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Two-dimensional terahertz strong-field spectroscopy reveals wave-mixing processes up to eighth order in a free-running quantum cascade laser, unraveling its sub-cycle gain dynamics and nonlinearities in a regime of negative absorption.
The performance of novel transmissive-detected LSCI was systematically demonstrated through simulation and experiments. With such a simple system, individual vessel-resolution blood flow mapping and monitoring were realized on human hand.
Thermo-optically induced transparency is a versatile implementation of EIT-analogs in an integrated photonic platform, at arbitrary wavelength of interest, room temperature and in a practical, low cost, and scalable system.
The ligand-tailored SnO2 QDs ETL with multi-functional terminal groups in situ refines the buried interfaces with both the perovskite and transparent electrode via enhanced interface binding and perovskite passivation.
Development of a simple yet insightful model to understand the optical behavior of dots-in-host semiconductors. Unprecedentedly shown that quantum-enabled absorption coefficients can reach levels close to that of bulk semiconductors.
Enhancement in local density of optical states arising from the optical anisotropy of hexagonal boron nitride significantly improves the emission rates of plasmons and photons in quantum mechanical tunnel junctions.
A novel three-channel intensified camera capable of imaging Cherenkov emission in full color was developed, allowing for sensitivity to in vivo biological tissue information during radiotherapy.
Mirror-enhanced scanning light-field microscopy (MiSLFM) achieves long-term high-speed 3D imaging at near-isotropic subcellular resolution with a single objective, facilitating native observations of various intracellular and intercellular interactions.
An absolute characterization technique for microscope objectives is presented, working without a calibrated reference element. To achieve this, a reference wave is created by a sub-wavelength object.
The incorporation of plasmonic core-shell nanostructures at the grain boundaries of perovskite films reduces the charge recombination loss through photo-brightening of trap states.