Broadband terahertz pulse generation driven by an ultrafast thin-disk laser oscillator

Paradis, Clément; Drs, Jakub; Modsching, Norbert; Razskazovskaya, Olga; Meyer, Frank; Kränkel, Christian; Saraceno, Clara J.; Wittwer, Valentin J.; Südmeyer, Thomas

doi:10.1364/oe.26.026377

Cited by 26 publications

(15 citation statements)

References 38 publications

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“…The measured spectra corresponding to the field-traces extend up to about , limited by the detection bandwidth of the EOS measurement. Due to the limited phase matching, decreasing nonlinear index towards higher frequencies as well as absorption of THz radiation in GaP [3, 28], the detection can not retrieve the full spectrum of the generated radiation. From the simulation depicted in Fig.…”

Section: Resultsmentioning

confidence: 99%

Fiber laser-driven gas plasma-based generation of THz radiation with 50-mW average power

et al. 2019

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We present on THz generation in the two-color gas plasma scheme driven by a high-power, ultrafast fiber laser system. The applied scheme is a promising approach for scaling the THz average power but it has been limited so far by the driving lasers to repetition rates up to 1 kHz. Here, we demonstrate recent results of THz generation operating at a two orders of magnitude higher repetition rate. This results in a unprecedented THz average power of 50 mW. The development of compact, table-top THz sources with high repetition rate and high field strength is crucial for studying nonlinear responses of materials, particle acceleration or faster data acquisition in imaging and spectroscopy.

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Section: Resultsmentioning

confidence: 99%

Fiber laser-driven gas plasma-based generation of THz radiation with 50-mW average power

et al. 2019

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“…Sources based on ytterbium active media occupy an operating range around 1030 nm, restricting the choice of nonlinear crystals suitable for THz generation. Figure 1(a) shows the relationship between the coherence length and the optical pump wavelength for GaP, where we consider the optical group index dispersion from [21] and the THz index from [22]. It is clear to see that for pump wavelengths around 1030 nm, a 1 mm thick crystal will support THz wave generation up to nearly 4 THz because the group index of the pump (n g = 3.31) and the refractive index of the THz wave (n THz ≈ 3.36) in this wavelength region are relatively well matched [22].…”

Section: Theorymentioning

confidence: 99%

“…Here, we adopt a non-depleted, plane-wave pump approximation, account for the frequency dependent Fresnel transmission at each crystal-air interface, assume a transform limited 30 fs input pump and probe pulse, measurement of the generated THz waveform in time using air-biased coherent detection (i.e. a broadband detection scheme that does not impose a spectral response function), and realistic material parameters including the dispersion of the refractive index and absorption in the THz and optical range for GaP [21,22] and for HMQ-TMS [16,17], respectively. It can be seen from Figs.…”

Section: Theorymentioning

confidence: 99%

MHz-repetition-rate, sub-mW, multi-octave THz wave generation in HMQ-TMS

Buchmann¹,

Kelleher²,

Kaltenecker³

et al. 2020

Opt. Express

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We demonstrate the first megahertz (MHz) repetition-rate, broadband terahertz (THz) source based on optical rectification in the organic crystal HMQ-TMS driven by a femtosecond Yb:fibre laser. Pumping at 1035 nm with 30 fs pulses, we achieve few-cycle THz emission with a smooth multi-octave spectrum that extends up to 6 THz at-30 dB, with conversion efficiencies reaching 10 −4 and an average output power of up to 0.38 mW. We assess the thermal damage limit of the crystal and conclude a maximum fluence of ∼1.8 mJ•cm −2 at 10 MHz with a 1/e 2 pump beam diameter of 0.10 mm. We compare the performance of HMQ-TMS with the prototypical inorganic crystal gallium phosphide (GaP), yielding a tenfold electric field increase with a peak on-axis field strength of 7 kV•cm −1 and almost double the THz bandwidth. Our results further demonstrate the suitability of organic crystals in combination with fibre lasers for repetition-rate scaling of broadband, high-power THz sources for time-domain spectroscopic applications.

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“…The green curve demonstrates the results with a thinner crystal, where the phase mismatch frequency cutoff at 7.3 THz is no longer the main limiting factor, and the THz spectrum is mostly limited by the pulse duration of the driving laser. The PM conditions between the IR and THz pulse in GaP were calculated according to [28] based on a Sellmeier fit of the THz refractive indices presented in [19] and a group refractive index for the IR pulse n g = 3.31 calculated from [29] (see Table 1 in Appendix A).…”

Section: Influence Of Pulse Duration and Crystal Thickness On The Thzmentioning

confidence: 99%

“…Recently, we demonstrated the generation of broadband THz radiation with a gap-less spectrum extending to 5 THz at a few microwatts of average power [19]. This was achieved by optical rectification in GaP of 50 fs pulses, delivered by a 4 W TDL oscillator.…”

Section: Introductionmentioning

confidence: 99%

Optical rectification of ultrafast Yb lasers: pushing power and bandwidth of terahertz generation in GaP

et al. 2019

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We demonstrate broadband high-power terahertz (THz) generation at megahertz repetition rates by optical rectification in GaP driven by an ultrafast Yb-based thin-disk laser (TDL) oscillator. We investigate the influence of pulse duration in the range of 50-220 fs and thickness of the GaP crystal on the THz generation. Optimization of these parameters with respect to the broadest spectral bandwidth yields a gap-less THz spectrum extending to nearly 7 THz. We further tailor the driving laser and the THz generation parameters for the highest average power, demonstrating 0.3 mW THz radiation with a spectrum extending to 5 THz. This was achieved using a 0.5 mm thick GaP crystal pumped with a 95 fs, 20 W TDL, operating at 48 MHz repetition rate. We also provide a simple method to estimate the THz spectrum, which can be used for design and optimization of similar THz systems

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Broadband terahertz pulse generation driven by an ultrafast thin-disk laser oscillator

Cited by 26 publications

References 38 publications

Fiber laser-driven gas plasma-based generation of THz radiation with 50-mW average power

Fiber laser-driven gas plasma-based generation of THz radiation with 50-mW average power

MHz-repetition-rate, sub-mW, multi-octave THz wave generation in HMQ-TMS

Optical rectification of ultrafast Yb lasers: pushing power and bandwidth of terahertz generation in GaP

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