We present a self-mixing intermode-beatnote spectroscopy system, based on a THz quantum cascade laser operating as a frequency comb (FC). The emitted radiation is back-scattered from the tip of a scanning near-field opticalmicroscope (s-SNOM), which allows to exploit the sensitivity of FC phase-coherence to optical feedback to manipulate the frequency, amplitude and linewidth of the intermode FC beatnote. By stabilizing the phase-locked regimes, we demonstrate, for the first time, a FC based hyper-spectral, THz sSNOM nanoscope providing coherent detection of multiple phase-locked modes and mapping of the THz near-field response of materials in the 2.29-3.6 THz range, with noise-equivalentpowers of similar to 400pW/vHz.
Phase-sensitive hyperspectral near-field nanoscope based on self-induced phase locking of terahertz frequency combs
Pistore Valentino;Viti Leonardo;Vitiello Miriam S
2022
Abstract
We present a self-mixing intermode-beatnote spectroscopy system, based on a THz quantum cascade laser operating as a frequency comb (FC). The emitted radiation is back-scattered from the tip of a scanning near-field opticalmicroscope (s-SNOM), which allows to exploit the sensitivity of FC phase-coherence to optical feedback to manipulate the frequency, amplitude and linewidth of the intermode FC beatnote. By stabilizing the phase-locked regimes, we demonstrate, for the first time, a FC based hyper-spectral, THz sSNOM nanoscope providing coherent detection of multiple phase-locked modes and mapping of the THz near-field response of materials in the 2.29-3.6 THz range, with noise-equivalentpowers of similar to 400pW/vHz.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.