4.1 Method of analysis

In order to investigate how the plate-like or needle-like GaN single crystals grow, it is necessary to take a closer look at the longitudinal sections along each of the habits (cf. Figure 2). All sections of crystals shown in this paper present the growth bands corresponding to subsequently growing layers, often observed in real crystals. Each layer corresponds to the position of a given face at equal time intervals. It means that the growth bands allow the investigation of the growth history of crystals Reference Görnert, Voigt and Kaldis[6]. Therefore, the sections illustrate growth histories of exemplary GaN single crystals. If we assume that the layer of a given face grows with constant rate, the distances between the growth bands are proportional to growth rates of individual faces. The same layer, but of some other face, grows with constant rate too, but these two constant rates do not have to be the same. It means that the distance between growth bands is not the same for different faces.

In all cases considered in this paper the growth begins from a two-dimensional seed. The (000

) face adheres to a basis and its growth rate is equal to zero. The two-dimensional seed grows and plate-like or needle-like three-dimensional crystals appear. It would be very interesting to know how it happens that the crystal habits that appear are so different.

In order to explain these different crystal habits let us analyze the critical growth rate R_A ^crit , defined as the normal growth rate of face Aat which the edge l_A/C created by faces Aand C preserves its size Reference Szurgot and Prywer[7] Reference Szurgot[8]. It was derived in Reference Prywer[9] that the critical growth rate R_A ^crit may be expressed by the formula:

where: R_B , R_C and R_D are the normal growth rates of individual faces B, C and D respectively. These faces B, C and D are surrounding faces of the edge l_A/C . Their growth rates, R_B , R_C and R_D , are assumed to be constant not during the whole growth process, but only during the growth of a single layer of crystal. A layer of crystal may be defined as the distance between one growth band and another as described above. The angles α, β, γ are the angles between vectors normal to the pairs of faces: A/B, A/C, A/D, respectively. The angles ψ ₁, ψ ₂ are the complements of angles between appropriate edges of face A Reference Prywer[9]. If the face A grows with normal growth rate R_A greater than R_A ^crit , then the size of l_A/C decreases. In the case where the growth rate R_A is smaller than R_A ^crit the edge size increases. For some faces, (for example all faces without parallel edges or pentagonal faces) the critical growth rate for a given edge is simultaneously the critical growth rate for the whole face Reference Prywer[10]. This means that for such cases not only a given edge but also the whole face may change or preserve its size.

The above formula is applied in this paper to GaN single crystals. It yields critical growth rates for different edges and faces which correspond to decreases in the size of some faces and to increases in the size of other faces. The values obtained for these critical growth rates make it possible to analyze the changes in habits of growing GaN crystals.

4.2 Transformation from plate-like into needle-like GaN single crystal habits

In order to investigate how these plate-like or needle-like crystals grow, let us take a closer look at one chosen habit, for example the one shown in Figure 3a and Figure 3b. The section (Figure 3b) shows the growth bands which illustrate an exemplary growth history and the transition from plate-like to needle-like GaN single crystal habit. The growth begins from a two-dimensional seed. The two-dimensional seed grows and a plate-like three-dimensional crystal appears. Up to the m ₃ growth band (Figure 2b) the relative growth rates R _{10

_0} /R _{{10 1}} and R ₍₀₀₀₁₎ /R _{{10 1}} are assumed to be constant and equal to 1.07 and 0.13, respectively. Beginning from the m ₃ growth band these relative growth rates change. Up to m ₆ growth band the relative growth rate R _{{10 0}} /R _{{10 1}} remains the same but the ratio R ₍₀₀₀₁₎ /R _{{10 1}} changes its value to 0.20. This change is big enough to start the appearance of the {101} set of faces - m ₄ growth band - Figure 3b. From these relative growth rates it is seen that the growth rates of the new {101} faces are a little smaller than the rate of the neighboring {100} face and is much higher than the growth rate of another neighboring face (0001). The next assumed changes in these relative growth rates (changes in R _{{10 0}} /R _{{10 1}} from 1.02 at the m ₇ growth band to 0.82 at the m ₁₅ growth band and in R ₍₀₀₀₁₎ /R _{{10 1}} from 0.51 at the m ₇ growth band to 1.51 at the m ₁₅ growth band) cause the increase in size of all faces. It is seen that up to the m ₁₅ growth band the crystal is in a plate-like shape.

Figure 3a. The observed GaN needle-like single crystal habits with pyramidal faces {10

1}. The letter “s” indicates the line of longitudinal section shown in Figure 3b.

Figure 3b. The longitudinal section of GaN single crystal habit shown in Figure 3a, with pyramidal faces {10

1}. m ₃, m ₃₀ denote growth bands.

It is possible to apply Equation (1) to GaN single crystals and evaluate the relative growth rate

. The (0001) face is surrounded by {101} faces. If there is no anisotropy of growth rates of the faces in the {101} set surrounding the (0001) face, when this face disappears it becomes a corner. This means that the ratio corresponds to the size changes of the whole (0001) face, not only to one of its edges. In the case of the (0001) face R _B =R _C =R _D =R _{{10 1}} . When we divide the above Equation 1 by R _{{10 1}} , it is possible to evaluate the critical relative growth rate, . For the (0001) face the angles α= β = γ =(0001)/{101} = 61.96° and ψ ₁ = ψ ₂= 60.00°. Substituting these values into Equation 1 we have equal to 2.13. This relative growth rate depends only on the geometry of the crystal represented by the appropriate angles. The value of this critical relative growth rate means that for relative growth rate , the size of the (0001) face remains the same during further growth. Up to the m ₁₅ growth band the ratio R ₍₀₀₀₁₎ /R _{{10 1}} is smaller than the evaluated value 2.13 and the sector of the (0001) face is wide. However, beginning from the m ₁₆ growth band, the (0001) face grows very fast (R ₍₀₀₀₁₎ /R _{{10 1}} = 2.86) while the {100} face grows more and more slowly (R _{{10 0}} /R _{{10 1}} = 0.61) and the crystal starts to transform to the needle-like habit. As a result of the further increase of growth rate of the (0001) face this face disappears in the habit at the m ₂₇ growth band and it is absent in the m ₂₈ growth band. Finally, the face is present in the habit because of the decrease of relative growth rate R ₍₀₀₀₁₎/R _{{10 1}} to 1.22 (R _{{10 0}} /R _{{10 1}} = 0.31). The final habit is needle-like.

Similarly, as it was done for the (0001) face, it is also possible to evaluate

. In this case face B is the face belonging to the {101} set of faces, so R_B =R _{{10 1}} . Face C is the face belonging to the {101} set of faces, so R_C =R _{{10 0}} . Face D corresponds to the (000) face, whose growth rate was assumed to be equal to zero. The angle αis the angle between vectors normal to two adjacent faces, the first one from the {101} set and the second from the {100} set and it is equal to 28.04°. The angle β is the angle between vectors normal to two neighboring faces belonging to the set {100} and it is equal to 60.00°. The angle γ is the angle between a vector normal to a face from the {100} set and one normal to the (000) face and it is equal to 90.00°. As the faces {100} are of rectangular shape the angles ψ ₁, ψ ₂ are the same and equal to 90.00°. Because the sum of ψ ₁, ψ ₂ is equal to 180°, does not depend on the R_C growth rate (see Equation 1). In such a case the ratio depends on the geometry of crystal and is equal to 1.13. The relative growth rate is smaller than the evaluated value 1.13 throughout the considered exemplary GaN single crystal growth process. As a result, the {100} face becomes bigger and bigger and in the final habit this set of faces is very well developed.

Let us take a closer look at the habit at the m ₉ growth band. It is seen that at this stage of growth the crystal is plate-like. The relative growth rates R ₍₀₀₀₁₎/R _{10

_1} and R _{{10 0}} /R _{{10 1}} for this growth band are assumed to be equal to 0.51 and 1.01, respectively. If these relative growth rates were constant from this band till the end of growth process, the final shape of crystal would be plate-like, very similar to that seen in Figure 1b or Figure 2.

Generally, it is seen that the plate-like GaN single crystals grow when the relative growth rate R ₍₀₀₀₁₎/R _{10

_1} is much smaller than the evaluated critical ratio and also when the relative growth rate R _{{10 0}} /R _{{10 1}} is a little smaller than . Such values of relative growth rates guarantee a continuous increase in the (0001) face size and a moderate increase in the {100} face size.

For some crystals, pyramids are formed with {10

1} faces and for others, with {102} faces (Figure 4). In the latter case it is necessary to consider . The first value is equal to 1.37 (R_B =R _C =R _D =R _{{10 2}} , α= β = γ = (0001)/{102} = 43.19°, ψ ₁ = ψ ₂ = 60.00°). The relative growth rate is equal to 1.46. To determine this value it is necessary to know that the faces Band C are the faces belonging to the {102} set and the {100} set, respectively. Therefore, R _B =R _{{10 2}} and R_C =R _{{10 0}} . Face D corresponds to (000), thus, R _D =R _{(000 )} = 0. The angle αis the angle between normals to two adjacent faces, the first one from the {100} set and the second from the {102} set and is equal to 46.81°. The angle β is the angle between normals to two neighboring {100} faces and is equal to 60.00°. The angle γ is the angle between a vectors normal to a {100} face and a (000) face and is equal to 90.00°. The angles ψ ₁, ψ ₂ are both equal to 90.00°. These values, and indicate that the plate-like GaN single crystals with pyramidal faces {102} grow when the relative growth rate R ₍₀₀₀₁₎/R _{{10 2}} is much smaller than 1.37 and when R _{{10 0}} /R _{{10 2}} a little smaller than 1.46. Such values of relative growth rates guarantee successive increase in the (0001) face size and a moderate increase of the {100} face size.

Figure 4. Two kinds of the observed GaN needle-like single crystal habits and their longitudinal sections; habits: a) with pyramidal faces {10

2}, b) with both sets of pyramidal faces {10

1} and {10

2}. The letter “s” indicates the line of longitudinal section.

In the case considered above it is assumed that all faces belonging to a given set {10

0}, {101} or {102} grow with the same rates. This assumption was made for simplicity. But in real crystals the growth rates of faces from the same set may differ slightly. In such cases the hexagonal symmetry is disordered as it may be seen in Figure 1a.

Sometimes, star-like GaN crystal habits were observed - Figure 5. In this figure well developed {10

0} faces which forming a star created by raised edges of {101} faces may be seen. If the faces were absent in the habit, it would be possible to suppose that the star-like crystal is in fact a triplet crystal. But when the star-like crystals were observed, they always were surrounded by the {100} faces. For that reason it is supposed that habits like this are the result of unstable growth Reference Elwell and Scheel[11]. The most likely reason for growth of such crystals is that the higher supersaturation at the corners and edges of the crystal leads to an increase in growth rate with increasing distance from the center of the face. At first such progressive increase in supersaturation leads to more rapid growth of edge and corner regions and as a result raised edges develop. Simultaneously, the center of the faces tend to develop terraced depressions. The next stage is the hopper crystals and, in the extreme case of growth at the edges of crystal, the final shape will be dendritic. In the considered case of GaN single crystals, the dendritic shape is sometimes seen in the direction of rapid growth. The slowly growing faces are very well developed and without depressions.

Figure 5. The exemplary star-like GaN single crystal habit Reference Grzegory and Krukowski[2].

On the basis of the above analysis and the exemplary longitudinal sections of GaN single crystal habits, the conclusion may be drawn that the transition from the plate-like to needle-like habit is possible and it can occur in a stable way. The transformation from the plate-like into the needle-like habit in the case of the {10

1} pyramidal faces is caused by the increase in the relative growth rate R ₍₀₀₀₁₎/R _{{10 1}} above 2.13 and a simultaneous decrease in the relative growth rate R _{{10 0}} /R _{{10 1}} below 1.13. When the pyramid is created by the set of {102} faces, the transformation from plate-like to needle-like habit is caused by the increase in the relative growth rate R ₍₀₀₀₁₎/R _{{10 2}} above 1.37 and simultaneous decrease in relative growth rate R _{{10 0}} /R _{{10 2}} below 1.46. The observed star-like needles are supposed to be the result of unstable growth. The higher supersaturation at the corners and edges of crystal leads to the more rapid growth at these regions and, as a result, the final shape is star-like.