Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-23T23:00:35.004Z Has data issue: false hasContentIssue false

GaInN/GaN Multi-Quantum Well Laser Diodes Grown by Low-Pressure Metalorganic Chemical Vapor Deposition

Published online by Cambridge University Press:  13 June 2014

P. Kung
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University
A. Saxler
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University Air Force Research Laboratory, Materials Directorate, Wright-Patterson AFB
D. Walker
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University
A. Rybaltowski
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University
Xiaolong Zhang
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University
J. Diaz
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University
M. Razeghi
Affiliation:
Center for Quantum Devices, Department of Electrical and Computer Engineering, Northwestern University

Abstract

We report the growth, fabrication and characterization of GaInN/GaN multi-quantum well lasers grown on (00·1) sapphire substrates by low pressure metalorganic chemical vapor deposition. The threshold current density of a 1800 μm long cavity length laser was 1.4 kA/cm2 with a threshold voltage of 25 V. These lasers exhibited series resistances of 13 and 14 Ω at 300 and 79 K, respectively.

Type
Research Article
Copyright
Copyright © 1998 Materials Research Society

1 Introduction

Semiconductor laser diodes (LDs) and light emitting diodes (LEDs) emitting in the ultraviolet-to-visible spectral region are important sources of light for practical applications. Of particular importance is the use of short wavelength (λ~400 nm) laser diodes for the optical data storage (compact disk, digital video disk), printing and imaging industry. At present, only a few research groups have reported III-V nitride based laser diodes. Reference Nakamura, Senoh, Nagahama, Iwasa, Yamada, Matsushita, Sugimoto and Kiyoku[1] Reference Akasaki, Sota, Sakai, Tanaka, Koike and Amano[2] Reference Itaya, Onomura, Nishio, Sugiura, Saito, Suzuki, Rennie, Nunoue, Yamamato, Fujimoto, Kokobun, Ohba, Hatakoshi and Ishikawa[3] Reference Kuramata, Domen, Soejima, Horino, Kubota and Tanahashi[4] Reference Bulman, Doverspike, Sheppard, Weeks, Kong, Dieringer, Edmond, Brown, Swindell and Schetzina[5] Reference Mack, Abare, Aizcorbe, Kozodoy, Keller, Mishra, Coldren and DenBaars[6] In this paper, we report the growth, fabrication and characterization of GaInN/GaN multi-quantum well laser diodes emitting at 405 nm.

2 GaInN/GaN multi-quantum wells

The epitaxial layers were grown on (00·1) sapphire substrates by low pressure metalorganic chemical vapor deposition (LP-MOCVD). Details of the growth conditions may be found in Ref. Reference Saxler, Walker, Kung, Zhang, Razeghi, Solomon, Mitchel and Vydyanath[7]. Figure 1 shows the room temperature photoluminescence and optical pumping from a 10 period 33Å Ga0.89In0.11N/66Å GaN multiple quantum well (MQW) structure capped with a thin GaN layer. The photoluminescence measurements were conducted using a 10 mW He-Cd laser. The optical pumping was carried out using a pulsed nitrogen laser (337 nm) with a pulse width of 600 ps and a repetition rate of 6 Hz. Neutral density filters were used to attenuate the optical power. Stimulated emission was collected from a bar with mechanically polished edges and was observed for pumping densities higher than a threshold estimated at 100 kW/cm2. The peak position was 401 nm and its width of ~1 nm was limited by the resolution of the measurement equipment.

Figure 1. Room temperature (a) photoluminescence and (b) stimulated emission from a 10 period 33ÅGa0.89In0.11N / 66ÅGaN MQW.

3 GaInN/GaN multi-quantum well lasers

Figure 2(a) shows a schematic diagram of the laser diodes grown under the same conditions as discussed in the previous section, which consisted of (i) a 3 μm-thick Si-doped GaN (n~ 2×1018 cm−3); (ii) a 10 period 33 Å Ga0.89In0.11N/66 Å GaN multiple quantum wells; and (iii) a 0.25 μm-thick Mg-doped GaN contact layer (p~2×1017cm−3). The wafers were then annealed using rapid thermal annealing (RTA) under nitrogen ambient for 30 seconds at 1000° C to achieve low resistivity p-type GaN:Mg Reference Nakamura, Mukai, Senoh and Iwasa[8], and broad-area lasers with 100-μm wide stripes were fabricated using ECR-RF dry etching. In order to make the n-type contact, the surface of the sample was etched until the underlying n-type GaN layer was exposed as shown in Figure 2(b). Ti/Au and Ni/Au metal contacts were deposited on the n-type and p-type GaN, respectively, using an electron-beam evaporator and were defined by a conventional lift-off process. Mirror facets were mechanically polished for various cavity lengths from 700 μm to 1800 μm. The roughness of the facet surface was in the range of 50 nm. No antireflection or high-reflection coatings were applied on the mirror facets.

Figure 2. (a) Schematic diagram of a 10 period 33Å Ga0.89In0.11N / 66Å GaN MQW laser structure, and (b) Cross-section of a processed broad-area 33Å Ga0.89In0.11N / 66Å GaN MQW laser with 100 μm-wide metal contacts.

Figure 3 shows the room temperature electroluminescence spectrum for increasing injected currents under continuous wave operation. The light was collected from the back of the sample. An intense electroluminescence peak at ~416nm could be observed.

Figure 3. Room temperature continuous wave electroluminescence from a 10 period 33Å Ga0.89In0.11N / 66Å GaN MQW LD.

Figure 4 (a) shows the 79 K photoluminescence of the MQW laser structure. In order to be able to detect photoluminescence from the multi-quantum wells in the laser structures, the top p-type GaN:Mg layer was partially removed by dry etching to allow penetration of the laser beam. The spectrum exhibited a small peak at ~384 nm and an intense peak at 410 nm. The full width at half maximum of the peak at 410 nm is ~11 nm. This width and the presence of two peaks in the spectrum strongly suggests that there is some degree of phase separation in the MQW structure, leading to localized regions -e.g. quantum dots- which are In rich and others regions which are In deficient. Figure 4(b) shows the 79 K electroluminescence spectrum of this laser structure, exhibiting a peak at ~403 nm.

Figure 4. (a) 79 K photoluminescence from a GaInN/GaN MQW and (b) 79 K electroluminescence from a LD with the same active region.

Laser diodes with cavity lengths varying from 700 to 1800 μm were prepared and bonded with indium to copper heatsinks. Light-current characteristics were recorded in pulse operation (pulse width 2-6 μs, repetition rate 200 Hz) using a silicon detector. From the current versus voltage (I-V) curve, the series resistance of the laser (L~ 1800μm) was estimated to be 13 Ω at 300 K (turn-on voltage ~ 3.6V) and 14 Ω (turn on voltage ~ 6V) at 79 K, as shown in Figure 5. When decreasing the sample temperature from 300 to 79 K, the resistivity of the p-type GaN:Mg is expected to increase drastically, by at least two orders of magnitude, as a result of the relatively high activation energy of Mg levels in GaN. Reference Nakayama, Hacke, Khan, Detchprohm, Hiramatsu and Sawaki[9] Reference Kung, Saxler, Walker, Zhang, Lavado, Kim and Razeghi[10] The fact that the series resistance does not increase significantly in these diodes may be directly due to the small thickness of the GaN:Mg layer, to the absence of AlGaN cladding layers or to higher p-type doping of GaN:Mg which results in lower device resistances. Reference Kung, Saxler, Walker, Zhang, Lavado, Kim and Razeghi[10]

Figure 5. Output power versus injection current for a MQW GaInN/GaN 405 nm uncoated diode laser measured at 79 K (pulse operation: 5 μs-200 Hz) with cavity length of 1800 μm and 100 μm-wide aperture. Inset: Current-voltage characteristics of the laser diode with series resistance of 13 Ω at 300 K and 14 Ω at 79 K. Spectrum of the laser diode slightly above threshold.

Figure 5 illustrates the light output power versus injection current of an uncoated 1800 μm-long laser at 79 K. Stimulated emission was observed at currents of 2.5 A, which corresponds to a threshold current density of 1.4 kA/cm2. Because the laser stripes used in this study are 100 μm wide, the lasing action may occur in a filament and the threshold current density may be locally higher than the value measured above. The voltage of this laser at threshold was 25 V. The peak wavelength of the measured lasers was 405 nm at 3.4 A as shown in Figure 5. At currents lower than 4 A, no degradation was observed for these diodes under pulse operation.

Table 1 summarizes the emission wavelengths from the same laser wafer measured at low temperature (79 K) by photoluminescence, electroluminescence and current injection stimulated emission. A good agreement between the electroluminescence and current injection stimulated emission is observed.

Table 1 Emission wavelengths from GaInN/GaN MQW and lasers using different measurement techniques at low temperature (79 K).

The threshold current density for several lasers of different cavity length was measured and the results are summarized in Figure 6. Further measurements of these laser diodes are in progress. Improvements in the performance of these MQW devices are also in progress.

Figure 6. Threshold current density vs. inverse cavity length for 100 μm wide GaInN/GaN MQW lasers at 79 K.

4. Conclusion

In conclusion, GaInN/GaN multi-quantum well lasers were grown on basal plane sapphire substrates by low pressure MOCVD and characterized. Preliminary studies for these devices showed laser operation at 405 nm with a threshold current density of 1.4 kA/cm2 and a threshold voltage of 25 V; series resistance was 13 ω at 300 K and 14 ω at 79 K.

Acknowledgments

The authors would like to acknowledge the permanent support of M. Yoder, Dr. Y.-S.-Park, and Dr. C. Wood from ONR; Dr. L. Lome from BMDO; Dr. A. Husain from DARPA; and Dr. M. Prairie, Dr. G. Witt, Dr. W. Mitchel and Dr. G. Brown from the Air Force. This work was supported by BMDO/ONR contract No. N00014-93-1-0235, and DARPA/ONR contract No. N00014-96-1-0714.

References

Nakamura, S., Senoh, M., Nagahama, S. I., Iwasa, N., Yamada, T., Matsushita, T., Sugimoto, Y., Kiyoku, H., Jpn. J. Appl. Phys. 36, L1059 (1997).CrossRefGoogle Scholar
Akasaki, I., Sota, S., Sakai, ,H, Tanaka, T., Koike, M., Amano, H., Electron. Lett. 32, 1105-1106 (1996).CrossRefGoogle Scholar
Itaya, K., Onomura, M., Nishio, J., Sugiura, L., Saito, S., Suzuki, M., Rennie, J., Nunoue, S., Yamamato, M., Fujimoto, H., Kokobun, Y., Ohba, Y., Hatakoshi, G., Ishikawa, M., Jpn. J. Appl. Phys. 35, l1315-l1317 (1996).CrossRefGoogle Scholar
Kuramata, A, Domen, K, Soejima, R, Horino, K, Kubota, S, Tanahashi, T, Jpn. J. Appl. Phys. 36, L1130 (1997).CrossRefGoogle Scholar
Bulman, G.E., Doverspike, K., Sheppard, S.T., Weeks, T.W., Kong, H.S., Dieringer, H.M., Edmond, J.A., Brown, J.D., Swindell, J.T., Schetzina, J.F., Electron. Lett. 33, 1556-1557 (1997).CrossRefGoogle Scholar
Mack, M.P., Abare, A., Aizcorbe, M., Kozodoy, Peter, Keller, S., Mishra, U. K., Coldren, L., DenBaars, Steven, MRS Internet J. Nitride Semicond. Res. 2, 41 (1997).CrossRefGoogle Scholar
Saxler, D., Walker, P., Kung, A., Zhang, X., Razeghi, M., Solomon, J., Mitchel, W. C., Vydyanath, H. R., Appl. Phys. Lett. 71, 3272 (1997).CrossRefGoogle Scholar
Nakamura, S., Mukai, T., Senoh, M., Iwasa, N., Jpn. J. Appl. Phys. 31, L139-L142 (1992).CrossRefGoogle Scholar
Nakayama, H., Hacke, P., Khan, M. R. H., Detchprohm, T., Hiramatsu, K., Sawaki, N., Jpn. J. Appl. Phys. 35, L282 (1996).CrossRefGoogle Scholar
Kung, P., Saxler, A., Walker, D., Zhang, X., Lavado, R., Kim, K.S., Razeghi, M., Mater. Res. Soc. Symp. Proc. 449, 79-84 (1997).CrossRefGoogle Scholar
Figure 0

Figure 1. Room temperature (a) photoluminescence and (b) stimulated emission from a 10 period 33ÅGa0.89In0.11N / 66ÅGaN MQW.

Figure 1

Figure 2. (a) Schematic diagram of a 10 period 33Å Ga0.89In0.11N / 66Å GaN MQW laser structure, and (b) Cross-section of a processed broad-area 33Å Ga0.89In0.11N / 66Å GaN MQW laser with 100 μm-wide metal contacts.

Figure 2

Figure 3. Room temperature continuous wave electroluminescence from a 10 period 33Å Ga0.89In0.11N / 66Å GaN MQW LD.

Figure 3

Figure 4. (a) 79 K photoluminescence from a GaInN/GaN MQW and (b) 79 K electroluminescence from a LD with the same active region.

Figure 4

Figure 5. Output power versus injection current for a MQW GaInN/GaN 405 nm uncoated diode laser measured at 79 K (pulse operation: 5 μs-200 Hz) with cavity length of 1800 μm and 100 μm-wide aperture. Inset: Current-voltage characteristics of the laser diode with series resistance of 13 Ω at 300 K and 14 Ω at 79 K. Spectrum of the laser diode slightly above threshold.

Figure 5

Table 1 Emission wavelengths from GaInN/GaN MQW and lasers using different measurement techniques at low temperature (79 K).

Figure 6

Figure 6. Threshold current density vs. inverse cavity length for 100 μm wide GaInN/GaN MQW lasers at 79 K.