The development of dilute nitride alloys for use in mid-infrared diode lasers operating in the 3-4 μm spectral range is described. The dilute nitrides are found to offer improved temperature stability of the photon emission. This arises from localization effects and reduced non-radiative Auger recombination.
We report the growth of InAsN onto GaAs substrates using nitrogen plasma source molecular beam epitaxy. We describe the spectral properties of InAsN alloys with N-content in the range of 0%–1% and photoluminescence emission in the midinfrared spectral range. The photoluminescence emission of the sample containing 1% N reveals localized energy levels resonant with the conduction band states of InAsN.
We perform a structural and optical characterization of InAs 1−x N x epilayers grown by molecular beam epitaxy on InAs substrates ͑x Շ 2.2%͒. High-resolution x-ray diffraction ͑HRXRD͒ is used to obtain information about the crystal quality and the strain state of the samples and to determine the N content of the films. The composition of two of the samples investigated is also obtained with time-of-flight secondary ion mass spectroscopy ͑ToF-SIMS͒ measurements. The combined analysis of the HRXRD and ToF-SIMS data suggests that the lattice parameter of InAsN might significantly deviate from Vegard's law. Raman scattering and far-infrared reflectivity measurements have been carried out to investigate the incorporation of N into the InAsN alloy. N-related local vibrational modes are detected in the samples with higher N content. The origin of the observed features is discussed. We study the compositional dependence of the room-temperature band gap energy of the InAsN alloy. For this purpose, photoluminescence and optical absorption measurements are presented. The results are analyzed in terms of the band-anticrossing ͑BAC͒ model. We find that the room-temperature coupling parameter for InAsN within the BAC model is C NM = 2.0Ϯ 0.1 eV.
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