Yong-Hee Lee, Yongsop Hwang, Min-Kyo Seo, Kwang-Yong Jeong, Ki Soo Kim, Hong Gyu Park, You Shin No, Jeong, Kwang-Yong, No, You-Shin, Hwang, Yongsop, Kim, Ki Soo, Seo, Min-Kyo, Park, Hong-Gyu, and Lee, Yong-Hee
The realization of lasers as small as possible has been one of the long-standing goals of the laser physics and quantum optics communities. Among multitudes of recent small cavities, the one-dimensional nanobeam cavity has been actively investigated as one of the most attractive candidates for effective photon confinement thanks to its simple geometry. However, the current injection into the ultra-small nano-resonator without critically degrading the quality factor remains still unanswered. Here we report an electrically driven, one-dimensional, photonic-well, single-mode, room-temperature nanobeam laser whose footprint approaches the smallest possible value. The small physical volume of ~4.6 × 0.61 × 0.28 μm3 (~8.2(λ n−1)3) was realized through the introduction of a Gaussian-like photonic well made of only 11 air holes. In addition, a low threshold current of ~5 μA was observed from a three-cell nanobeam cavity at room temperature. The simple one-dimensional waveguide nature of the nanobeam enables straightforward integration with other photonic applications such as photonic integrated circuits and quantum information devices., Lasers for on-chip optical technologies should be as small as possible. Here, Jeong et al. achieve room-temperature lasing in an electrically driven nanobeam photonic structure using only 11 holes to confine the light.