1. Introduction
Recent breakthroughs in modern epitaxy techniques have enabled the synthesis of GaN epilayers with improved mobility and reduced residual n-type conductivity. N-type doping can be reproduceably controlled over several decades using Si donors. The absence of an efficient p-type dopant has long hampered the progress of GaN pn junction based device development. Recently, the successful activation of Mg acceptors in the GaN lattice by post growth treatments such as LEEBI Reference Amano, Kito, Hiramatsu and Akasaki[1] or in-situ thermal treatment under nitrogen Reference Nakamura, Mukai, Senoh and Iwasa[2] has enabled great progress in GaN based devices.
Optical spectroscopy techniques have long been recognized as efficient methods of investigating semiconductors and their heterostructures. The Raman method is known to be a sensitive technique, in comparison to photoluminescence or reflectance, for determining strains. It can therefore be used to calibrate, mutatis mutandis, the residual strain in ternary alloy layers such as InGaN, which are important for nitride based heterostructures.
Here, we investigate the strain of heteroepitaxial GaN epilayers. These layers, grown on (0 0 0 1) sapphire substrates using the MOVPE technique, have residual strains present resulting from the lattice and thermal mismatch between the substrate and epilayer. This stress is calibrated using reflectance measurements of the excitonic structure. Next, we determine the deformation potentials for some of the Raman-active phonons in α-GaN epilayers.
2. Stress calibration
Reflectance measurements enable the details of the MOVPE GaN/sapphire valence band structure to be probed. In particular, we relate the exciton energies and their splitting to the residual strain in the layers. The complete nature of the residual strain is not clear at the moment. It is weakly related to the sample thickness, and is rather strongly influenced by the layer’s growth conditions such as the V/III molar ratio.
Taking into account the spin-orbit and wurtzite crystal field interactions, three excitons (A, B and C) are expected, corresponding to the three electronic transitions, Γ7C − Γ9V, Γ7C − (Γ7V) + and Γ7C − (Γ7V)-. Careful examination of reflectance spectra reveals an increase of the A-B and B-C energy splittings with increasing energy of the A exciton which is evidence of residual strain fields in the GaN. When the three excitons are plotted as a function of the fundamental (A) transition energy, a linear variation with different slopes is obtained. In the case of a cubic approximation, and neglecting spin-orbit interaction, we get expressions for these energies as function of stress. The zero stress values are introduced corresponding to strain free situation. After some elementary manipulations of these expressions and using hydrostatic pressure coefficient, a stress calibration is obtained.
3. GaN Phonon Spectra
Wurtzite GaN/sapphire epilayers have symmetry belonging to the C6v4 (P63mc) space group with two formula units per primitive cell. A group theory analysis of q = 0 lattice vibrations predicts six optical modes which decompose into the following representations of the C6v (6mmm) point group: Γopt = A1 + E1 + 2E2 + 2B1. The polar modes, A1and E1 (both infra-red and Raman active), are polarized along the z optical axis and in the basal (x,y) plane, respectively (x,y,z represent the crystal principal axes). Of the non polar lattice vibrations, the E2 modes are Raman active while the B1 modes are not. Obviously, the anisotropic structure of GaN and the ionic character of the crystal bonding have a strong influence on the dynamical properties. The anisotropy in short range atomic forces is thus responsible for the A1-E1 splitting while the long-range Coulomb field causes the longitudinal-transverse (LO-TO) splitting of polar modes. This results in direction dependent frequencies and polarization properties when approaching the limiting q = 0 value along or perpendicular to the optical axis.
The effect of stress on q = 0 phonons in the wurtzite structure was addressed in piezospectroscopic studies of CdS Reference Briggs and Ramdas[3] within the context of a perturbative approach. In the linear approximation, the phenomenological Hamiltonian can be expressed as
where the εij(i,j = x,y,z)is the strain tensor. Rearranging this contracted tensorial product to form combinations of V ij transforming according to the A1, E1, and E2 irreducible representations of the crystal point group leads to the construction of meaningful quantities, i.e. the deformation potentials. The changes in frequency of q = 0 phonons under stress are obtained in first order perturbation theory in terms of deformation potential constants. Under hydrostatic or biaxial ( 0 0 0 1 ) oriented stress, the shifts of the phonon frequencies can be expressed as:
The σii’s are the diagonal components of the stress tensor, with σxx = σzz for the hydrostatic pressure and σzz = 0 for biaxial (0 0 0 1) stress. The coefficients a′J and b′J are expressed in terms of the elastic constants and deformation potential constants as:
and
where aJ represents the change in frequency of phonon J per unit relative change of length along z, and bJ is its counterpart along x.
According to a recent investigation of the optical properties of GaN/sapphire Reference Gil, Briot and Aulombard[4], exciton energies are extremely sensitive to the biaxial compression in the epilayers. The full nature of the residual strains is not yet elucidated. A thermoelastic contribution, originating from the mismatch of the thermal expansion coefficients between the layer and the substrate, is present, but an additionnal strong dependence on growth conditions (more precisely, the V/III molar ratio) was also established Reference Briot, Alexis, Gil and Aulombard[5].
4. Vibrational properties in α-GaN under stress
The q = 0 phonon frequencies were measured by Raman spectroscopy (backscattering configuration) in a series of layers grown under different V/III ratios. Stress calibration for each sample was obtained from reflectance measurements as described above. Values of the biaxial stress coefficient KBJ = dνj/dσ where σ = − σxx, (σ >0 for compression) were estimated from the data. A first relation between the aJ’s and bJ’s, obtained from (3) and (4), can thus be established:
One more relation is needed for the determination of the {aJ, bJ} set of deformation potential constants. It is obtained from the Raman measurements carried out by Perlin et al. Reference Perlin, Jauberthie-Carillon, Itie, Miguel, Grzegory and Polian[6] on bulk GaN crystals under hydrostatic pressure since, according to (3), (4) and (5):
5. Raman experiment and discussion
Raman measurements were performed at 77K on the series of GaN layers grown at different V/III molar ratios (for further details about growth, see Reference Madelung[7]). The layer characteristics are given in Table I, together with the corresponding built-in stress estimated from the 2K reflectance studies Reference Briot, Alexis, Gil and Aulombard[5]. The stress at 2K can be used confidently at 77K also, as demonstrated on Figure 1, which compares the reflectivity spectra recorded on the same sample at 2K and 77K, respectively. Except for an overall red shift of 4 meV, and in terms of splittings between A, B and C lines, the77K data is identical to that taken at 2K. Since the change of the A-C splittings amounts to 1.4 meV/kbar Reference Briot, Alexis, Gil and Aulombard[5], within the experimental uncertainty in the determination of energy of C line (<0.5 meV) we estimate the error in stress calibration to be at worst 250 bar.
Figure 1. Typical GaN reflectivity spectra taken at 2K (full line) and 77K (dashed line). The 77K spectrum is blue-shifted by 4 meV to match the energy of structures A. Except for a weak broadening of the structures with increasing temperature, due to thermal increasing of collisions, the constant splittings we observe between the A, B and C lines is experimental evidence of a constant biaxial strain for temperatures ranging between 2K and 77K.
Table I Layer characteristics and corresponding built-in stress estimated from 2K reflectance experiments.
The Raman spectra were excited in backscattering geometry along [ 0 0 0 1 ], using the 488 nm radiation of an Ar+ laser. The scattered light was analyzed with a T800 triple spectrometer equipped with a conventional photon counting system. Although the actual scattering geometry allows the observation of the A1 (LO) extraordinary phonon and that of the two E2 modes, the low frequency E2 mode at 144 cm−1 was hardly detected due to far off-resonant conditions with respect to the yellow photoluminescence band. No reliable conclusions can be drawn concerning this mode. Figure 2 shows the non-analyzed Raman spectra in the frequency range of the highest E2 mode. A shift of the E2 frequency is clearly observed with respect to the sapphire line at 578 cm−1, corresponding to mode hardening with decreasing V/III ratio. To a lesser extent, the same trend is noted for the A1 (LO) mode. The phonon frequency as a function of biaxial stress in GaN is deduced from our Raman measurements for the E2 and A1 (LO) modes and is displayed in Figure 3. Using elastic compliance constants obtained from the elastic stiffness coefficients C11 = 296 GPa, C12 = 130 GPa, C13 = 158 GPa, C33 = 267 GPa Reference Madelung[7], a least squares fit gives the following values for the slopes: KE2B = 2.9 ± 0.3 cm−1/GPa and KA1(LO)B = 0.8 ± 0.4 cm−1/GPa. Despite the large imprecision in the KA1(LO)B pressure coefficient due to the rather weak Raman efficiency of the mode, its lower value undoubtedly reflects the weak influence of the in-plane biaxial stress to the A1(LO) compared to the E2 mode.
Figure 2. Unanalyzed Raman Spectra recorded at 77K for different GaN layers at λL = 488 nm in the E2 frequency range. The asterisk marks one of the sapphire lines at 578cm−1.
Figure 3. Least-squares fit of the mode wave numbers vs. the internal stress estimated at 77K for the E2 and A1 (LO) modes.
The hydrostatic pressure coefficients of the modes were taken from Reference Perlin, Jauberthie-Carillon, Itie, Miguel, Grzegory and Polian[6]. Since their heavily doped sample had no observable A1(LO) mode in backscattering geometry along [ 0 0 0 1 ], we adopted the pressure coefficient of their A1(TO) mode, in fact the phonon-like component of the A1(LO) plasmon coupled mode Reference Perlin, Camassel, Knap, Taliercio, Chervin, Suski, Grzegory and Porowski[8]. For KE2H = 4.17 cm−1/GPa and KA1(LO)H = 4.06 cm−1/GPa, we obtain the two sets of deformation potential constants, listed in Table II for each mode. As expected, they are two orders of magnitude smaller than those describing strain effects on the electronic band extrema Reference Perlin, Jauberthie-Carillon, Itie, Miguel, Grzegory and Polian[6]. However, in view of the uncertainty in the KA1(LO)B coefficient value, the determination of the deformation potentials of A1(LO) mode must be considered only as a tentative one. Anyhow, we are confident in the low value of this coefficient which is indicative of significant anisotropy in the A1(LO) deformation potentials.
Table II Phonon deformation potentials of GaN at liquid nitrogen temperature in cm−1/unit strain.
6. Conclusion
Raman investigations of strained GaN epilayers grown with strain on sapphire substrates have been performed at low temperature. Taking into account the stress calibrations based on reflectance measurements, we determined deformation potentials of two q = 0 phonons from shifts in phonon frequencies under the built-in stress. Until now, these deformation potentials have not been obtained for GaN because classical piezospectroscopic studies under external uniaxial stress require large size crystals not available at this time in GaN. This work should be a helpful basis for further Raman studies of residual strain fields in InGaN- and AlGaN-based heterostructures.
