Dye stabilization and wavelength tunability in lasing fibers based on DNA

TL;DR

This paper demonstrates wavelength-tunable DNA nanofiber lasers with enhanced emission, achieved through morphological control and a detailed understanding of the physico-chemical mechanisms, including DNA-dye interactions and waveguiding effects.

Contribution

It introduces a novel DNA nanofiber laser system with tunable wavelengths and elucidates the physico-chemical mechanisms behind fluorescence enhancement and lasing.

Findings

DNA-dye interaction hinders non-radiative decay

Morphology controls optical properties and lasing

Design rules for DNA-based nanolasers are established

Abstract

Lasers based on biological materials are attracting an increasing interest in view of their use in integrated and transient photonics. DNA as optical biopolymer in combination with highly-emissive dyes has been reported to have excellent potential in this respect, however achieving miniaturized lasing systems based on solid-state DNA shaped in different geometries to confine and enhance emission is still a challenge, and physico-chemical mechanisms originating fluorescence enhancement are not fully understood. Herein, a class of wavelength-tunable lasers based on DNA nanofibers is demonstrated, for which optical properties are highly controlled through the system morphology. A synergistic effect is highlighted at the basis of lasing action. Through a quantum chemical investigation, we show that the interaction of DNA with the encapsulated dye leads to hindered twisting and suppressed channels for the non-radiative decay. This is combined with effective waveguiding, optical gain, and tailored mode confinement to promote morphologically-controlled lasing in DNA-based nanofibers. The results establish design rules for the development of bright and tunable nanolasers and optical networks based on DNA nanostructures.