Be should be a shallower acceptor in GaN than Mg [6] [7] due to its large electronegativity and the absence of d-electrons [8]. Theoretical calculations suggest that Be behaves as a rather shallow acceptor in GaN [9], with a thermal ionization energy of 60 meV [10]. Nevertheless, experimental evidences point to the introduction of deep levels by Be doping in GaN. Several authors have reported a Be-related deep emission detected by photoluminescence (PL) in Be-doped [11] [12] and Be-implanted GaN [5], probably associated with the formation of complex defects. Salvador et al. [13] observed a broad band centered at 390-420 nm, which is interpreted as a donor-acceptor emission involving Be acceptors, with an ionization energy of 250 meV.
In this work, the optical properties of GaN:Be layers will be analyzed in order to determine the shallow acceptor level and study the generation of deep levels.
7N) standard solid sources were used for Ga and
Be. Samples consist of an AlN buffer layer (500 Å) and a 0.5-1 µm
thick GaN:Be layer grown at 840 °C and 750 °C respectively. The Be
doping level was controlled varying the Be cell temperature (TBe) in
the range of 700-910°C. Secondary ion mass spectroscopy (SIMS)
measurements showed Be concentration increasing over two orders of magnitude in
the TBe range of 700 - 870°C (Figure 1). The scale of Be
concentration is arbitrary, because no SIMS calibration was available for Be in
GaN.PL experiments were carried out in a He closed-cycle cryostat at temperatures between 4 and 300 K. The 334 nm line of an Ar+ laser was used for continuous wave (cw) excitation. Sample luminescence was dispersed by a THR-1000 Jobin-Yvon monochromator and detected by a GaAs photomultiplier. Time resolved PL measurements were performed at 10 K using a frequency doubled Ti-Sapphire laser with 200 fs pulses (peak power ~ 0.2 MW/cm2 ) pumped by a mode-locked Ar+ laser, with a system time resolution of 100 ps.
PL detected electron paramagnetic resonance (PL-EPR) measurements were performed at 1.5 K, with a microwave frequency of 72 GHz (V-band), for higher resolution. The optical excitation was performed with a halogen lamp followed by a monochromator, and the magnetic resonance was measured as a change of the PL intensity detected by a photomultiplier, with amplitude modulation of the microwaves and lock-in techniques.
|
| (1) |
E , and 
are respectively the transition
energy at 0 K, the Einstein temperature and a constant. The values obtained for
these parameters with the best fit are: E(0) = 3.4658 ± 0.0001 eV, 0.171
± 0.007 eV and E = 447 ± 9 K. Calle et al.
observed the FXA recombination at 3.479 eV in relaxed samples grown on Si (111)
[17]. However, in the samples analyzed in this work, the energy position of FXA
is affected by biaxial tensile strain due to thermal expansion mismatch between
GaN and Si [18]. From x-ray diffraction measurements performed in these layers,
a lattice parameter c = 5.1844 Å has been obtained, in agreement with the
results by Chichibu et al. [18].
The variation of the energy position of the emissions with excitation power and temperature has been analyzed to identify the origin of the emission at 3.384 eV. Figure 4 shows the evolution of this transition with increasing temperature in the range 4-60 K. A blueshift of ~ 4 meV is observed. This variation in the energy position corresponds to a rate of ~ k, the Boltzmann constant, consistent with that expected for a donor- acceptor pair recombination (DAP). This dependence with temperature is due to the enhancement of more closely spaced pairs by a higher thermal ionization rate for the donors [19]. The evolution of the energy of the transition at 3.292 eV with increasing temperature is parallel to that described for the DAP band (Figure 3), supporting the identification of this emission as a first order LO phonon replica (DAP-LO).
The evolution of the transition at 3.384 eV with increasing excitation power is depicted in Figure 5. The emission shifts 15 meV to higher energies when increasing the incident excitation power for almost three orders of magnitude (0.02-10 mW), what is consistent with the saturation of distant pairs under increasing excitation expected for a DAP recombination. On the contrary, the emission at 3.466 eV does not shift with excitation power, confirming its excitonic origin (FXA), as previously established.
PL intensity decay measurements also support that the peak at 3.384 eV is a DAP transition. Figure 6 shows a comparison between the luminescence decays of the 3.466 eV emission (FXA) and that of the 3.384 eV peak (DAP). The excitonic emission shows a very fast and exponential decay, with a time constant limited by the system resolution (~100 ps). Conversely, the decay of the DAP luminescence is slow and strongly non exponential, with a life time of 0.2 µs in the region between 200 ns and 500 ns.
Time resolved PL spectra are shown in Figure 7, recorded in several 10 ns periods from the beginning of the decay. The DAP emission and its first LO phonon replica shift to a lower energy (longer wavelength) with time. This red-shift is explained considering the exponential decrease of the transition probability with increasing distance between donor and acceptor. Thus, the recombination of close pairs (higher energy transitions) dominates the emission for short times (0-10 ns). On the contrary, the recombination of distant pairs (lower energy) becomes dominant at longer times (250-260 ns).
All the above results are consistent with the identification of the peak at 3.384 eV with a DAP transition, with the acceptor probably related to substitutional Be. The energy of a DAP transition is given by:
| (2) |
3.492 eV because of the biaxial tensile strain [18], as was
established for the FXA recombination. The coulombic interaction energy can be
estimated as Ecoul 15 meV [19]. Hence, an ionization energy
EA ~ 90 meV is derived for the Be-acceptor. This result is in
agreement with recent theoretical calculations, predicting that Be is a shallow
acceptor in GaN [9], with a thermal ionization energy of 60 meV [10], and it is
very close to the 85 meV calculated by Pödör for the hydrogenic
acceptor in GaN [7]. This conclusion is also supported by the recent work by
Dewsnip et al. [15] where a DAP character related to substitutional Be is
attributed to the 3.384 eV recombination, finding an optical ionization energy
between 90-100 meV for the Be acceptor.
Figure 9 shows the variation of the band position with excitation power. The center of the interferencial pattern envelope of the band shifts about 400 meV to higher energies when increasing the power three orders of magnitude (0.01-10 mW). This blue-shift is much higher than that corresponding to a DAP transition between discrete levels (see Figure 5 for 3.384 eV DAP). This fact points to a transition involving a broad band of deep levels related to Be.
The evolution of this luminescence with increasing temperature is shown in Figure 10. The center of the emission envelope is red-shifted ~ 300 meV for a temperature range of 4-290 K. This shift to lower energies is higher than that observed in Figure 3 for the free exciton recombination, FXA. This behavior also suggests the presence of a band of deep states whose occupation level changes with temperature, rather than a single DAP recombination.
Time resolved PL has also been performed in this spectral region at low temperature (10 K). The time evolution of the intensity at 2.25 eV is shown in Figure 11. The decay is extremely slow and clearly non exponential, with a lifetime of 10 µs for the range 4-10 µs. This result provides additional support for the interpretation of this broad band as produced by deep levels with different lifetimes, making the decay strongly non exponential.
PL-EPR measurements have been carried out in order to obtain more information about the levels involved in this transition. The PL-EPR spectrum shown in Figure 12 was measured via the 2.4-2.5 band. In first order perturbation theory, the deviation of the g factor from the free electron value, ge = 2.0023, is given by the expression:
| (3) |
is the spin-orbit interaction constant, E is the energy of the
perturbed state and E0 is the energy of the fundamental state,
without perturbation effects.
A donor-like resonance with a half width ~ 7 mT was observed at 2.637 T
(Figure 12), with an anisotropic g factor, g|| = 1.955 ±
0.001 and g
= 1.949 ± 0.001 (|| and indicate
magnetic field B being parallel or perpendicular to the c-axis of the layers
respectively). These results are in agreement with those obtained for the
residual donor in undoped MOVPE layers grown on sapphire [20] [21]. On the low
field side of this resonance, there is another peak, with a half width ~ 15
mT and g|| = 1.956 ± 0.001 and g = 1.957
± 0.001 (inset in Figure 12), likely related to a second shallow donor
also involved in the 2.4-2.5 eV luminescence. The resonance at lower magnetic
field (2.57 T), with g = 2.008 ± 0.003, is assigned to an acceptor-like
defect. This resonance does not present any anisotropy, as expected for a deep
acceptor.All the experimental evidences described above suggest a model for the broad emission at 2.4-2.5 eV, that consists of a recombination between shallow residual donors, and a band of deep acceptors at 0.9-1 eV above the valence band.
© 1998 The Materials Research Society
