Introduction
The development of blue light-emitting diodes (LEDs) [Reference Nakamura, Senoh, Iwasa and Nagahama1] and laser diodes (LDs) [Reference Nakamura, Senoh, Nagahama, Iwasa, Yamada, Matsushita, Kiyoko and Sugimoto2] has focused a great deal of research activity on GaN-based III-V nitrides. The band gaps of In x Ga1−x N alloys cover a wide spectral range, from red (InN) to UV (GaN), making this alloy system ideal for optoelectronic applications [Reference Ponce and Bour3]. The diffusion characteristics of host and impurity atoms in In x Ga1−x N alloys are of considerable interest [Reference McCluskey, Romano, Krusor, Johnson, Suski and Jun4]. In this paper, results from structural and optical studies of In-Ga interdiffusion in InGaN/GaN multiple quantum wells (MQWs) are presented.
While compositional disordering of superlattices within the InAlGaAs materials system has been extensively studied [Reference Chang and Koma5,Reference Hofstetter, Maisenhölder and Zappe6], superlattice disordering in III-nitrides has only recently been observed [Reference McCluskey, Romano, Krusor, Johnson, Suski and Jun4]. The interdiffusion of In and Ga in In x Ga1−x N alloys is complicated by the immiscibility of InN and GaN [Reference Ho and Stringfellow7], which can result in phase separation in thick InGaN layers [Reference Singh, Doppalapudi, Moustakas and Romano8] and MQW structures [Reference McCluskey, Romano, Krusor, Bour, Johnson and Brennan9]. In this study, we have investigated the diffusion of In and Ga in annealed In0.18Ga0.82N/GaN MQW structures. We observe quantum-well superlattice disordering, with no phase separation, for annealing temperatures from 1250 to 1400°C.
Experimental Details
The MQW structures were grown by metalorganic chemical vapor deposition (MOCVD). The structures consist of a 1 μm GaN:Mg layer, a 20 period superlattice of 16 Å In0.18Ga0.82N well / 64 Å GaN barrier, and a 4 μm GaN:Si layer on a sapphire substrate. The thickness of the well plus barrier was determined by the spacing between satellite peaks in the x-ray diffraction (XRD) spectrum. A barrier-to-well thickness ratio of approximately 4:1 was measured with transmission electron microscopy (TEM). The In concentration in the InGaN quantum wells was determined by Rutherford backscattering spectrometry (RBS), by assuming the absence of In within the GaN barriers. Since the In concentration in the barriers is nonzero, however, the estimated In concentration of x = 0.18 should be regarded as an upper bound.
The samples were annealed at temperatures ranging from 1200 to 1400°C in a highpressure furnace [Reference Suski, Jun, Leszczyñski, Teisseyre, Strite, Rockett, Pelzmann, Kamp and Ebeling10]. Pressures of up to 15 kbar were applied, with purified N2 as a pressuretransmitting medium, in order to prevent decomposition of the GaN and InGaN. Pieces of Mg were placed in the high-pressure furnace near the sample to provide a Mg overpressure during annealing. To ensure the quasi-equilibrium conditions for the high-pressure annealing, GaN powder was placed in the crucible. The temperature was increased from room temperature, at a rate of 1800°C/h, until it reached a point ∼100°C below the annealing temperature. At that point, the rate was reduced to 1000°C/h until the annealing temperature was reached. After annealing for 15 min, the temperature was decreased at a rate of 3000°C/h.
To enable optical pumping studies, the top GaN:Mg layer was etched to a thickness of 150 nm by chemically-assisted ion beam etching (CAIBE) after the high-pressure anneal. Optical pumping was performed with a pulsed 337-nm N2 laser with a peak power of 250 kW. The laser light was focused to a 100 μm wide by 4-mm long stripe. The pump beam was attenuated by inserting a variable number of 1-mm thick glass slides between the lenses and the sample. The output of the InGaN/GaN MQW sample was collected by a 30 × microscope objective, focused onto a quartz fiber, and fed into an Oriel spectrometer with a resolution of 1 nm and a grating with 1200 lines/mm. The light was detected by a photodetector array with 1024 elements at the output slit. Intensity versus wavelength data was acquired by collecting light for up to 300 s in order to maximize the signal-to-noise ratio.
Results
X-ray diffraction
The XRD spectra for the as-grown and annealed material are shown in Fig. 1. In the as-grown spectrum, InGaN (0006) satellite diffraction peaks were observed up to the 4th order. The satellite peaks arise from the periodicity of the quantum-well superlattice. The XRD spectrum for material that was annealed at 1200°C for 15 min (not shown) is identical to the as-grown spectrum. After annealing at a temperature of 1250°C for 15 min, the intensities of the 1st, 2nd, and 3rd order peaks were reduced, and the 4th order peak was not detected. The reduction in satellite peak intensity is consistent with interdiffusion of In and Ga in the MQW region, resulting in a broadening of the quantum well profiles. Previous results from XRD and transmission electron microscopy indicated that after annealing at 1400°C for 15 min, the quantum well region was replaced by a relatively uniform InGaN layer [Reference McCluskey, Romano, Krusor, Johnson, Suski and Jun4].
Secondary Ion Mass Spectrometry
The In and Mg concentrations were measured as a function of depth with secondary ion mass spectrometry (SIMS). The depth resolution was limited to ∼500 Å, due to surface roughness, so that the individual quantum wells were not resolved. Before annealing, the Mg concentration is constant to a depth of 1 μm, after which point it sharply decreases to a level below the detection limit (∼1016 cm−3). Compared to Mg, however, In does not show significant diffusion under these annealing conditions [Reference McCluskey, Romano, Krusor, Johnson, Suski and Jun4].
The In-Ga interdiffusion in the MQW region is correlated with the diffusion of Mg. It is possible that the diffusion of Mg enhances the interdiffusion of In and Ga in InGaN/GaN MQWs. Impurity induced disordering was first observed in Zn-diffused AlAs/GaAs superlattices [Reference Laidig, Holonyak, Camras, Hess, Coleman, Dapkus and Bardeen11]. In the case of In x Ga1−x As/GaAs MQW’s with x = 0.15, significant interdiffusion has been observed at temperatures less than 700°C [Reference Laidig, Lee, Chiang, Simpson and Bedair12]. The fact that no interdiffusion is observed in In x Ga1−x N/GaN MQW’s for temperatures below 1300°C is a result of the comparatively low rates of diffusion in the III-V nitrides. Although our results are suggestive of impurity induced disordering, further studies will be required to determine the effect of impurities on the interdiffusion of In and Ga in InGaN.
Spontaneous Emission
Spontaneous emission peaks for as-grown and annealed samples are shown in Fig. 3. The decrease in peak wavelength is consistent with In-Ga interdiffusion, which increases the band gap of the InGaN quantum wells [Reference Chan, Li and Chan13]. The peak intensities of the annealed samples were reduced by a factor of ∼50 with respect to the as-grown samples. To obtain comparable signals, larger pump intensities were used for the annealed material than for the as-grown material. While the as-grown material exhibited lasing for sufficiently high pump intensities, lasing was not observed for the annealed samples. The shift of the spontaneous emission peak is plotted in Fig. 4 for several annealing temperatures.
Conclusions
In conclusion, compositional disordering has been observed in In x Ga1−x N/GaN MQW’s with x = 0.18. This disordering results in a blue shift of the spontaneous emission peak. Similar to the case of Zn-diffusion in AlGaAs, it is conceivable that Mg-diffusion enhances In-Ga interdiffusion in InGaN.
Acknowledgments
The authors are pleased to thank P. Floyd for helpful discussions. The work at Xerox was supported by DARPA MDA972-96-3-0014. The work at Unipress was supported by KBN 7T08A 007 13.