Electrically reconfigurable extended lasing state in an organic liquid-crystal microcavity

Dmitriy Dovzhenko (1); Luciano Siliano Ricco (2); Krzysztof Sawicki (1); Marcin Muszy\'nski (3); Pavel Kokhanchik (4); Piotr Kapu\'sci\'nski (3); Przemys{\l}aw Morawiak (5); Wiktor Piecek (5); Piotr Nyga (6); Przemys{\l}aw Kula (5); Dmitry Solnyshkov (4; 8); Guillaume Malpuech (4); Helgi Sigur{\dh}sson (2; 3); Jacek Szczytko (3); Simone De Liberato (1; 9) ((1) School of Physics; Astronomy; University of Southampton; Southampton; United Kingdom; (2) Science Institute; University of Iceland; Reykjavik; Iceland; (3) Institute of Experimental Physics; Faculty of Physics; University of Warsaw; Warsaw; Poland; (4) Institut Pascal; Universit\'e Clermont Auvergne; CNRS; Clermont-Ferrand; France; (5) Institute of Applied Physics; Military University of Technology; Warsaw; Poland; (6) Institute of Optoelectronics; Military University of Technology; Warsaw; Poland; (8) Institut Universitaire de France; Paris; France; (9) Istituto di Fotonica e Nanotecnologie; Consiglio Nazionale delle Ricerche (CNR); Milano; Italy)

arXiv:2506.05717·cond-mat.mes-hall·April 27, 2026

Electrically reconfigurable extended lasing state in an organic liquid-crystal microcavity

Dmitriy Dovzhenko (1), Luciano Siliano Ricco (2), Krzysztof Sawicki (1), Marcin Muszy\'nski (3), Pavel Kokhanchik (4), Piotr Kapu\'sci\'nski (3), Przemys{\l}aw Morawiak (5), Wiktor Piecek (5), Piotr Nyga (6), Przemys{\l}aw Kula (5), Dmitry Solnyshkov (4, 8)

PDF

TL;DR

This paper demonstrates room-temperature, electrically reconfigurable lasing states in an organic liquid crystal microcavity, enabling controlled on-chip coherence and interaction between spatially separated lasers in the weak light-matter coupling regime.

Contribution

It introduces an electrically tunable, extended lasing state in an organic liquid crystal microcavity, advancing on-chip coherence control at room temperature.

Findings

01

Achieved electrically controlled in-plane interaction between lasing states.

02

Demonstrated wide-range micro-scale control of near-field and far-field properties.

03

Realized a spin-selective directional coupling regime using photonic spin-orbit interaction.

Abstract

Small-footprint, low-power arrays of coupled coherent emitters with the capability of near- and far-field engineering and coherence control are highly sought after to meet modern nanophotonics evolving needs. Between existing solutions based on vertical-cavity surface-emitting lasers, phase masks in bulk traditional cavity-based systems, and lattices of exciton-polariton condensates, only the strongly light-matter coupled systems were shown to be capable of controlled on-chip interaction between the individual coherent states while often operating at cryogenic temperatures. Here we demonstrate electrically controlled in-plane interaction between optically reconfigurable spatially separated lasing states, operating at room temperature in the weak light-matter coupling regime. We show spatially extended coherent lasing state or "supermode" with wide-range micro-scale control of…

Peer Reviews

No public reviews on file for this paper yet. If you reviewed it on a platform where reviews are public (OpenReview, ICLR, NeurIPS, ICML), you can paste yours below so the community can read it here.

Videos

No videos yet. Explain this paper in a talk, walkthrough, or lecture? Add one.