Abstract
Lasers are the pillars of modern photonics and sensing. Recent advances in microlasers have demonstrated its extraordinary lasing characteristics suitable for biosensing. However, most lasers utilized lasing spectrum as a detection signal, which can hardly detect or characterize nanoscale structural changes in microcavity. Here the concept of amplified structured light‐molecule interactions is introduced to monitor tiny bio‐structural changes in a microcavity. Biomimetic liquid crystal droplets with self‐assembled lipid monolayers are sandwiched in a Fabry–Pérot cavity, where subtle protein‐lipid membrane interactions trigger the topological transformation of output vector beams. By exploiting Amyloid β (Aβ)‐lipid membrane interactions as a proof‐of‐concept, it is demonstrated that vector laser beams can be viewed as a topology of complex laser modes and polarization states. The concept of topological‐encoded laser barcodes is therefore developed to reveal dynamic changes of laser modes and Aβ‐lipid interactions with different Aβ assembly structures. The findings demonstrate that the topology of vector beams represents significant features of intracavity nano‐structural dynamics resulted from structured light‐molecule interactions.
Highlights
Because of the lens effect provided by the liquid crystal (LC) droplet,[43] a relatively low lasing threshold of 24.2 μJ mm−2 is obtained, which is comparable to the previous results.[44]
Since the first invention of laser emission-based imaging a few years ago, most studies focused on the generation of laser emission as a detection signal or enhanced resolution approach
FP cavity provides a whole-body interaction between the light and the gain medium, in contrast to the evanescent interaction in ring resonator sensors or gold plasmonic sensors
Summary
Most lasers utilized lasing spectrum as a detection signal, which can hardly detect or characterize nanoscale structural changes in microcavity. By exploiting Amyloid β (Aβ)-lipid ity, subtle changes within the cavity could be detected.[3,4,5,6] Recently, microlasers from bio-integrated systems have demonstrated distinct advantages for biochemical analysis in terms of signal amplification, narrow membrane interactions as a proof-of-concept, it is demonstrated that vector linewidth, and strong intensity, leading to laser beams can be viewed as a topology of complex laser modes and polarization states. In contrast to lasing spectra (longitudinal mode), spatial images derived from transverse laser mode could provide information on the spatial distribution of physical properties and structural changes in microcavities
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