Open Access
Add to BibSonomyAbstract
We analyse the properties of GaAs based quantum dot semiconductor lasers emitting near 1310 nm. The line-width enhancement factor is shown to depend strongly on device temperature, ranging from 1.5 at 20° C to 5 at 50° C. With optical feedback from a distant reflector, devices remained stable at 20° C but displayed a range of instabilities at 50° C, including irregular power drop–outs and periodic pulsations, before entering a chaotic regime. Such dynamical features are unique to quantum dot lasers – quantum well lasers are significantly more unstable under optical feedback making such a clear route to chaos difficult to observe.
©2006 Optical Society of America
1. Introduction
Quantum dot (QD) semiconductor lasers display an interesting hybrid of atomic laser and standard quantum-well (QW) semiconductor laser properties. Single isolated quantum-dots display linewidths at room-temperature limited only by optical phonon lifetimes [1], but quantum-dot ensembles display linewidths on the order of several 10s of meV, very similar to those of QW lasers. An area where atomic lasers and QW lasers differ greatly is that of the phase-amplitude coupling, or α–factor [2]. Atomic lasers posess values near zero at gain peak, while QW lasers have substantial values that dictate significant characteristics of the laser. The nature and magnitude of the α–factor in QD devices is a current topic of discussion in the literature. A range of values has been reported, ranging from very small [3] to “giant” [4], and this has been attributed in part or whole to plasma effects [5] or excited state population [4].
Two technologically important shortcomings of QW lasers governed by their finite α–factors are the spatial instability of filamentation and the temporal instability of coherence collapse. QD lasers have demonstrated reduced filamentation [6] and low sensitivity to optical feedback [7]. This latter property allows QD laser transmitters to operate without the presence of optical isolators. The improved performance of QDs under optical feedback has been linked to an increased damping of the relaxation oscillations and a reduction in the α–factor [8] that can be explained by conventional rate equations [9]. It has also recently been shown that short cavity quantum dot semiconductor lasers that emit from both ground and excited states, can exhibit antiphase low frequency power drop-outs under the influence of optical feedback [10]. This paper will detail the effect of temperature on the α–factor and feedback stability of QDs from 20° C to 50° C. The devices studied in this article lase only in the ground state. We observe that higher temperature increased both the line-width enhancement factor and the feedback sensitivity of the QD devices. In this regime, the laser remained more stable under optical feedback than conventional QWs as it only displayed instabilities at high levels of injection current. In particular noise induced power drop–out events followed by an oscillatory transient whose duration increased with feedback level were observed. As the feedback level increased, a sequence of periodic oscillations at increasing multiples of the round-trip frequency was observed until chaotic behaviour appeared.
2. Device properties
The devices used in this paper were fabricated from a single quantum dot wafer, its active region consisting of a six–fold stack of InAs QDs in a GaAs waveguide, emitting at 1.3 μm. The QD layers were embedded in a strained InGaAs QW (DWELL structure) to improve carrier capture, with optical confinement provided separately by AlGaAs cladding regions. The growth and fabrication techniques are detailed elsewhere [11]. Alpha–factor measurements were performed on 1.5 mm long, 35 μm stripe, gain guided broad-area lasers (BAL) with uncoated facets. The feedback measurements were carried out using uncoated ridge waveguide lasers (RWGL), with ridge widths of 3 μm and cavity lengths of 1.5 mm.
3. Temperature dependence of α
The α–factor was measured using the Hakki-Paoli technique [12], where amplified spontaneous emission (ASE) spectra are recorded as a function of bias below threshold. The BAL were mounted p–side up on a temperature–controlled copper mount and the devices biased in pulsed mode and at low duty cycles to avoid self–heating. The laser output was coupled via an optical isolator to a single mode fibre, which acted as a spatial filter. It has been previously reported for similar devices that α decreased from 3 to 1 as cavity lengths increased from 1 mm to 2 mm [13]. The results obtained for these 1.5 mm long devices are shown on Fig. 1. α is < 2 at 20° C and shows a pronounced increase with temperature to exceed 5 at 50° C. This result is not unexpected, as increasing the temperature decreases the differential gain, in this case by 50%. The differential index increases by about 60%, possibly due to increased non-resonant carrier populations in excited and wetting layer states.
Fig. 1. Measurement of the α–factor at different operating temperatures. There is a sharp increase in the slope at 40° C, and the major part of the change from 2 to 5 occurs between 40° C and 50° C.
4. Room temperature stability with optical feedback
The QD RWG lasers were mounted p-side up on a copper mount giving optical access to both facets. Through this means, the largest range of the feedback parameter may be explored without compromising the detection sensitivity. The external cavity arm comprised a high numerical aperture lens, a high reflectivity mirror and a neutral density filter to control the feedback level. Optimum coupling of light back into the QD laser is achieved by adjusting the lens and mirror so as to minimise laser threshold. Light in the diagnostic arm was coupled through a focussing lens to a multi mode fiber (MMF) via an optical isolator to eliminate spurious feedback effects. The MMF was coupled to a Newport D–30 fast detector and a Newport AD–300 amplified detector to monitor the power spectrum and the time series simultaneously. The D–30 photodiode signal was amplified using a Miteq high gain amplifier. The D–30 had a bandwidth of 14 GHz, the AD–300 a bandwidth of 1 GHz and the Miteq amplifier a bandwidth of 20 GHz and a noise figure of 3.5 dB. The electronic spectrum and time series were analysed with a 26 GHz Ad–vantest R3172 electronic spectrum analyser (ESA) and a 6 GHz LeCroy real–time oscilloscope respectively. The length of the feedback arm was varied from 40 to 80 cm to obtain various external cavity round–trip times. The threshold current reduction of the device with feedback was measured using a linear gain approximation, similar to that used by Olsson, [14]. The feedback strength, fext , could then be calculated using a simple analytical expression relating fext to the effective reflectivity of the external cavity, Reff,
where R 2 corresponds to the reflectivity of the solitary laser facet in the external cavity arm. A threshold current of 35 mA at room temperature was measured for the free–running laser (this reduced to 28 mA at maximum levels of feedback for all external cavity lengths). For a temperature of 50° C, the free–running threshold increased to 67 mA, with a corresponding threshold redction of 9 mA for maximum feedback. Over the entire feedback range accessed (-13 to -5 dB), and for all external cavity lengths, no fluctuations distinguishable from detector noise were visible on the 6 GHz oscilloscope. The ESA offers more sensitivity as it does not integrate the noise over the frequency spectrum. For very low feedback levels, the power spectra were similar to those obtained for the free–running laser. At higher levels of feedback, the power spectra exhibited a series of peaks corresponding to the external cavity modes. This indicates multiple external cavity mode operation, but the amplitude of the side modes remained smaller than the noise level of our oscilloscope as no periodic oscillations were detected in the time domain.
5. Instability with optical feedback at 50°C
As the temperature of the device was increased from 20 to 50° C, the threshold for the onset of instabilities decreased, and more complex dynamical features were observed at high injection current, typically in the range 2–3Ith. Let us discuss the most typical dynamical regimes: power dropouts, hysteresis and bistability between periodic oscillations and steady state, and higher order instabilities which were observed in several devices.
Power dropouts were observed at a feedback level fext = -13 dB. The laser displayed infrequent, irregular dropouts, an example of which is shown in Fig. 2(b). Here the output power drops to the solitary laser power followed by a number of oscillations at the external cavity round-trip time. These drop-out events were extremely rare, with interburst intervals on the order of ms, a timescale which is much longer than any intrinsic timescale in the system. The power spectrum displayed a small peak at a frequency ν1, slightly lower than the external cavity frequency νext = c/(2L), Fig. 2(a). Experiments at different external cavity lengths (L) yielded different values for ν1; L = 40, 60 and 80 cm resulted in ν1 = 305, 215 and 166 MHz respectively. The power spectrum did not exhibit fluctuations at multiples of the external cavity frequency (Fig. 2(a)) and there was no other manifestation of multiple external cavity modes. The origin of ν1 could be related to the relaxation oscillation frequency of the compound cavity. The clarification of this question requires further experimental and theoretical work that will be reported later.
As the feedback level was increased at fixed current, the frequency and duration of these dropouts increased, leading to the appearance of frequencies at νext , 2νext… in the power spectrum together with ν1. Each dropout was followed by an oscillatory transient whose duration increased with feedback level until it finally became a stable periodic oscillation. This occured at a feedback level fext = -11 dB. The frequency ν1 was no longer present in the power spectrum which consisted of νext and its harmonics, Fig. 3(a).
Fig. 2. (a) Power spectrum for low feedback levels, fext = -13 dB, where a small peak at frequency ν1 is observed and (b) the corresponding time series with a noise–induced dropout event for a pump current of 190 mA at 50°C and an external cavity of 40 cm
Fig. 3. (a) Periodic features observed in the power spectrum for fext = -11 dB and (b) the corresponding time series with periodic oscillations at the round-trip frequency for I=190 mA, L=40 cm and T=50°C
A hysteresis loop was observed when the current at this feedback level was varied, as shown on Figure 4. We found that there was a bistability between the stable steady state operation and the periodic oscillations at νext0 as indicated in the figure.
Fig. 4. Hysteresis loop observed at a fixed feedback level fext=-11 dB for an operating temperature of 50°
Higher order instabilities were observed for a feedback level above fext = - 11 dB and for L = 40 cm. The frequency of the regular oscillations changed abruptly from νext to 2νext. A similar transition to higher frequency (3νext) was observed at a higher feedback level, fext = -10 dB, (Fig. 5(a), 5(b)), before the laser exhibited chaotic behaviour for a maximum feedback level (fext = -5 dB), Fig. 6(a), 6(b).
Extending the external cavity length lead to a remarkable increase in the number of observable harmonics before the appearance of chaos. For an external cavity of 40 cm, (νext = 355 MHz), periodic oscillations up to 3νext (≃ 1 GHz) were observed before the laser entered a chaotic regime. For a 60 cm cavity, periodic oscillations up to and including 5 νext (≃ 1.2 GHz) were observed, while for an 80 cm external cavity, periodic oscillations up to and including 7 νext (≃1.3 GHz) were seen. The frequency ν1 was not present in the sequence of higher harmonics nνext. The observation of the ordered sequence 3νext,4νext, …7νext before chaos is a unique feature of QDs and has not been observed for QW devices subjected to optical feedback.
The feedback-induced instabilities presented here differ significantly from those ordinarily observed in QW semiconductor lasers. For these devices low frequency power drop-outs are commonly observed. In the case of the quantum dot devices investigated in this paper, such low frequency drop-out events were not present but instead the dynamical regimes described above were observed. The absence of low frequency fluctuations in our devices can be explained by strong damping of the relaxation oscillations preventing drift between the external cavity modes. For this reason quantum dot devices display different instabilities to those previously reported in quantum wells.
Fig. 5. (a) Power spectrum showing the appearance of higher harmonics and (b) time series for fext = -10 dB, both at a pump current of 190 mA, temperature of 50°C and 40 cm external cavity
Fig. 6. (a) Power spectrum showing broadened peaks and (b) time series exhibiting chaotic behaviour for maximum current (190 mA) at 50°C, and feedback levels (fext = -5 dB) for an external cavity length of 40 cm
6. Discussion
We have analysed the dynamics of a quantum dot semiconductor laser subjected to optical feedback as a function of operating temperature. We have shown that the α–factor increases with device temperature, most likely due to increased occupancy in non-resonant states. We have also seen that the device was more unstable at a temperature of 50° C, where it operated with a higher value for α. However, these dynamics were only observed for temperatures of 50° C and at high injection currents (typically 2-3Ith), so that the overall device stability remains very good. The specifics of the route to chaos are dependent on the external cavity length, with longer external cavities introducing higher order dynamics into the laser system. Such behaviour has, to our knowledge, not been observed in QW lasers, most likely because these devices have a larger alpha-factor and a lower relaxation oscillation damping rate. The superior stability of QD lasers under optical feedback enables us to observe the progressive development of instabilities, thereby identifying distinctive operating regimes unseen in QWs.
Acknowledgments
We gratefully acknowledge Brian Corbett for the fabrication of the devices and Zia Laser for wafer supply. This study has been supported by Science Foundation Ireland (SFI) under contract number SFI/01/FI/CO13, through the National Access Programme and the Irish Higher Education Authority under the PRTLI program. The work in Brussels was supported in part by the Fonds National de la Recherche Scientifique and by the Interuniversity Attraction Pole Program - Belgian Science Policy.
References and links
1. M. Bayer and A. Forchel, “Temperature dependence of the exciton homogeneous linewidth in In0.6Ga0.4As/GaAs self-assembled quantum dots,” Phys. Rev. B , 65, 041308 (2002). [CrossRef]
2. C.H. Henry, “Theory of the linewidth of semiconductor lasers,” IEEE J. Quantum Electron. 18, 259 (1982). [CrossRef]
3. T.C. Newell, D.J. Bossart, A. Stintz, B. Fuchs, and K.J. Malloy, “Gain and linewidth enhancement factor in InAs quantum-dot laser diodes,” IEEE Photon. Technol. Lett. 11, (12), 1527–29 (1999). [CrossRef]
4. B. Dagens, A. Markus, J.X. Chen, J.-G. Provost, D. Make, O. Le Gouezigou, J. Landreau, A. Fiore, and B. Thedrez, “Giant linewidth enhancement factor and purely frequency modulated emission from quantum dot lasers,” Electron. Lett. 41, 323 (2005). [CrossRef]
5. S.P. Hegarty, B. Corbett, J.G. McInerney, and G. Huyet, “Free-carrier effect on index change in 1.3 μm quantum-dot lasers,” Electron. Lett. , 95 (2005).
6. C. Ribbat, R.L. Sellin, I. Kaiander, F. Hopfer, N.N. Ledentsov, D. Bimberg, A.R. Kovsh, V.M. Ustinov, A.E. Zhukov, and M.V. Maximov, “Complete suppression of filamentation and superior beam quality in quantum-dot lasers,” Appl. Phys. Lett. 82, 952 (2003). [CrossRef]
7. D. O’Brien, S.P. Hegarty, G. Huyet, J.G. McInerney, T. Kettler, M. Laemmlin, D. Bimberg, V.M. Ustinov, A.E. Zhukov, S.S. Mikhrin, and A.R. Kovsh, “Feedback sensitivity of 1.3 μm InAs/GaAs quantum dot lasers,” Electron. Lett. 39, 1819 (2003). [CrossRef]
8. D. O’Brien, S.P. Hegarty, G. Huyet, and A.V. Uskov, “Sensitivity of quantum dot semiconductor lasers to optical feedback,” Opt. Lett. 29, 1072 (2004). [CrossRef] [PubMed]
9. J. Helms and K. Petermann, “A simple analytic expression for the stable operation range of laser diodes with optical feedback,” IEEE J. Quantum Electron. 26, 833 (1990). [CrossRef]
10. E.A. Viktorov, P. Mandel, I. O’Driscoll, O. Carroll, G. Huyet, J. Houlihan, and Y. Tanguy, “Low-frequency fluctuations in two-state quantum dot lasers,” Opt. Lett. 31, 2302 (2006). [CrossRef] [PubMed]
11. L. F. Lester, A. Stintz, H. Li, T. C. Newell, E. A. Pease, B. A. Fuchs, and K. J. Malloy, “Optical characteristics of 1.24 μm InAs quantum-dot laser diodes,” IEEE Photon. Technol. Lett. 11, (8), 931–933 (1999). [CrossRef]
12. B.W. Hakki and T.L. Paoli, “CW degradation at 300K of GaAs double-heterostructure junction lasers. II. Electronic gain,” J. Appl. Phys. 44, 4113 (1973). [CrossRef]
13. J. Muszalski, J. Houlihan, G. Huyet, and B. Corbett, “Measurement of linewidth enhancement factor of self- assembled quantum dot semiconductor lasers emitting at 1310 nm,” Electron. Lett. 40, 128 (2004). [CrossRef]
14. A. Olsson and C.L. Tang, “Coherent optical interference effects in external-cavity semiconductor lasers,” IEEE J. Quantum Electron. , 17, 1320 (1981). [CrossRef]
15. C. Risch and C. Voumard, “Self-pulsation in the output intensity and spectrum of GaAs-AlGaAs cw diode lasers coupled to a frequency-selective external optical cavity,” J. Appl. Phys. , 48, 2083–2085 (1977). [CrossRef]
16. G. Huyet, S.P. Hegarty, M. Giudici, B. de Bruyn, and J.G. McInerney, “Statistical properties of the dynamics of semiconductor lasers with optical feedback,” Europhys. Lett. 40, 619 (1997). [CrossRef]
