Abstract
AbstractSemiconductor optoelectronics have contributed tremendously to various aspects of the technological progress in the past. Recently, they also stimulate research in nanophotonics seeking to overcome the inherent limitations of electronic integrated circuits and satisfy the growing demand for faster on‐chip communications. In particular, nanowire (NW) lasers generate coherent light at the nanoscale and meanwhile work consistently at room temperature covering a huge spectral range from the ultraviolet down to the mid‐infrared depending on the NW material. The underlying physics of their electronic and photonic systems are also studied very recently, thus NW lasers become relevant as an emergent tool for a variety of practical applications. In this review, the origins determining the emission wavelength of the device are explained, and approaches toward efficient improvement of the NW laser devices in terms of emission energy tunability are summarized. The optical mode field distribution strongly influences the emission dynamics of the nanolaser device; it will be highlighted how increasing the light–matter interaction in plasmonic type nanolasers causes a significant acceleration of their temporal emission dynamics. Both spectral and temporal tuning will help to solve scientific and engineering challenges forging semiconductor nanowire lasers into powerful tools for nanosensing, nanospectroscopy, and nanotechnology.
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