Related papers: Quantum Squeezing Enhanced Photothermal Microscopy

Quantum Squeezing Enhanced Photothermal Microscopy

URL: http://arxiv.org/abs/2601.20632v1
Date: Wed, 28 Jan 2026 14:13:15 GMT
Title: Quantum Squeezing Enhanced Photothermal Microscopy
Authors: Pengcheng Fu, Xiao Liu, Siming Wang, Nan Li, Chenran Xu, Han Cai, Huizhu Hu, Vladislav V. Yakovlev, Xu Liu, Shi-Yao Zhu, Xingqi Xu, Delong Zhang, Da-Wei Wang,
Abstract summary: squeezing-enhanced photothermal microscopy (SEPT) achieves 3.5 dB noise suppression beyond the standard quantum limit.<n>SEPT establishes a new paradigm for molecular absorption imaging with far-reaching implications in cellular biology, nanoscience, and materials characterization.
Score: 19.35465268779723
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Label-free optical microscopy through absorption or scattering spectroscopy provides fundamental insights across biology and materials science, yet its sensitivity remains fundamentally limited by photon shot noise. While recent demonstrations of quantum nonlinear microscopy show sub-shot-limited sensitivity, they are intrinsically limited by availability of high peak-power squeezed light sources. Here, we introduce squeezing-enhanced photothermal (SEPT) microscopy, a quantum imaging technique that leverages twin-beam quantum correlations to detect absorption induced signals with unprecedented sensitivity. SEPT achieves 3.5 dB noise suppression beyond the standard quantum limit, enabling a 2.5-fold increase in imaging throughput or 31% reduction in pump power, while providing an unmatched versatility through the intrinsic compatibility between continuous-wave squeezing and photothermal modulation. We showcase SEPT applications by providing high-precision characterization of nanoparticles and revealing subcellular structures, such as cytochrome c, that remain undetectable under shot-noise-limited imaging. By combining label-free contrast, quantum-enhanced sensitivity, and compatibility with existing microscopy platforms, SEPT establishes a new paradigm for molecular absorption imaging with far-reaching implications in cellular biology, nanoscience, and materials characterization.

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