posted on 2020-10-09, 07:36authored byJani M. Taskinen, Antti J. Moilanen, Heikki Rekola, Kim Kuntze, Arri Priimagi, Päivi Törmä, Tommi K. Hakala
We report on reversible all-optical
emission control and lasing
in plasmonic nanoparticle lattices. By incorporating photochromic
molecules into the liquid gain medium composed of organic fluorescent
molecules, we realize all-optical control over gain and absorption,
the two key parameters associated with both conventional and nanoscale
lasing. We demonstrate reversible photoswitching between two distinct
modes of operation: (1) spontaneous emission to the lattice mode,
characterized by broad emission line width, low emission intensity,
and large angular distribution; and (2) lasing action, characterized
by very narrow (sub-nm) line widths due to the emergence of increased
gain and temporal coherence in the system, approximately 3 orders
of magnitude increase in emission intensity, and narrow 0.7°
angular divergence of the beam. A rate-equation model is employed
to describe the operation of the switchable plasmonic laser. Our results
provide the first demonstration of optically tunable losses in plasmonic
lattice lasers, which is an important milestone for the development
of active plasmonics and paves the way for ultrafast all-optical switching
of plasmonic nanolasers.