Quantum Light Nano-Imaging
Abstract
Entanglement and quantum correlations are central to the physics of quantum materials, yet they have remained notoriously difficult to probe experimentally. Probing these phenomena in solids requires quantum optical probes that operate at the native length and time scales of material excitations, below the diffraction limit of light. Developing the requisite tools has previously been infeasible due to the extremely weak intensities of state-of-the-art quantum light sources and extreme inefficiency of near-field light-matter interactions. In this work, we circumvent these challenges and develop a quantum light scattering-type scanning near-field optical microscope (q-SNOM) that can explore the broad domain of solid-state quantum effects at length scales below the diffraction limit. In its first application, we image in real space the self-interference of single hybrid light-matter quasiparticles in a van der Waals semiconductor, providing a direct nanoscale visualization of the wave-particle duality. We also introduce a polaritonic time-of-flight metrology that exploits the temporal correlations among entangled photons to observe the quasiparticle propagation dynamics with femtosecond resolution. This work sets the stage for nanoscale exploration and control of quantum effects in materials.
Keywords
Cite
@article{arxiv.2605.28987,
title = {Quantum Light Nano-Imaging},
author = {Michael Dapolito and Matthew Fu and Fuyang Tay and Suheng Xu and Yuchen Lin and Neil Hazra and Adam K. Williams and Samuel L. Moore and Rocco A. Vitalone and Jonas Kolker and Thomas Cherradi and Aaron Holman and Thomas P. Darlington and Mark E. Ziffer and Xavier Roy and Sebastian Will and Cory R. Dean and Mengkun Liu and A. J. Millis and Abhay N. Pasupathy and P. J. Schuck and D. N. Basov},
journal= {arXiv preprint arXiv:2605.28987},
year = {2026}
}