Abstract
We describe a robust system for laser-driven narrowband terahertz generation with high conversion efficiency in periodically poled Lithium Niobate (PPLN). In the multi-stage terahertz generation system, the pump pulse is recycled after each PPLN stage for further terahertz generation. By out-coupling the terahertz radiation generated in each stage, extra absorption is circumvented and effective interaction length is increased. The separation of the terahertz and optical pulses at each stage is accomplished by an appropriately designed out-coupler. To evaluate the proposed architecture, the governing 2-D coupled wave equations in a cylindrically symmetric geometry are numerically solved using the finite difference method. Compared to the 1-D calculation which cannot capture the self-focusing and diffraction effects, our 2-D numerical method captures the effects of difference frequency generation, self-phase modulation, self-focusing, beam diffraction, dispersion and terahertz absorption. We found that the terahertz generation efficiency can be greatly enhanced by compensating the dispersion of the pump pulse after each stage. With a two-stage system, we predict the generation of a 17.6 mJ terahertz pulse with total conversion efficiency ηtotal = 1.6% at 0.3 THz using a 1.1 J pump laser with a two-lines spectrum centered at 1 μm. The generation efficiency of each stage is above 0.8% with the out-coupling efficiencies above 93.0%.
Highlights
The last decades have seen a surge in research studies on generation and applications of terahertz radiation, which typically refers to electromagnetic waves in the spectral range from 0.1 to 3 THz
We describe a robust system for laser-driven narrowband terahertz generation with high conversion efficiency in periodically poled Lithium Niobate (PPLN)
We suggest compensating the dispersion accumulated in the material of the pump pulse generated at the end of each stage before recycling it to the subsequent PPLN stage in order to enhance the conversion efficiency
Summary
The last decades have seen a surge in research studies on generation and applications of terahertz radiation, which typically refers to electromagnetic waves in the spectral range from 0.1 to 3 THz. Applications like particle accelerations place steep requirements of a few millijoules of single/multi-cycle terahertz pulse energy to enable bunch manipulation in the relativistic regime Such performance is largely contingent on increasing the terahertz generation efficiency towards the percent level and beyond. Large pump electric field strength induces optical breakdown and damage to the material, which limits the achievable terahertz efficiency [41]. Another challenge is introduced by the terahertz absorption of the material. We aim to alleviate these limitations by recycling the optical pump and separating the generated terahertz radiation in a staged approach, before significant terahertz absorption occurs In this multi-stage architecture, consecutive stages utilize the same optical pump pulse. Detailed information about the terahertz spatial profile and terahertz beam combination is presented
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