of cosh-Gaussian laser beams in collisionless magnetized plasma. Laser Part. Beams 36(2), 254–260 (2018)

Article  ADS  Google Scholar 

B.D. Vhanmore, M.V. Takale, S.D. Patil, Influence of light absorption in the interaction of asymmetric elegant Hermite-cosh-Gaussian laser beams with collisionless magnetized plasma. Phys. Plasmas 27(6), 063104 (2020)

Article  ADS  Google Scholar 

B.D. Vhanmore, A.T. Valkunde, T.U. Urunkar, K.M. Gavade, S.D. Patil, M.V. Takale, Self-focusing of higher-order asymmetric elegant Hermite-cosh-Gaussian laser beams in collisionless magnetized plasma. Eur. Phys. J. D 73, 1–5 (2019)

Article  Google Scholar 

B.D. Vhanmore, S.P. Rajmane, S.D. Patil, S.B. Sadale, M.V. Takale, Dominance of polarization modes and external magnetic field on self-focusing of laser beams in collisionless magnetized plasma. J. Opt. (2024). https://doi.org/10.1007/s12596-024-01920-z

Article  Google Scholar 

B.D. Vhanmore, A.T. Valkunde, T.U. Urunkar, K.M. Gavade, S.D. Patil, M.V. Takale, Self-focusing of asymmetric cosh-Gaussian laser beams in weakly ionized collisional magnetized plasma. AIP Conf. Proc. 2142, 110017 (2019)

Article  Google Scholar 

S.P. Rajmane, B.D. Vhanmore, S.B. Sadale, K.Y. Kandale, S.D. Patil, M.V. Takale, A comparative study of extraordinary and ordinary modes in the presence of external magnetic field in self-focusing of higher-order mode TEM m, n of elegant Hermite–cosh-Gaussian laser beams in collisionless plasma medium. J. Opt. (2024). https://doi.org/10.1007/s12596-024-01731-2

Article  Google Scholar 

H.R. Askari, M. Noroozi, Effect of a wiggler magnetic field and the ponderomotive force on the second harmonic generation in laser-plasma interactions. Turk. J. Phys. 33, 299–310 (2009)

Google Scholar 

M. Abedi-Varaki, Relativistic laser third-harmonic generation from magnetized plasmas under a tapered magnetostatic wiggler. Phys. Plasmas 30, 8 (2023)

Article  Google Scholar 

V. Sharma, V. Thakur, N. Kant, Third harmonic generation of a relativistic self-focusing laser in plasma in the presence of wiggler magnetic field. High Energy Density Phys. 32, 51–55 (2019)

Article  ADS  Google Scholar 

J. Rajput, N. Kant, H. Singh, V. Nanda, Resonant third harmonic generation of a short pulse laser in plasma by applying a wiggler magnetic field. Opt. Commun. 282(23), 4614–4617 (2009)

Article  ADS  Google Scholar 

H. Sharma, H. Jaloree, J. Parashar, Magnetic wiggler-assisted third-harmonic generation of a Gaussian laser pulse in plasma. Turk. J. Phys. 37, 368–374 (2013)

Article  Google Scholar 

S. Vij, N. Kant, V. Thakur, Resonant enhancement of THz radiation through vertically aligned carbon nanotubes array by applying wiggler magnetic field. Plasmonics 14, 1051–1056 (2019)

Article  Google Scholar 

J. Singh, J. Rajput, N. Kant, S. Kumar, Comparative study of inverse free-electron laser interaction based on helical and planar wiggler. Optik 260, 169017 (2022). https://doi.org/10.1016/j.ijleo.2022.169017

Article  Google Scholar 

R. McLaughlin, Q. Chen, A. Corchia, C.M. Ciesla, D.D. Arnone, X.C. Zhang, G.A.C. Jones, E.H. Linfield, M. Pepper, Enhanced coherent terahertz emission from indium arsenide. J. Mod. Opt. 47(11), 1847–1856 (2000)

Article  ADS  Google Scholar 

N. Yugami, T. Higashiguchi, H. Gao, S. Sakai, K. Takahashi, H. Ito, Y. Nishida, T. Katsouleas, Experimental observation of radiation from Cherenkov wakes in a magnetized plasma. Phys. Rev. Lett. 89(6), 065003 (2002)

Article  ADS  Google Scholar 

J. Yoshii, C.H. Lai, T. Katsouleas, C. Joshi, W.B. Mori, Radiation from Cerenkov wakes in a magnetized plasma. Phys. Rev. Lett. 79(21), 4194 (1997)

Article  ADS  Google Scholar 

M. Abedi-Varaki, Effects of the wiggler field on the terahertz radiation generated by intense laser beam in collisionless magnetoplasma. UPB Sci. Bull. A Appl. Math. Phys. 80(2), 289 (2018)

Google Scholar 

M. Abedi-Varaki, M.E. Daraei, Impact of wiggler magnetic field on wakefield generation and electron acceleration by Gaussian, super-Gaussian and Bessel-Gaussian laser pulses propagating in collisionless plasma. J. Plasma Phys. 89(1), 905890114 (2023)

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