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Extreme Terahertz Nonlinearity of AlGaN/GaN-Based Grating-Gate Plasmonic Crystals - Dataset

Version 1.0

Sai, Pavlo, 2025, "Extreme Terahertz Nonlinearity of AlGaN/GaN-Based Grating-Gate Plasmonic Crystals - Dataset", https://doi.org/10.18150/XHXKGG, RepOD, V1

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Description

This is a set of research data related to the article titled "Extreme Terahertz Nonlinearity of AlGaN/GaN-Based Grating-Gate Plasmonic Crystals", Advanced Optical Materials, Pages 2500716, 2025.

The set contains numerical data used to create the next Figures:

Fig.1a: FTIR-measured transmittance spectra of samples S13;

Fig.1b: FTIR-measured transmittance spectra of samples S8;

Fig.2a: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S13 at gate voltage = 0V;

Fig.2b: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S13 at gate voltage = -3.5V;

Fig.2c: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S8 at gate voltage = -0.6V;

Fig.2d: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S8 at gate voltage = -4V;

Fig.3a: Contour plots ofΔT/Tas a function of the gate voltage, VG, and delay time,Δt, for samples S13;

Fig.3b: Contour plots ofΔT/Tas a function of the gate voltage, VG, and delay time,Δt, for samples S8;

Fig.3c: Contour plots of FTIR transmittance (measured in linear regime) as a function of the frequency and gate voltage for the sample S13;

Fig.3d: Contour plots of FTIR transmittance (measured in linear regime) as a function of the frequency and gate voltage for the sample S8;

Fig.4a: Measured time delay dependence of ΔT/T of the sample S13 in the delocalized plasmonic phase at different equilibrium temperatures, T0;

Fig.4b: The peak values of the pump-probe signal. Temperature dependence of ΔT/T peak values are taken at Δt = 0 ps;

Fig.6: Steady-state field dependences of the drift velocity (curves 1a and 2a) and the electron temperature (1b and 2b) for two equilibrium temperatures T0 = 10 K and 150 K, respectively;

Fig.7a: The waveform the incident and transmitted pulses in the time domain is calculated at Emax = 3 kV cm−1, 𝛿t = 16 ps, and 𝜈c = 1.84 THz;

Fig.7b: The corresponding normalized power Fourier spectrum is calculated at a small field, Emax = 0.1 kV cm−1;

Fig.7c-g: The snapshots of the spatial distribution of the magnetic components of the FEL pulse), which interact with the PC structure at different moments;

Fig.8a,d: A spatial distribution of the electric field in the 2DEG plane of one period of the PC;

Fig.8b,e: A spatial distribution of the electron drift velocity in the 2DEG plane of one period of the PC;

Fig.8c,f: A spatial distribution of the electron temperature in the 2DEG plane of one period of the PC;

Fig.9a: The calculated fluence dependences of ΔT/T characteristic at Δt = 0 ps for samples S13;

Fig.9b: The calculated fluence dependences of ΔT/T characteristic at Δt = 0 ps for samples S8.









Subject
Physics
Keyword

AlGaN/GaN, nonlinear plasmonics, plasmonic crystals, THz photonics, THz pump-probe spectroscopy

Related Publication

Sai, P., Korotyeyev, V. V., But, D. B., Dub, M., Yavorskiy, D., Łusakowski, J., Słowikowski, M., Kukhtaruk, S., Liashchuk, Y., Han, J. W., Böttger, C., Pashkin, A., Winnerl, S., Knap, W., Mittendorff, M. Extreme Terahertz Nonlinearity of AlGaN/GaN‐Based Grating‐Gate Plasmonic Crystals. Advanced Optical Materials, p.2500716 (2025). (DOI: https://doi.org/10.1002/adom.202500716) https://doi.org/10.1002/adom.202500716 doi: 10.1002/adom.202500716

CC BY - Creative Commons Attribution 4.0 CC BY - Creative Commons Attribution 4.0

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DataSet.zip
ZIP Archive - 4.1 MB - Sep 26, 2025 - 2 Downloads
MD5: bd8ac5513d3f5a005b85f951c4e45a25
License: CC BY - Creative Commons Attribution 4.0
This is a set of research data related to the article titled "Extreme Terahertz Nonlinearity of AlGaN/GaN-Based Grating-Gate Plasmonic Crystals", Advanced Optical Materials, Pages 2500716, 2025. The set contains numerical data used to create the next Figures: Fig.1a: FTIR-measured transmittance spectra of samples S13; Fig.1b: FTIR-measured transmittance spectra of samples S8; Fig.2a: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S13 at gate voltage = 0V; Fig.2b: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S13 at gate voltage = -3.5V; Fig.2c: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S8 at gate voltage = -0.6V; Fig.2d: The relative pump-induced changes in transmission, ΔT/T, measured at different pump pulse fluencies varied from 1.5 to 350 nJ cm−2 for sample S8 at gate voltage = -4V; Fig.3a: Contour plots ofΔT/Tas a function of the gate voltage, VG, and delay time,Δt, for samples S13; Fig.3b: Contour plots ofΔT/Tas a function of the gate voltage, VG, and delay time,Δt, for samples S8; Fig.3c: Contour plots of FTIR transmittance (measured in linear regime) as a function of the frequency and gate voltage for the sample S13; Fig.3d: Contour plots of FTIR transmittance (measured in linear regime) as a function of the frequency and gate voltage for the sample S8; Fig.4a: Measured time delay dependence of ΔT/T of the sample S13 in the delocalized plasmonic phase at different equilibrium temperatures, T0; Fig.4b: The peak values of the pump-probe signal. Temperature dependence of ΔT/T peak values are taken at Δt = 0 ps; Fig.6: Steady-state field dependences of the drift velocity (curves 1a and 2a) and the electron temperature (1b and 2b) for two equilibrium temperatures T0 = 10 K and 150 K, respectively; Fig.7a: The waveform the incident and transmitted pulses in the time domain is calculated at Emax = 3 kV cm−1, 𝛿t = 16 ps, and 𝜈c = 1.84 THz; Fig.7b: The corresponding normalized power Fourier spectrum is calculated at a small field, Emax = 0.1 kV cm−1; Fig.7c-g: The snapshots of the spatial distribution of the magnetic components of the FEL pulse), which interact with the PC structure at different moments; Fig.8a,d: A spatial distribution of the electric field in the 2DEG plane of one period of the PC; Fig.8b,e: A spatial distribution of the electron drift velocity in the 2DEG plane of one period of the PC; Fig.8c,f: A spatial distribution of the electron temperature in the 2DEG plane of one period of the PC; Fig.9a: The calculated fluence dependences of ΔT/T characteristic at Δt = 0 ps for samples S13; Fig.9b: The calculated fluence dependences of ΔT/T characteristic at Δt = 0 ps for samples S8.
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