1. Introduction
Group III-nitrides are of great importance for green, blue and ultraviolet light emitting and laser diodes, as well as high power and high temperature electronic devices Reference Strite, Lin and Morkoc[1]. Progress in this field is closely related to success in growing epitaxial layers and heterostructures. For this purpose both metal-organic vapor phase epitaxy (MOVPE) and molecular beam epitaxy (MBE) are employed. Optimization of the growth process using these techniques is a key issue of many recent studies.
Numerous experiments have shown that the properties of group III-nitrides differ significantly from those of other III-V compounds. Molecular nitrogen interacts poorly with the surfaces of nitrides. As a result, an activation of nitrogen (by plasma or ionization assistance) is necessary for effective growth of nitrides at lower temperatures. The second peculiarity is the relatively high thermal stability of GaN and InN in the temperature range where these compounds dissociate into the liquid and vapor phases, in accordance with thermodynamic estimations Reference Newman, Ross and Rubin[2] Reference Karpov, Makarov, Ramm and Talalaevin[3]. The thermal stability results causes the fall in the GaN growth rate due to thermal desorption to occur at temperatures considerably higher than typical of GaAs and GaP Reference Morkoc, Botchkarev and Salvador[4]. Desorption is delayed despite of the higher volatility of nitrogen compared with other group V molecular species. Finally, group III-nitrides exhibit a drastic dependence of the nitrogen partial pressure on the orifice area in the case of vaporization from the Knudsen cell Reference Munir and Searcy[5] Reference Gordienko and Fenochka[6].
All these observations can be consistently explained by assuming the existence of a physisorption precursor at the surface of the nitrides which provides the low evaporation/condensation coefficient of N2. Using this assumption, we develop a quasi-thermodynamic approach which allows the trends in nitride MBE to be modeled, along with the prediction of the growth conditions where extra liquid phase appears on the surface.
2. Physisorption precursor of N2
The physisorption precursor can be represented schematically (Figure 1) as a potential well separated from the crystal surface.
The main parameters of the precursor are the heights of the potential barriers that must be overcome by N2 molecules to reach the surface (W in ) and to exit into the vacuum (W out ), and the relevant transition frequencies:
and
where ν ph is the oscillation frequency of nitrogen in the physisorption precursor, and g in and g out are the state degeneracy factors corresponding to activated N2 complex on the top of the respective potential barrier. We do not distinguish between the states of the atoms in the bulk of the crystal and the atoms chemisorbed in the adsorption layer. This simplification is workable if the exchange reaction between the crystal and adsorption layer is not the limiting step in the growth or evaporation of the material.
It is known that N2 poorly chemisorbs on the surfaces of nitrides. This results from the small value of its condensation coefficient αc considerably less than unity. Assuming second order dissociative chemisorption of N2 on the surface, and considering the dynamics of its arrival and release from the physisorption precursor similarly to Reference Arthur[7] Reference Karpov and Maiorov[8], we can obtain the following expression for the condensation coefficient:
Then the flux of the molecules incorporating into the crystal is equal to
, where is the incident N2 flux. This means that only a small part of the N2 arriving at the surface is able to incorporate into the crystal while the rest of the molecules reflect from the surface without any chemical interaction. By similar consideration of the reverse transition of nitrogen atoms from the crystal (or chemisorption layer) to the molecular state in vacuum, one can find that the desorbed N2 flux is related to the desorbed flux established under thermodynamic equilibrium as:where α e is the evaporation coefficient of N2. In our model of the physisorption state, the evaporation coefficient is found to be equal to the condensation coefficient (α e =α c ). Thus the expression (4) shows that the physisorption precursor provides additional stability to the crystal by suppressing the desorption of N2.
Simulation of the growth process requires us to know the evaporation coefficients over a wide temperature range. To obtain them, we compare the pressures of the gaseous components measured under Langmuir evaporation of AlN and GaN Reference Munir and Searcy[5] Reference Dreger, Dadape and Margrave[9] to the pressures calculated for the case of congruent vaporization of the crystals. The standard thermodynamic properties used in the calculations are refined to account for new information on specific heat and enthalpy of formation of the nitrides. The data obtained by such a way are then extrapolated using the Arrhenius function in accordance with Equation 4. As a result we obtain:
The corresponding data for InN are unavailable due to the lack of experimental information of its Langmuir vaporization.
3. Model of nitrides growth by MBE
We consider nitride growth of certain nitrides using external fluxes of group-III atoms (F III ) and activated nitrogen (F N ). Both group III and activated nitrogen species (atomic nitrogen, N+ ion, etc.) are assumed to have condensation coefficients near unity. In this case the elements, conservation on the growing surface can be written in the form:
Here n is the number of atoms in the activated nitrogen complex, σ is the surface density of crystalline sites, and V is the growth rate measured in monolayers per second. According to the thermodynamic approach Reference Shen and Chatillon[10] these expressions have to be added by the mass action law equation:
which follows from the assumption that heterogeneous ‘vapor-solid’ equilibrium is established between the desorbed species and the crystal. In Eq. (7), P III and
denote the partial pressures of the desorbed group III atoms and N2 molecules, is the equilibrium constant of nitride formation from the gaseous components; is proportional to (see figure 1). Taking into account that partial pressures are related to desorbed fluxes by the Hertz-Knudsen equation: (here β v = (2πm v kT)−1/2 is the Hertz-Knudsen factor for the ν-th species, m ν is the mass of ν-th component, and k is the Boltzmann constant), one can derive from Equation 7 an additional relationship valid for the desorbed fluxes and :In contrast to this thermodynamic consideration in the case of nitrides, however, a systematic shift from the equilibrium conditions arises due to the extremely low evaporation coefficient of N2 (see Equation 4). This means that instead of the mass action law Equation 8, we should use the equation
which accounts for the existence of the nitrogen physisorption precursor. Eqs. (6) and (9) form a closed equation system. Its solution allows the determination of the desorbed fluxes of all species, and the growth rate as function of temperature and incident fluxes.
4. Formation of the liquid phase during nitride growth
Prediction of liquid phase formation during nitride growth can be accomplished using the approach proposed in Reference Karpov, Kovalchuk, Myachin and Pogorelsky[11] in which a minimum incident group V molecular flux was predicted to be needed to provide the growth of a III-V compound under constant incident group III atomic flux growth without the appearance of an undesirable liquid phase on the surface. The main idea employed in Reference Karpov, Kovalchuk, Myachin and Pogorelsky[11] is to set the minimum group V incident flux to correspond to the three-phase ‘vapor-liquid-solid’ heterogeneous equilibrium. The value of minimum group V flux can be obtained from the numerical solution of the equations combining conservation of elements on the growthe surface with the mass action equations.
Here we present the analytical expression for minimum active nitrogen flux
providing for the growth of a nitride without appearance of liquid droplets on the growth surface. This expression can be obtained from the Eqs. (6) and (9), and by taking the desorbed group-III flux to be equal to the saturated vapor pressure over the liquid phase: (detailed analysis of this follows in a separate paper). We find:Both the
and K III−N in Equation 10 can be calculated using the standard thermodynamic properties of nitrides and the relevant elements.5. Results of calculations and comparison to experiment
To verify the proposed approach we compare theoretical results with the experimental data obtained for the MBE growth of GaN using activated nitrogen as a source.
Figure 2 shows the minimum nitrogen flux needed to avoid the appearance of the liquid phase during GaN growth as a function of inverse temperature.This curve represents a boundary between the area where epitaxial growth occurs without liquid droplets formation and the area where appearance of the extra liquid phase is expected. The dashed curve in figure 2 is calculated using pure thermodynamics Reference Karpov, Makarov, Ramm and Talalaevin[3] without accounting for the evaporation kinetics of N2. The solid curve in figure 2 is obtained using Equation 10. It is seen that the consideration of the physisorption precursor drastically shifts the position and shape of the calculated boundary of the liquid phase formation. In the case of pure thermodynamics, the liquid phase is expected to be formed under practically all common growth conditions. This prediction is not supported by experiment. The existence of the nitrogen precursor results in a temperature gap where the liquid phase is not formed, even at negligibly small incident nitrogen fluxes (a similar gap has been predicted earlier for AlAs and AlP Reference Karpov, Kovalchuk, Myachin and Pogorelsky[11]).
Detailed experimental data on liquid droplet formation while growing GaN were obtained from Reference Cho, Sakamoto, Akimoto, Okada and Akimoto[12] Reference Eddy, Moustakas and Scanlon[13]. In these works, the incident Ga flux (i.e. growth rate) and temperature were varied while holding the incident nitrogen flux constant. The appearance of droplets was monitored during growth. Assuming the value of activated nitrogen flux to be equal to 0.15 ML/s, we calculate the critical growth rate separating the area of extra liquid phase formation which is plotted in figure 3. The solid and open circles in figure 3 denote the growth regimes with and without droplets, respectively. One can see that theory and experiment agree with one another.
Detailed measurements of the GaN growth rate versus temperature under nitrogen rich conditions have been carried out Reference Morkoc, Botchkarev and Salvador[4]. The authors used an ECR-plasma for nitrogen activation. Assuming the incident Ga flux is equal to that corresponding to the low-temperature growth rate of 0.2 μm/h, we calculated the growth rate at different V/III ratios over a wide temperature range (see figure 4). One can see that the theoretical curve reproduces as a whole the behavior of the growth rate, although it predicts a more steep drop of the growth rate with increasing temperature than that observed in the experiment.
6. Conclusion
In this work a quasi-thermodynamic model for the analysis of group III-nitride growth by MBE and the conditions of surface liquid phase formation are developed. In the model, the shift of heterogeneous equilibrium attributed to the evaporation kinetics of N2 is taken into account. Reasonable agreement between the theory and experimental data obtained for MBE GaN growth supports the concept of a physisorption precursor which we propose to explain the MBE growth of nitrides. The model allows a straightforward generalization to the case of ternary nitrides.
Acknowledgments
This work was supported in part by Grant No 96-02-17203 from the Russian Foundation of Basic Research.