1. Introduction
The development of electroluminescent heterostructures based on GaN and III-N ternary compounds has been quite successful over the past three years ( [2] and references therein). The best short wavelength (violet, blue, bluish-green) light-emitting diodes (LEDs) were MOVPE-grown InGaN/AlGaN/GaN multilayers with a thin (25-30 Å) In1-xGaxN active layer. External quantum efficiencies in the 4-9 % range have been achieved Reference Nakamura, Senoh, Iwasa, Nagahama, Yamada and Mukai[1] [2]. The electroluminescence (EL) spectra of InGaN/AlGaN/GaN heterostructures were studied in Reference Nakamura, Senoh, Iwasa, Nagahama, Yamada and Mukai[1], and in the earlier publications of the same group Reference Nakamura, Senoh, Iwasa and Nagahama[3] Reference Nakamura, Mukai and Senoh[4] Reference Nakamura, Mukai and Senoh[5]. In this paper, we report the spectra of the multilayered structures InGaN/AlGaN/GaN with a thin active InGaN layer at currents J=0.01-20mA at temperatures T=200-300K.
A model of the radiative recombination in two dimensional (2D) structures which takes into account potential fluctuations Reference Cingolani, Stolz and Ploog[6] was previously applied to describe photoluminescence spectra of GaAs/AlGaAs multiple quantum wells Reference Vardanyan and Yunovich[7], and is used here to analyze the spectra of GaN 2D LED structures. Optical interference can occur in multilayered structures and we have detected the influence of interference on the spectra of blue-green LEDs. In addition, the spectra of tunnel radiation were detected for the first time in GaN-based structures.
2. Experimental
We have studied LEDs made from structures described in [2]. A GaN buffer layer (≈300 Å) was grown on the sapphire substate followed by an n-GaN:Si (≈5 μm) base and electron emitter layer (barrier for holes). The thin active layer InxGa1−xN was ≈20-30 Å. The In content (x = 0.2-0.43) and thickness of this layer were varied to move the spectra from violet-blue to green. A p-type Al0.1Ga0.9N:Mg (≈100 nm) layer was grown onto the active layer as a hole emitter (barrier for electrons) and the structure was completed by a top-GaN:Mg (≈0.5μm) cap. The ohmic contact metallizations were was Ni-Au (p-type) and Ti-Al (n-type). The device had a mesa structure with an active area S = 350×350 μm2.
EL spectra were recorded on a KSVU-12 spectrometer connected to an x486 PC.
3. Experimental results
3.1 Spectra at room temperature
The luminescence spectra of some LEDs at the room temperature (RT) and J=10 mA are given in Figure 1. The violet-blue and blue LEDs have spectral maxima ωmax = 2.58-2.75 eV, and the green LEDs in the ωmax = 2.38-2.45eV range dependent on the active layer In content (x=0.20-0.25 for the blue and 0.42-0.44 for the green LEDs). The LEDs span the entire visible short wavelength spectrum Reference Nakamura, Senoh, Iwasa, Nagahama, Yamada and Mukai[1] [2]. The spectra of a blue diode at various currents are shown in Figure 2. The exponential decay on both sides of the peak are unchanged over the range of currents plotted (J = 0.3-20 mA). The long wavelength side of the peak is described by an exponent:
Figure 1. Room temperature spectra of blue and green InGaN/AlGaN/GaN LEDs, J=10 mA (Arrows show Emax).
Figure 2. Room temperature spectra of blue InGaN/AlGaN/GaN LED #3 over the current range J = 0.3-20 mA.
The parameter E0 varied in different diodes between E0 = 42-50 meV > kT, and was independent of temperature. The short wavelength side of the peak is described to first approximation by the formula:
with a temperature dependent parameter equal to E1 = 31-34 meV at RT.
3.2 Temperature dependence of spectra
The temperature dependence of spectra at T = 200-300 K for one of blue diodes is shown in Figure 3. The temperature, measured by a termocouple attached to the plastic cap of the LED, was current dependent above 1mA as a result of Joule heating. Therefore measurements were taken at J = 1 mA, where such heating was negligible. The data are bunched roughly in two groups in this temperature interval. The high energy side of the spectra are changing according to (2), the parameter E1 being approximately proprtional to T.
Figure 3. Temperature dependent spectra of blue LED #2 at 1mA.
3.3 Interference structrure
A distinct structure on the spectra could be detected when measurements were done at a spectral resolution better than 1meV. This structure was better resolved when a Gaussian or hyperbolic fitting function is substracted from experimental curves, or if the derivatives of spectra were analysed (see Figure 4). The structure is nearly periodical. This can be understood if the light interference is taken into account. The period of the spectral structure is of the order of several nm. If the interference is localized in a layer having thickness t and a refractive index n, then
Figure 4. Two Gaussian approximation of a blue LED #3 spectrum at RT, J = 10 mA. The lower curve is the difference between the experimental data and the sum of the two Gaussians.
The n-GaN layer of the structure is t = 5.0 ± 0.5 μm. The values of the refractive index n and its dispersion (1 + (λ/n)(dn/dλ)) calculated from (3) for different blue LEDs were 2.48, 2.73, and 3.03. These values correspond to the known refractive index of GaN n = 2.5 to within the limits of the above analysis.
3.4 Dependence of intensity versus current
The integrated radiation intensity of the spectrum was proportional to the intensity at the peak Imax and the full width at half-maximum D(ω)1/2. The D(ω)1/2 values for the blue (D(ω)1/2 = 0.12 - 0.13 eV) and green (D(ω)1/2=0.15-0.16 eV) LEDs were current independent. We therefore were able to determine the current dependence of integrated intensity by merely measuring Imax.
The current dependence Imax(J) was different for blue and green LEDs (see Figure 5 and Figure 6). The linear dependence Imax(J) ~ J is seen in the current range 1 mA < J < 10 mA. For J > 10mA, Joule heating overrides the dependence. The intensity dropps dramatically at currents below 1 mA in the blue diodes, following a Imax(J) ~ J4-5 dependence at RT (see also Figure 2). At lower temperature, the transition between the two regimes occurs at lower current levels (J < 0.1 mA). The green diodes had no such temperature dependence (see Figure 6a).
Figure 5a. Current dependence of Imax at RT for blue LED #5.
Figure 5b. RT J-V curve of blue LED #5.
Figure 6a. Current dependence of Imax at RT for green LED #3.
Figure 6b. RT J-V curve of green LED #3.
The difference in efficiency corresponds to the different J-V characteristics of blue and green diodes (see Figure 5 and Figure 6). The low temperature J(V) of the blue diodes was exponential:
with EJ = 130-140 meV independent of temperature. This can be caused by a tunnel “excess” current which is common for thin p-n-junctions with high electric fields in the space charge region. At higher currents the curve flattens and can be described by a temperature dependent exponent. In this regime, series resistance Rs is limiting the current:
where U is the p-n-junction potential. The green diodes had higher series resistance and the J(V) curve had no tunnel component.
3.5 Tunnel radiative recombination
Tunneling effects in blue LEDs were detected also in the low current EL spectra (see Figure 7). A wide spectral band is seen on the low energy side of the specta with its maximum moving nearly equal to the voltage ωmax ≈ V ≈ U. Analogous spectra were studied in highly doped GaAs, InP and GaSb narrow p-n junctions Reference Yunovich and Ormont[8] Reference Stuchebnikov and Yunovich[9]. It was shown that optical transitions between the tails in the density of states at the band gap edges are caused both by the high electric field at the junction and the fluctuating fields of charge impurities. Now we can conclude that such a situation occurs in GaN based structures characterized by narrow space charge regions and a thin 2D active layer.
Figure 7. Low current RT spectra of blue LED #2 showing tunnel radiative recombination.
4. Discussion
4.1 Energy diagram
Let us analyze the energy diagram of a multilayered structure at forward bias (see Figure 8). There are three main current components in the space charge regions: tunneling, injection and recombination, and only injection and recombination currents in the 2D active layer. The tunneling component can dominate at low currents in highly doped junctions with thin space charge regions. The larger part of the space charge corresponds to the p-Al0.1Ga0.9N:Mg (~100 nm) layer. The space charge width is lower for blue diodes as determined by preliminary capacitance measurements which give values of 25 nm for the blue and 40 nm for green LEDs. We conclude that the difference between the two LED groups is differing concentrations of charge impurities in the p-regions. Tunneling dominates at low currents in blue LEDs. The main part of this component is non-raditive recombination, but another part is the tunnel radiative recombination. Injection and recombination in space charge p-region dominate in green LEDs at low currents. Effective radiative recombination is achieved when both carrier types are injected to the active QW layer. At high currents some of the voltage will drop across the adjacent layers, and some recombination will occur there. This produces the maximum of the quantum efficiency at a given current density. It means that the charge distribution in InGaN/AlGaN/GaN heterostructures is very important for optimizing the efficiency.
Figure 8. Energy diagram of a InGaN/AlGaN/GaN heterostucture under forward bias.
4.2 A model approximation of the main spectral band
The effective energy gap of a doped QW can be estimated by taking into account the dependence of Eg(x,T) for InGaN, shifts of QW levels for electrons and holes (ΔE1c, ΔE1v), shifts due to deformations ΔEP, and shifts due to impurity band tails ΔEA,D:
An estimation of Eg(x,T) was made by taking data from a review Reference Morkoc, Strite, Gao, Lin, Sverdlov and Burns[10]. The parameters ΔE1c+ΔE1v were approximated using standard formulae for levels in rectangular quantum wells Reference Herman[11] and approximate effective masses in InGaN. A model of joint 2D-density of states suggested in Reference Cingolani, Stolz and Ploog[6] and used in Reference Vardanyan and Yunovich[7] to analyze spectra of GaAs/AlGaAs MQWs can be applied to fit the spectral band by the equations:
with fc(hω,kT,Fn) and (1 − fv(hω,kT,Fp)) representing the Fermi functions for states near the effective band edges. One of the fits is shown in Figure 3. The fit is quite successful and the number of parameters is not so high. The parameter E0 depends on the roughness of interfaces, strains, alloy inhomogenities and Coulombic impurity fields.
The exponential decay on the high energy side is described by the exponents
We would like tod iscuss the parameters of this fit in the future.
5. Conclusions
The luminescent spectra of InGaN/InGaN/GaN heterostructures have maxima and exponential decays in the blue and green spectral regions which can be described by taking into account the impurity band tails in the 2D active layer. A model approximation for the spectra is suggested. A periodical structure was detected in the spectra which can be described by interference effects in the GaN base layer.
The dependence of intensity versus current differs for blue and green LEDs. The falloff of the blue LED efficiency at low currents is caused by a non-radiative tunnel component of the current. The tunnel radiative recombination spectra with the maxima moving with the voltage have been detected for the first time in GaN based heterostructures.
Acknowledgments
The authors thank A. N. Kovalev and F. I. Manyachin for measurements of electrical properties of the LEDs and A. E. Kovalev and S. S. Shumilov for help in computer problems.
