Transverse Magnetic Mode Laser in Photonic Crystal Nanobeam Cavity

TL;DR

This paper reports the first experimental demonstration of a room-temperature transverse magnetic mode laser in a photonic crystal nanobeam cavity with a high Q-factor, achieved through numerical optimization and material engineering.

Contribution

It introduces a novel photonic crystal nanobeam cavity supporting a high-Q TM mode and demonstrates room-temperature lasing in an InGaAsP quantum-well structure.

Findings

Achieved a Q-factor over 1,000,000 for the TM mode.

Observed single TM mode lasing at room temperature.

Optimized cavity design through numerical simulations.

Abstract

We first experimentally demonstrated a transverse magnetic (TM) mode laser in a Photonic crystal (PhC) slab structure at room temperature. This study proposes a PhC nanobeam (NB) cavity to support a high-quality-factor (Q-factor) TM mode. For a large and complete photonic bandgap, the PhC NB structures consist of large air holes in a thick dielectric slab. The PhC NB cavity was optimized numerically for a high-Q-factor TM mode of over 1,000,000 by reducing the radii of the air holes quadratically from the center to the edge of the PhC NB. A single TM mode lasing action was observed in an InGaAsP quantum-well (QW)-embedded optimized PhC NB cavity structure at room temperature via optical pulse pumping, where the QW layer was lightly etched. We believe that the TM mode lasers in PhC NB cavities with a lightly etched QW can be good candidates for a surface plasmon excitation source or a highly sensitive optical sensor.