We have developed a versatile near-field microscopy platform that can operate at high magnetic fields and below liquid-helium temperatures. This configuration covers a large spectral bandwidth, extending up to 6.5 THz, and increases the spectral intensity by more than 400 times around 3 THz. The concept relies on a phase grating etched at the surface of both the THz generation and detection crystals. A broadband and high‐sensitivity time‐resolved terahertz (THz) system is demonstrated. This system is compared to a standard collinear scheme based on thin (0.2 mm) crystals and, while both systems provide access to a spectral bandwidth extending up to 6.5 THz, it is found that the noncollinear configuration improves the THz signal by more than a factor of 400 and the dynamic range of the system by 30 dB at a frequency of 3 THz. The concept relies on a pair of thick (2 mm) GaP crystals with a phase grating etched on their surface to achieve phase matching between a diffracted near‐infrared pulse and a THz wave propagating at normal incidence. This noncollinear scheme enables a higher THz generation and detection efficiency in nonlinear crystals.
A broadband and sensitive time‐resolved terahertz (THz) configuration relying on noncollinear optical interactions is presented.
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