1. Introduction
Recombination mechanisms in InGaN/AlGaN/GaN heterostructures are not fully understood in spite of the great progress in the development of GaN-based light-emitting diodes (LEDs). A model of radiative recombination in 2D-structures with band tails caused by potential fluctuations was successfully applied to luminescence spectra of LEDs with single quantum wells (SQW) Reference Nakamura, Senoh, Iwasa, Nakamura and Nagahama[1] Reference Yunovich, Kudryashov, Turkin, Zolina, Manyakhin, Manyakhin, Senoh, Iwasa, Nagahama, Yamada, Zolina and Mukai[2] Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5] and radiative recombination by tunneling was detected at low currents Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6] Reference Kudryashov, Zolina, Turkin, Yunovich, Kovalev and Manyakhin[7] [8].
There is evidence of the fact that phase separation can take place during the growth of InGaN active thin layers (quantum wells). Clusters (quantum dots) with a higher In content may be formed Reference Manyakhin, Kovalev, Kudryashov and Turkin[9]. But no attempts have been reported to describe the spontaneous emission spectra of LEDs using a model of recombination in such clusters.
It was interesting to study details of luminescence spectra of working LEDs recently developed with multiple quantum wells (MQW) [10] Reference Sakai, Koide, Suzuki, Yamaguchi, Yamasaki, Koike, Amano and Akasaki[11] and to compare their properties with those of LEDs with SQWs.
In this work samples of blue and green LEDs with MQW InGaN/GaN active layers [10] Reference Sakai, Koide, Suzuki, Yamaguchi, Yamasaki, Koike, Amano and Akasaki[11] were studied at a wide range of currents. A model of radiative recombination in 2D-structures with band tails is applied to describe the luminescence spectra. Charge and electric field distributions for LEDs with SQWs and MQWs are compared. The mechanisms of recombination in GaN-based MQWs are discussed.
2. Experimental
Blue and green LEDs based on InxGa1-xN/AlyGa1-y/GaN heterostructures were studied [10] Reference Sakai, Koide, Suzuki, Yamaguchi, Yamasaki, Koike, Amano and Akasaki[11]. Structures were grown by MOCVD on sapphire substrates with an AlN buffer layer (30 nm) followed by a base n-GaN: Si layer (4-5 μm). An InxGa1-xN/GaN MQW structure was grown on the base. The number of periods in the MQW varied; samples with 5 periods were chosen for the study; the thickness of each period was less then 8 nm. The upper layer of AlyGa1-yN (50 nm) and a cap layer GaN (0.5 μm) were Mg-doped. The indium content in the wells varied, with x = 0.2-0.4. This value determined the spectral range of the luminescence, blue (x ≈ 0.2) or green (x ≈ 0.4). In order to look at details of the spectra, a wide interval of forward currents J was used (0.1 μA-200 mA); pulsed measurements were used at J>10 mA (50 Hz, 5 μs).
3. Experimental results
3.1 Luminescence spectra of LEDs
Spectra of 10 blue and 10 green LEDs were studied. The room temperature spectral maxima of the blue LEDs at J = 10 mA were hωmax= 2.64-2.67 eV, (λmax = 465-467 nm), and the spectral width was Δ(hω)1/2= 0.21 eV (Δ(λ)1/2= 36-37 nm). The maxima for green LEDs were hωmax= 2.35-2.37 eV, (λmax = 465-467 nm), spectral width Δ(hω)1/2= 0.21 eV (Δ(λ)1/2= 36-37 nm).
Spectra of blue and green LEDs at currents in the range J = 10−7−10−1 A are shown in Figure 1 and Figure 2. The lower currents at which spectra are shown is ≈0.15 μA for blue and ≈0.5 mA for green LEDs. We have not seen room-temperature spectra of GaN-based LEDs at such low currents in the literature. The maxima of the spectra of the blue LEDs move with the current in the range hωmax= 2.57-2.67 eV, in contrast to blue SQW LEDs in which the blue maximum does not shift with the current Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5]. There is no additional band in the yellow-green region moving with the voltage at low currents. Such a band was described as a tunnel band in blue SQW LEDs Reference Kudryashov, Turkin, Yunovich and Yunovich[5] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6] Reference Kudryashov, Zolina, Turkin, Yunovich, Kovalev and Manyakhin[7]. The maxima of the spectra of the green LEDs move in the range hωmax= 2.2-2.45 eV, a wider range than in green SQW LEDs Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5].
The low-energy sides of the spectra have an exponential form I ~ exp(hω/E0). The parameter E0had the value E0 ≈ 50-60 meV, and changed only slightly with the current, as occurred in the spectra of SQW LEDs Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5]. The high-energy sides also have an exponential form, I ~ exp~. The value of E1 was about 40-50 meV, not equal to kT. A new band could be detected (as shoulders, hω=2.7-2.8 eV) on the high-energy tails of the spectra of green LEDs at higher currents (see Figure 2). The value of E1in the high-energy tails of the spectra of blue LEDs was proportional to T in the range T = 220-290 K, E1 = m·kT, m = 1.3-1.6.
3.2 Spectral shift with current and voltage
Spectra of blue LEDs at higher currents are shown in Figure 3 (J = 20-150 mA). The maxima of the spectra at constant (dc) current move to lower energies for J > 40 mA (see Figure 3a). The parameter E1 in the high-energy exponential tails grew with this shift. The maxima of the spectra at pulsed currents (50 Hz, 5 μs) moved to higher energies; the parameter E1 remained unchanged (see Figure 3b). Heating of LEDs at high dc currents may explain these facts. A dependence of hωmax of the energy eV (V-voltage) is shown in Figure 4. In a comparatively wide range of voltage this function is linear, but the slope of the line is << 1, (in contrast with the tunnel band reported in Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6]). Filling of the tail states in the active layer causes this shift.
3.3 Current-voltage characteristics
Current-voltage characteristics J(V) of blue and green LEDs are shown in Figure 5. There is an exponential part at low currents, J < 10−7 A at 300 K, a steep exponential growth in the range V = 2.3-2.7 V, a linear part at higher currents, J > 20 mA. Low currents can be understood as a tunnel component; tunnel currents in these LEDs play some role at J 3-4 orders of magnitude lower than that for SQW-based LEDs Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6] Reference Kudryashov, Zolina, Turkin, Yunovich, Kovalev and Manyakhin[7]; J(V) curves of SQW-based LEDs are shown in Figure 5 for comparison. The difference can be explained as a consequence of a wider active layer of MQW structures.
A good approximation of the J(V) curves for MQW LEDs was made when not only a series resistance Rs at the linear part at higher J was taken into account, but also the quadratic part: J ~ (V-V1)2. The fit of the curve J(V) at J > 0.1 mA by the equation:
is shown in Figure 5. The fitting parameters are φk (contact potential), EJ(EJ=c·kT, c = 1-2), J0 (saturation current), and J1, Rs. One part ~(J/J1)0.5 is sufficient between an exponential (injection) and a linear parts, in the usual working current range J=2-30 mA..
3.4 Quantum efficiency
Dependencies of the integrated intensity Φ(J) and external quantum efficiency ηe(J) = eΦ/J versus J are shown in Figure 6. Measurements of ηe were done by a method described in Reference Domen[12]. The efficiency ηe(J) has a maximum at low currents J≈0.5-1.0 mA, at the start of the steep exponential growth of J(V). The value of ηe goes down logarithmically with J at high currents (linearly with V).
3.5 Distribution of charged centers
The distributions of charged centers in p- regions of MQW and SQW InGaN/AlGaN/GaN p-n- heterostructures are shown in Figure 7 (see the measurement method in Reference Manyakhin, Kovalev, Kudryashov, Turkin and Yunovich[13]). The MQW LEDs space charge is wider than that of SQW LEDs Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Zolina, Kudryashov, Turkin, Yunovich and Nakamura[4] Reference Kudryashov, Turkin, Yunovich and Yunovich[5] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6]; in both cases the width for green LEDs is wider than for blue ones. This fact corresponds to a low probability of tunneling in the MQW LEDs.
It seems that high Mg-doping of p-AlGaN and GaN layers is more difficult for higher In concentration in InGaN active layers.
4. Discussion
4.1 Spectral fit by the model of 2D-density of states with low-energy tails
We describe the spectra with a model previously applied for fitting the spectra of SQW LEDs Reference Nakamura, Senoh, Iwasa, Nakamura and Nagahama[1] Reference Yunovich, Kudryashov, Turkin, Zolina, Manyakhin, Manyakhin, Senoh, Iwasa, Nagahama, Yamada, Zolina and Mukai[2] Reference Kudryashov, Turkin, Yunovich, Zolina and Nakamura[3] Reference Yunovich, Kovalev, Kudryashov, Manyachin, Turkin and Zolina[6]. The model implies that an effective radiative recombination takes place when carriers of both signs are injected into the active layer at voltages on the layer U < V. The value of U is close to φk. Optical transitions at hω are going between states E(c) and E(v) in the tails of the 2D-structure caused by potential fluctuations. A model 2D joint density of states is
an effective energy gap Eg eff is Eg eff= E*c- E*v . The parameter E0 is determined by potential fluctuations. A discussion of possible sources of these fluctuations (well and barrier inhomogeneities, fields due to impurities, or piezoelectric effects) will be published elsewhere.
The spectral intensity I( hω) is proportional to the Fermi-functions of electrons and holes with quasi-Fermi levels Fn, Fp as parameters (details in Ref. Reference Kudryashov, Turkin, Yunovich and Yunovich[5]):
Examples of the fit are shown in Figure 1 and Figure 2; parameters of the fit are summarized in Table 1. It is possible to describe a change of hωmax in a certain range of J by changes of the parameter Fn - the parameters Eg eff, E0 and E1= m·kT may be unchanged. This is evidence of the fact that the mechanism of recombination in the 2D tail-states is not changed.
4.2 Parameters of the approximation
This description is valid only in some range of J. The parameter E1= m·kT changes at higher J. This is caused first of all by heating at J > 10 mA. Curves of approximation are shown in Figures 3a, 3b. It is possible to describe shifts of pulse spectra without changing the parameter E1, and shifts of the dc spectra - without changing the parameter m, supposing a change of temperature T. The low energy shift of spectral maxima at higher J corresponds to the empirical equation of Varshni:
The parameters in this equation are E(0)=3.07 eV; α=12.8·10−4 eV/K; β=1190 K (see Reference Dmitriev and Oruzheinikov[14]).
4.3 Possible origin of the new spectral band
The short wavelength tail changes not only by heating, but also with the current. It depends also on the new spectral band that is clearly seen in the logarithmic scale on the spectra (see Figure 2). We suppose that this band is caused by large-scale inhomogeneities - separation of phases with different content of indium in InxGa1-xN. Models of recombination either in the band tails or quantum dots were examined as an alternative in the discussion at the Tokushima Conference [10]. It seems that our results confirm that both possibilities are realized. The proof of our supposition may be obtained by studying the luminescence of MQWs with microstructures revealed by electron microscopy and SIMS.
4.4 Maximum quantum efficiency
The problem of the maximum ηe versus J is a very important one. It is connected to the number of QWs and to the properties of p-AlGaN layers made by various technologies.
This maximum can be understood as follows. Nonradiative channels of recombination (for example, tunnel recombination) take place at low J. Electrons are filling the active MQW layer by injection. This is the region of maximum ηe. At higher J electrons overflow the active layer and are pulled by an electric field into the i-layer and p-AlGaN (see an analogous model in Reference Soejima, Kuramata and Tanahashi[15]). The quadratic part of the J(V) and the linear dependence ηe(V) show the role of electric field and of a drift component of the current.
5. Conclusions
-
1. Luminescence spectra of LEDs based on InGaN/AlGaN/GaN heterostructures were studied in a wide range of currents, down to J = 10−7 A at room temperature. Filling the tail states in MQWs causes shifts of the spectral maxima with the voltage.
-
2. The model of recombination in a 2D-structure with exponential band tails describes the spectra with good accuracy. A new spectral band was detected; it is supposed that this band can be caused by phases of higher indium concentrations in InGaN QWs.
-
3. The tunnel component of the current is 3-4 orders of magnitude lower than in analogous SQW LEDs. The LEDs have a current component described by a model of double injection of carriers into the i-layers adjacent to the active MQW layer.
-
4. The quantum efficiency has a maximum depending on the current. Overflow of electrons through the active layer can cause lower quantum efficiency at higher currents; an electric field is pulling the carriers into compensated i-layers.
Acknowledgments
Authors are grateful to Dr. M.Koike (Toyoda Gosei Co. Ltd.) for sending LEDs to Moscow University. Two authors (A.E.Y. and V.E.K.) thank International Soros Science Education Program for a financial support.