2016
DOI: 10.1364/optica.3.001075
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Highly efficient scalable monolithic semiconductor terahertz pulse source

Abstract: Intense pulses at low terahertz (THz) frequencies of 0.1-2 THz are an enabling tool for constructing compact particle accelerators and for strong-field control of matter. Optical rectification in lithium niobate provided sub-mJ THz pulse energies, but it is challenging to increase it further. Semiconductor sources suffered from low efficiency. Here, a semiconductor (ZnTe) THz source is demonstrated, collinearly pumped at an infrared wavelength beyond the three-photon absorption edge and utilizing a contact gra… Show more

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Cited by 96 publications
(66 citation statements)
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“…A plane-parallel contact-grating THz source with uniform interaction length could be successfully demonstrated in ZnTe [45] (see also Section 2.3), but the realization of a practical (hybrid) contact-grating source in LN so far turned out to be very challenging. Recently, a modified hybrid approach was proposed to provide uniform interaction length across large pump and THz beams.…”
Section: Novel Scalable Conceptsmentioning
confidence: 99%
See 1 more Smart Citation
“…A plane-parallel contact-grating THz source with uniform interaction length could be successfully demonstrated in ZnTe [45] (see also Section 2.3), but the realization of a practical (hybrid) contact-grating source in LN so far turned out to be very challenging. Recently, a modified hybrid approach was proposed to provide uniform interaction length across large pump and THz beams.…”
Section: Novel Scalable Conceptsmentioning
confidence: 99%
“…[12] THz pulse energies on the order of 1 µJ were demonstrated both with OR [44,75] and OPA. [45,46] For this reason, OR in semiconductors is discussed here in more detail. [77] Recent developments indicate that OR will expectedly be scalable to substantially higher, mJ-level energies.…”
Section: Semiconductor Nonlinear Materialsmentioning
confidence: 99%
“…The significantly smaller effective nonlinear coefficient of semiconductors, as compared to that of LN, can be compensated for by a larger effective interaction length, enabled by the much smaller PFT angle. Furthermore, a small tilt angle is very advantageous for the realization of a semiconductor contact-grating THz source with exceptionally favorable energy scaling properties [26,27,31,32]. …”
Section: Resultsmentioning
confidence: 99%
“…An estimation of ( ) THz pulses with as high as 14 μJ energy were generated, 9 × higher than the highest previously reported value for semiconductors [13]. Further increase of the THz pulse energy to the mJ level can be expected by increasing the pump spot size to a few cm and scaling the pump pulse energy to the 100-mJ level, in combination with the scalable monolithic contactgrating technology [26,27,31,32]. Such new THz sources, in combination with novel efficient infrared pump sources in the 1.7 to 2.5 μm wavelength range based, for example, on Holmium laser technology [34][35][36][37], opens new perspectives for THz high-field applications.…”
mentioning
confidence: 76%
“…Ultrafast strong-field science, a rapidly expanding research field, steadily demands higher peak and average power lasers for pumping secondary radiation sources based on non-linear frequency conversion, such as (i) parametric amplifiers based on χ <2> and χ <3> interactions [1,2]; (ii) powerful THz radiation sources relying on optical rectification [3][4][5][6][7] and generation of laser plasma microcurrents [8]; (iii) coherent soft EUV/X-ray generation via higher-order harmonic generation [9]; and (iv) incoherent hard X-ray radiation emerging from K α and K β transitions and bremsstrahlung in strongly excited solid-state targets [10].…”
Section: Introductionmentioning
confidence: 99%