Abstract:
Hong-Ou-Mandel (HOM) interference, bunching of two indistinguishable photons on a balanced beam-splitter, has emerged as a promising tool for quantum sensing. There is a need for wide spectral-bandwidth photon pairs (for high-resolution sensing) with high brightness (for fast sensing). Here, the generation of photon-pairs with flexible spectral-bandwidth even using single-frequency, continuous-wave diode laser enabling high-precision, real-time sensing is showed. Using 1-mm-long periodically-poled KTP crystal, degenerate, photon-pairs with spectral-bandwidth of 163.42+-1.68 nm are produced resulting in a HOM-dip width of 4.01+-0.04m to measure a displacement of 60 nm, and sufficiently high brightness to enable the measurement of vibrations with amplitude of 205 +- 0.75 nm and frequency of 8 Hz. Fisher-information (FI) and maximum likelihood estimation enables optical delay measurements as small as 4.97 nm with precision (CramEr-Rao bound) and accuracy of 0.89 and 0.54 nm, respectively, therefore showing HOM sensing capability for real-time, precision-augmented, in-field quantum sensing applications.