P.F. Taday, I.V. Bradley, D.D. Arnone, M. Pepper, Using terahertz pulse spectroscopy to study the crystalline structure of a drug: a case study of the polymorphs of ranitidine hydrochloride. J. Pharm. Sci. 92(4), 831–838 (2003)
Article
Google Scholar
D.S. Sitnikov et al., Effects of high intensity non-ionizing terahertz radiation on human skin fibroblasts. Biomed. Opt. Express 12(11), 7122 (2021)
Article
MATH
Google Scholar
D. Crawley, C. Longbottom, V.P. Wallace, B. Cole, D. Arnone, M. Pepper, Three-dimensional terahertz pulse imaging of dental tissue. J. Biomed. Opt. 8(2), 303 (2003)
Article
ADS
Google Scholar
D. Hou et al., Terahertz spectroscopic investigation of human gastric normal and tumor tissues. Phys. Med. Biol. 59(18), 5423–5440 (2014)
Article
MATH
Google Scholar
Q. Wang, S. Hameed, L. Xie, Y. Ying, Non-destructive quality control detection of endogenous contaminations in walnuts using terahertz spectroscopic imaging. J. Food Measurement Character. 14(5), 2453–2460 (2020)
Article
MATH
Google Scholar
A. Kaur, S. Rani, B. Kaur, Ultrasound assisted removal of cadmium ions from wastewater using ionic liquid modified aluminium isopropoxide. Agrochimica 67(1), 91–102 (2023)
Article
MATH
Google Scholar
Y. Takida, K. Nawata, H. Minamide, Security screening system based on terahertz-wave spectroscopic gas detection. Opt. Express 29(2), 2529 (2021)
Article
ADS
MATH
Google Scholar
W. R. Tribe, D. A. Newnham, P. F. Taday, and M. C. Kemp, “Hidden object detection: security applications of terahertz technology R. J. Hwu, Ed., p. 168. (2004)
W. Jiang et al., Terahertz communications and sensing for 6G and beyond: A comprehensive review. IEEE Communications Surveys & Tutorials, (2024)
R.P. Sharma, A. Monika, P. Sharma, P. Chauhan, A. Ji, Interaction of high power laser beam with magnetized plasma and THz generation. Laser Part. Beams 28(4), 531–537 (2010)
Article
ADS
MATH
Google Scholar
L.V. Titova, C.L. Pint, Q. Zhang, R.H. Hauge, J. Kono, F.A. Hegmann, Generation of terahertz radiation by optical excitation of aligned carbon nanotubes. Nano Lett. 15(5), 3267–3272 (2015)
Article
ADS
Google Scholar
J. Singh, S. Rani, H.K. Midha, V. Sharma, V. Thakur, Parametric analysis of THz wave generation efficiency and plasma density using Sinh-Gaussian beams. J. Opt. (2024). https://doi.org/10.1007/s12596-024-01988-7
Article
MATH
Google Scholar
S. Kumar, S. Vij, N. Kant, V. Thakur, Resonant terahertz generation by the interaction of laser beams with magnetized anharmonic carbon nanotube array. Plasmonics 17(1), 381–388 (2022)
Article
MATH
Google Scholar
V. Thakur, N. Kant, S. Kumar, THz field enhancement under the influence of cross-focused laser beams in the m-CNTs. Trends in Sci. 20(6), 5284 (2023)
Article
MATH
Google Scholar
V. Thakur, S. Kumar, Terahertz generation in ripple density hot plasma under the influence of static magnetic field. J. Opt. (2024). https://doi.org/10.1007/s12596-023-01588-x
Article
MATH
Google Scholar
R. Kumar, K. Gopal, D. Singh, S. Singh, Terahertz field generation by beating of mixed profile lasers in under-dense plasma. IEEE Trans. Plasma Sci. 52, 1–9 (2024)
Article
MATH
Google Scholar
K. Gopal, D.N. Gupta, S. Singh, A. Vijay, Terahertz radiation generation from amplitude-modulated laser filament interaction with a magnetized plasma. Modern Phys. Lett. B (2024). https://doi.org/10.1142/S0217984924501926
Article
MathSciNet
MATH
Google Scholar
S. Kumar, N. Kant, V. Thakur, THz generation by self-focused Gaussian laser beam in the array of anharmonic VA-CNTs. Opt. Quantum Electron 55(3), 281 (2023)
Article
MATH
Google Scholar
H.K. Midha, V. Sharma, N. Kant, V. Thakur, Efficient THz generation by Hermite-cosh-Gaussian lasers in plasma with slanting density modulation. J. Opt. (2023). https://doi.org/10.1007/s12596-023-01413-5
Article
MATH
Google Scholar
S. Kumar, V. Thakur, N. Kant, Magnetically enhanced THz generation by self-focusing laser in VA-MCNTs. Phys. Scr. 98(8), 085506 (2023)
Article
ADS
MATH
Google Scholar
S. Kumar, S. Vij, N. Kant, V. Thakur, Nonlinear interaction of amplitude-modulated gaussian laser beam with anharmonic magnetized and rippled CNTs: THz generation. Braz. J. Phys. 53(2), 37 (2023)
Article
ADS
MATH
Google Scholar
M. Kumar, H.S. Song, J. Lee, D. Park, H. Suk, M.S. Hur, Intense multicycle THz pulse generation from laser-produced nanoplasmas. Sci. Rep. 13(1), 4233 (2023)
Article
ADS
Google Scholar
Y. Chen, Y. He, L. Liu, Z. Tian, J. Dai, Interaction of colliding laser pulses with gas plasma for broadband coherent terahertz wave generation. Photonics Res 11(9), 1562 (2023)
Article
MATH
Google Scholar
H.K. Midha, V. Sharma, N. Kant, V. Thakur, Optimizing terahertz emission with Hermite-Gaussian laser beams in collisional slanted up density plasma. J. Opt. (2024). https://doi.org/10.1007/s12596-024-01696-2
Article
MATH
Google Scholar
A.P. Singh, K. Gopal, D.N. Gupta, M. Kundu, P. Varshney, Laser beat-wave interaction with electron–hole plasmas relevant to terahertz field generation. Indian J. Phys. 98(1), 383–389 (2024)
Article
ADS
Google Scholar
Ashish, K. Gopal, S. Singh, and D. N. Gupta, High-intensity laser pulse interaction with a counter propagating electron beam for terahertz field generation in magnetized plasmas Opt Quantum Electron, vol. 55, no. 7, p. 605, (2023)
A.A.M. Choobini, F.M. Aghamir, Variable laser profiles and polarization states in the wave-mixing scheme for the generation of THz radiation in collisional-magnetized clustered-plasma”. Phys Plasmas (2023). https://doi.org/10.1063/5.0173130
Article
MATH
Google Scholar
A.A.M. Choobini, F.M. Aghamir, Generation of high-power terahertz waves in a collisional and magnetized plasma by two-color femtosecond laser beams. IEEE Trans. Plasma Sci. 51(2), 589–597 (2023)
Article
ADS
MATH
Google Scholar
M.R. JafariMilani, THz generation and spatiotemporal variation of two cross-focused Gaussian laser pulses in plasma. Contribut. Plasma Phys. (2024). https://doi.org/10.1002/ctpp.202400001
Article
Google Scholar
V. Sharma, V. Thakur, A comprehensive study of magnetic field-induced modifications in sin-Gaussian pulse-driven laser wakefield acceleration. J. Opt. (2024). https://doi.org/10.1007/s12596-023-01636-6
Article
MATH
Google Scholar
V. Sharma, V. Thakur, Comparative analysis of electron acceleration by Gaussian and cosh-Gaussian laser pulses in homogeneous plasma through laser wakefield acceleration. J. Opt. (2024). https://doi.org/10.1007/s12596-024-01760-x
Article
MATH
Google Scholar
V. Sharma, V. Thakur, Enhanced laser wakefield acceleration utilizing Hermite-Gaussian laser pulses in homogeneous plasma. J. Opt. (2023). https://doi.org/10.1007/s12596-023-01565-4
Article
MATH
Google Scholar
V. Sharma, N. Kant, V. Thakur, Exploring sin-Gaussian laser pulses for efficient electron acceleration in plasma. Opt. Quantum Electron 56(4), 601 (2024)
Article
MATH
Google Scholar
V. Sharma, N. Kant, V. Thakur, Optimizing laser-driven electron acceleration with sinh-squared Gaussian pulses. J. Opt. (2024). https://doi.org/10.1007/s12596-023-01649-1
Article
MATH
Google Scholar
V. Thakur, N. Kant, Resonant second harmonic generation of chirped pulse laser in plasma. Optik (Stuttg) 129, 239–247 (2017)
Article
ADS
MATH
Google Scholar
V. Thakur, N. Kant, Resonant second harmonic generation in plasma under exponential density ramp profile. Optik (Stuttg) 168, 159–164 (2018)
Article
MATH
Google Scholar
M. Singh, D.N. Gupta, Relativistic third-harmonic generation of a laser in a self-sustained magnetized plasma channel. IEEE J. Quantum Electron. 50(6), 491–496 (2014)
Article
ADS
MATH
Google Scholar
H.K. Midha, V. Sharma, N. Kant, V. Thakur, Resonant terahertz radiation by p-polarised chirped laser in hot plasma with slanting density modulation. J. Opt. (2023). https://doi.org/10.1007/s12596-023-01563-6
Article
MATH
留言 (0)