Introduction

Quantum dots (QDs) have validated their important role in current optoelectronic devices and they are also seen promising as light sources for quantum information applications. An improved efficiency of laser diodes and light-emitting diodes can be achieved by the incorporation of QDs ensembles in the optically active layers.1 In addition, the proposed quantum computer applications rely on photons with distinct energy and polarization vectors, which can be seen as the ultimate demand on photons emitted from individual QDs.2 A common requirement raised for several optoelectronic applications, e.g., liquid-crystal displays, three-dimensional visualization, (bio)-dermatology3 and the optical quantum computers,4 is the need of linearly polarized light for their operation. For existing applications, the generation of linearly polarized light is obtained by passing unpolarized light through a combination of polarization selective filters and waveguides, with an inevitable efficiency loss as the result. These losses can be drastically reduced by employment of sources, which directly generate photons with desired polarization directions.

Conventional QDs grown via the Stranski–Krastanov (SK) growth mode are typically randomly distributed over planar substrates and possess different degrees of anisotropies. The anisotropy in strain field and/or geometrical shape of each individual QD determines the polarization performance of the QD emission. Accordingly, a cumbersome post-selection of QDs with desired polarization properties among the randomly distributed QDs is required for device integration.5 Consequently, an approach to obtain QDs with controlled site and polarization direction is highly desired.

Although no perfect solution has been presented yet, several approaches on the site and polarization control of QDs have been reported. Preferential nucleation sites with finite areas created by in situ electron beam lithography6 and prefabricated pyramidal7,8,9,10,11 or nanowire12,13,14 templates have been demonstrated to obtain site-controlled QDs. However, these approaches do not provide any obvious path to polarization control. One route to achieve polarization control of the QD-based light-emitting sources is to grow stacked SK QDs.15,16 Large stacks of SK QDs are analogous to quantum wires, with the strongest confinement in the lateral directions, in contrast to a thin QD for which the vertical confinement is more significant. The observed polarization of the emission is successively rotated from a predominant transverse-electric mode to a transverse-magnetic mode, as the number of QDs in the stack increases. However, the emission is relatively broad and it red-shifts significantly when the polarization is rotated from transverse-electric to transverse-magnetic due to the reduced vertical quantum confinement.15 The QD-based single photon sources with polarization control presented up to date relies on a dot-in-microcavity design, in which the QD emission has to be tuned in order to efficiently couple with cavity modes. The tuning of the QD emission with respect to the cavity resonance can be done by temperature17,18 or by taking advantage of the Stark effect in an electrically gated cavity.19 The concept with single QDs embedded in a nanowire is a promising alternative, as both the QD site and the polarization direction can be controlled.14 However, the polarization will be restricted to the direction parallel to the long axis of nanowire, as the mechanism of polarization control in this case is due to the large dielectric constant contrast between the nanowire and the surrounding air, attenuating the electric field transverse to the long axis of the nanowire.14

In this work, an approach to directly generate linearly polarized QD emission is demonstrated. Deterministic polarization directions are achieved by introducing site-controlled InGaN QDs on top of elongated GaN-based hexagonal pyramids (GaN EHPs) without employing complex cavity solutions. The polarization directions of the QD emission are found to be well aligned with the orientation of the EHPs. The reliability and consistency for this architecture are tested by a statistical analysis of InGaN QDs grown on GaN EHP arrays with different in-plane orientations of the elongations.

III-nitrides (III-N) QDs with potential to emit from the deep ultraviolet to the infrared have emerged as one of the most technologically important materials for optoelectronic applications. The wide bandgap range of III-N semiconductors opens the possibility to attain deep confinement potentials for the QDs, which has potential for high-temperature operation, as already demonstrated for a GaN-based single-photon source operating at 200 K.20 Moreover, III-N QDs are seen to be the best candidate for high performance optoelectronic applications due to their feasibility of achieving QD emission with an inherently high degree of linear polarization.21 Our results clearly show that it is possible to control the polarization direction of the emitted photons from InGaN QDs by varying the orientations of the underlying GaN EHPs. The polarization direction of the ground-state-related emission from the QDs reflects the axis of in-plane anisotropy of the confining potential, concerning both strain and/or QD shape.22,23 The same polarization direction for different QDs indicates that all grown QDs possess the same unidirectional in-plane anisotropy. Such simultaneous alignment of multiple QDs with controllable orientations has not been reported up to now to the best of our knowledge.

Materials and methods

Patterned substrate for the growth of GaN EHPs and symmetric hexagonal pyramids (SHPs)

The GaN EHPs and ordinary sixfold SHPs were selectively grown through oval and circular openings, respectively, on a lithographically patterned SiN-masked substrate. The substrates consisted of a 2.0 µm thick (0001)-oriented GaN film epitaxially grown on a 4-inch, n-type, on-axis 4H-SiC substrate starting with an AlN nucleation layer (100 nm).24 The defined pattern was created by conventional ultraviolet lithography and reactive ion etching technique. Both circular openings and oval openings were repeated to form 10×10 arrays with a center-to-center distance of 6.3 µm. The radii (R) of the circular openings were made 1.5 µm. The oval openings were deviations from circular openings (Figure 1a) in such a way that a rectangle with a constant width of 2R and variable lengths E (E=0.2, 0.4, 0.6, 0.8 and 1 µm) was inserted between two semicircles along designated directions. An angular parameter α, defined as the angle between the E-axis and the [] direction of the underlying GaN template, was introduced to describe the orientations of GaN EHPs as shown in Figure 1b. α was varied in 30° steps over a 150° period giving rise to six different orientations for the oval openings. For simplicity, the GaN EHPs described below have E=1.0 µm and α=0° unless indicated otherwise.

Figure 1
figure 1

(a) Schematic illustration of the mask design allowing the creation of circular and oval shapes with α=0°. (b) Schematic illustrations of all oval openings with various orientations processed on the substrate. The red lines show the elongation axis. The angle between the [] direction of the underlying GaN and the red line is denoted α. (c, d) Schematic illustration of the morphologies of GaN SHPs grown from circular openings and GaN EHPs grown from oval openings with various values of α. EHP, elongated hexagonal pyramid; SHP, symmetric hexagonal pyramid.

The growth conditions of GaN/InGaN/GaN EHPs (SHPs)

A horizontal low pressure hot-wall metal organic chemical vapor deposition system was used to grow entire structure. Trimethylgallium, trimethylindium and ammonia were used as precursors and the pressure during growth process was kept at 50 mbar. The growth conditions of the GaN EHPs and SHPs were based on our earlier development of uniform GaN SHPs with top (0001) facets.25 After the formation of GaN EHPs (SHPs), InGaN and GaN-cap layers were subsequently deposited on top of the EHPs (SHPs). The growth temperature for the GaN EHPs (SHPs) and the subsequent InGaN QWs/QDs were 1030 °C and 800 °C, respectively. Upon this structure, a thin GaN cap layer (about 6–8 nm) was grown at 800 °C.

Optical characterizations

A continuous wave laser operating at 266 nm was used as the excitation source. The laser was focused to a spot diameter of 1.5 µm through a reflective objective. The spot diameter was significantly smaller than the interdistance between the pyramids (6.3 µm) and consequently could the emission properties of individual EHPs be studied. The emission was collected by the same objective and subsequently guided through the optics for polarization analysis, consisting of a rotatable half-wave retardation plate and a fixed linear polarizer, before entering the monochromator. This polarization analyzer provides detection of light linearly polarized along an adjustable angle θ. In order to correlate the direction of the linearly polarized emission with the designated elongation direction, the reference angle θ=0° corresponds to α=0°, which is parallel to the [] direction of the underlying GaN template. The polarization direction of the emission (φ) can be determined by fitting the measured data with the conventional formula for polarization: I(θ)=A+Bcos2(θφ). To elucidate the polarization guiding effect (α=φ) in our work, an overall tolerance of ±10° was used in order to include all possible systematic errors, including the misalignment of the sample and the optics as well as the judgment of the corresponding θ for maximum and minimum intensities. Therefore, we consider the results satisfying |αφ|≤10°(αφ) to be consistent with polarization guiding. The cathodoluminescene (CL) was performed at 4 K in a Leo 1550 SEM equipped with a MonoCL2 system. The CL measurements were done by an electron beam with an accelerating voltage of 2.5 keV and a spectral bandpass of 3 nm (for 2 mm slit and 1800 lines mm−1 grating).

Results and discussion

Morphological evolution of GaN EHPs

Given that the initial growth is determined by the shape of the SiN openings, the growth in circular openings results in GaN SHPs with six equivalent {} planes, as a direct consequence of the hexagonal characteristics of the wurtzite crystal.11 The GaN SHP is formed by the volume enclosed by one (0001) surface and six equally sized {} facets (Figure 1c). On the other hand, the growth in oval openings breaks the condition of equal size for all six {} planes; Two of the six {} planes are longer, determined by E, as depicted in Figure 1c. By prolonging the growth time, six {} sidewalls converged to form an elongated (0001) surface directed along E (forming a ridge). The length and width of the ridge were estimated to be approximately 1.0 µm and 100 nm, respectively, when E was set to 1.0 µm. Owing to the sixfold symmetry of the wurtzite structure, rotating GaN EHPs grown from α=0° with steps of 60° (120°) does not change the shape of GaN EHPs, but merely results in an in-plane rotation (cf. Figure 1d, upper part). However, a rotation with α=30°, 90° or 150° leads to a shape different than that of α=0°. Assuming that the growth rate is similar for GaN EHPs and SHPs, and that the long axis of the GaN EHPs still follow α, the growth of two planes perpendicular to α will be ceased during the growth. Continuous growth of the GaN EHPs will lead to small rhombic-shaped (0001) surfaces (Figure 1d, lower part). Consequently, one can say that the GaN EHPs with α=0°, 60° and 120° are characterized by one type of morphology, while those with α=30°, 90° and 150° have another type of morphology. The orientations of the GaN EHPs as well the top ridges are found to be highly correlated with the polarizations directions of the emission from the InGaN QDs. Such polarization guiding will be further elucidated and verified in the following.

Multiple InGaN QDs on a GaN EHP

Figure 2a shows representative polarization-dependent microphotoluminescence(µPL) spectra from a GaN EHP measured at 4 K. A broad emission band peaking at 386 nm and several emission peaks in the range between 410 and 420 nm are observed. The monochromatic CL images in Figure 2b clearly reveal that the broad emission band and the sharp peaks are associated with the InGaN layers on the {} facets and the InGaN QDs on top of the GaN EHP, respectively. Such an observation is consistent with previous results, in which c-plane truncations on GaN SHPs serve as preferential QD formation sites via SK-like mechanism.11,26 The full-width half-maxima of the emission peaks in the present case are relatively broad (> 4 meV). Two additional experimental observations should be noted. First, spectral peaks with the full-width half-maxima as sharp as that of individual QDs on GaN SHPs (in the range of 0.35–1.2 meV) can be observed.11 Second, the peaks merge into a broad band when the number of QDs on a GaN EHP is increased by shortening the growth time of the pyramid to enlarge the top (0001) area. Therefore, the larger full-width half-maxima in the present case is suggested to be due to the inhomogeneous broadening caused by multiple QDs on top of the EHP.27 In addition, the emission peaks of InGaN QDs are not sensitive to the temperature.11,28 A temperature robust optical behavior is advantageous for QD-based single photon emitters operating at high temperature.

Figure 2
figure 2

(a) µPL spectra of EHPs with the polarization analyzer set to θmax (θmin) by which the maximum (minimum) intensity of sharp emission peaks are detected. (b) Spatially resolved monochromatic CL intensity maps of another GaN EHP from the same growth experiment. CL, cathodoluminescene; EHP, elongated hexagonal pyramid; μPL, microphotoluminescence.

Interestingly, all the QD-related emission peaks are strongly polarized along the same direction as evidenced by the fact that all peaks have their maximum and minimum intensities at the same θ (Figure 2a). Referring to our excitation/detection geometry, the linearly polarized emission can be ascribed to the in-plane anisotropy of the QD confinement potential.22,23 Thus, our experimental results imply that the in-plane anisotropies of all the InGaN QDs on the same EHP are simultaneously aligned. Moreover, the magnitude of in-plane anisotropy should be significant to achieve the observed high degree of polarization.

The polarization guiding effect of GaN EHPs

As shown in Figure 2a, all the emission peaks associated with the QDs on a GaN EHP are linearly polarized along the same direction (showing the same φ). Further correlation between the polarization-resolved measurements and the orientations of GaN EHPs (defined by α) reveals that the polarization direction is parallel to the elongation (αφ=0 in Figure 2a). As depicted in Figure 1, the implantation of E in the mask design allows the creation of oval openings and the formation of GaN EHPs with ridges parallel to the E. The lengths of the ridges on GaN EHPs should be proportional to E, while the widths of the ridges should be independent on E, but related to the growth time. For simplicity, E is used as an averaged parameter representing the degree of elongation in GaN EHPs. The effect of E is statistically studied by measuring the polarization directions of QDs on GaN EHPs with various values of E for the case of α=0°. As demonstrated in Figure 3, the polarization guiding effect becomes more effective for E larger than 0.6 µm. A nearly perfect guiding effect (with a probability >0.9) is obtained for the maximal E=1.0 µm in the current mask design, implying that the elongated ridges help to guide the polarization. In addition, GaN EHPs with various values of α have been examined in order to investigate the possibility to control the polarization guiding in different directions. A polarization guiding (αφ) is unambiguously revealed for GaN EHPs with α=0°, 60° and 120° (as demonstrated in Figure 4). For the remaining group of GaN EHPs with α=30°, 90° and 150°, preferential polarization directions are seemly revealed, but αφ is not strictly followed.

Figure 3
figure 3

Statistical histogram of the observed polarization guiding effect as a function of E. The polarization guiding effect is defined in such a way that the measured polarization direction, φ, matches with the orientations of GaN EHPs, α, satisfying the criterion |αφ|≤10°. EHP, elongated hexagonal pyramid. n=78 for each different values of E.

Figure 4
figure 4

Distribution histograms of measured φ from the GaN EHPs located in blocks with various values of α. The results from reference GaN SHPs are also included for comparison (n=95). EHP, elongated hexagonal pyramid; SHP, symmetric hexagonal pyramid. n=78 for each different values of α.

The origin of polarization guiding

To investigate the polarization guiding, the actual morphologies of those GaN EHPs shown in Figure 4 have been further examined. A general observation is that the GaN EHPs tend to comply with the design of the oval openings with α=0°, 60° and 120°, as evidenced by a large scale of uniform GaN EHPs shown in Figure 5a. The orientations of the GaN EHPs as well as the top ridges match well with the directions of the oval openings of α=0°, 60° and 120° (compare the upper part of Figures 1d and 5b). On the other hand, the growth of GaN EHPs with α=30°, 90° and 150°, does not lead to the formation of elongated ridges (Figure 5c). It should be noted that the growth of EHPs with α=30° (150°) often resulted in distorted GaN EHPs with unidentified facets enclosed by the six {} planes. Therefore, the polarization guiding effect can be ascribed to the orientations of GaN EHPs and the formation of elongated ridges.

Figure 5
figure 5

(a) SEM image showing uniform growth of GaN EHPs from oval openings with α=0°. (b, c) Magnified SEM images of individual GaN EHPs complied with oval openings with various values of α. EHP, elongated hexagonal pyramid; SEM, scanning electron microscope.

Preferred polarization directions of III-N QDs grown on planar (0001)-oriented substrates have earlier been reported by using different fabrication approaches.22,23 In these reports, the preferential polarization directions were not understood. A unidirectional strain induced by the underlying layers to the overgrown QDs was given as a plausible explanation. However, such a behavior is a macroscopic character, rendering any further control of the polarization direction unrealistic based on current conventional growth techniques, as it would imply control of the strain under every QD over the entire substrate.

The polarization control observed in this work can be explained in three ways: (i) the GaN EHPs transfer an anisotropic biaxial strain field to the QDs resulting in the formation of elongated QDs. The strength of the strain field in the EHPs should then be strongly correlated with E and accordingly explaining why the guidance probability presented in Figure 3a increases continuously with E; (ii) given that the top parts of GaN EHPs are fully strain relaxed, as concluded for GaN SHPs,29 the asymmetry induced by a ridge will result in an anisotropic relaxation of the in-plane strain of the QDs on the ridge. The degree of relaxation is higher along the smallest dimension of the top area, i.e., along the direction perpendicular to the ridge elongation, leading to the ground state emission of the QD being polarized parallel to the ridge; and (iii) the ridge formation edges form a Schwoebel–Ehrlich barrier which prevents adatoms of diffusing out from the (0001) facet.30,31 Since the adatoms have larger probability to interact with an edge barrier parallel rather than orthogonal to the ridge elongation, the adatoms will preferentially diffuse parallel to the ridge elongation. Upon nucleation in such a directional diffusion of adatoms, elongated QDs may form. The polarization direction is known to be governed by the strain and shape anisotropy of the QD. As the strain and the shape of the QD are not independent factors and any accurate structural information of the QD currently is unavailable, further investigations are needed to gain additional information on the predominant factors determining the polarization.

The high degree of polarization in III-N QDs

Wherever the QDs are formed, on GaN SHPs or EHPs with various values of E, the degree of polarization for the QD emission is typically high, as shown in Figure 6a with measurements from a GaN EHP with α=0°. The polarization degree of the III-Ns is more sensitive to the in-plane asymmetry compared to the III-As system due to the significant band mixing and the identical on-axis effective masses of the A and B bands in the III-N.22 A statistical investigation of the value of P performed on 145 GaN EHPs (Figure 6b) reveals that 93% of the investigated GaN EHPs possess P>0.7 with an average value of P=0.84. A similar investigation has been performed on GaN QDs grown on AlN/Si (111) substrates by Bardoux et al.22 in which only 20% of the QD emissions had P>0.7 with an average value of P=0.63. The polarization of the emissions is related to the QD asymmetry determined by the anisotropy of the internal strain and electric fields, as well as by the structural shape of the QD itself.22 Numerical computations predict a high degree of polarization for small or moderate in-plane shape anisotropy of GaN and InGaN QDs.32,33 This is related to the intrinsic valence band structure of the III-Ns. To reach P0.95, an in-plane shape elongation of 1.251 is needed for an InGaN QD,23,33 while a corresponding aspect ratio of 2.51 is needed for GaN QDs.32 In particular, we have identified the split-off energy as the key material parameter determining the degree of polarization for a given asymmetry.21 Figure 7 shows the computed degree of polarization plotted against a variation of the split-off energy. Given a fixed asymmetry of the QDs, it is concluded that the material with the smallest split-off energy exhibits the highest degree of polarization. The extreme sensitivity on the asymmetry for InGaN QDs can be ascribed to a significant band mixing in InN and implies its inherent advantage for the generation of photons possessing a specific polarization.

Figure 6
figure 6

(a) Polar plots of the µPL intensity versus the angle of the polarization analyzer (θ) for three selected GaN EHPs with α=0°. (b) Statistical histogram showing the overall measured degree of polarization from GaN EHPs with E=1 µm and α=0°, 60° and 120°. Total number of pyramids measured is n=234 (78 for each different values of α). EHP, elongated hexagonal pyramid; μPL, microphotoluminescence; PL, photoluminescence.

Figure 7
figure 7

The computed degree of polarization plotted as a function of the split-off energy. The QD shape is assumed to be lens-shaped with an in-plane asymmetry of b/a=0.8. The single particle electron (hole) eigenstates are obtained from an effective mass Schrödinger equation (with a 6 band k·p Hamiltonian), discretized by finite differences. The Hamiltonians include strain and internal electric fields originating from spontaneous and piezoelectric polarizations. The polarized optical transitions are computed by the dipole matrix elements. QD, quantum dot.

Conclusions

In this paper, we have demonstrated an effective method to achieve site-controlled QDs emitting linearly polarized emission with controlled polarization directions by growing InGaN QDs on top of elongated GaN pyramids in a metal organic chemical vapor deposition system. The polarization directions of the QD emission can be guided by the orientations of the underlying elongated GaN pyramids. Such an effect can be realized as the elongated GaN pyramids provide additional in-plane confinement for the InGaN QDs implanting unidirectional in-plane anisotropy into the QDs, which subsequently emit photons linearly-polarized along the elongated direction of the GaN EHPs. Several advantages of our present work can be expected for applications. First, the deep confinement potential which is achievable for III-N QDs will allow high temperature operation.20 Second, the emission wavelength regime could be tunable from ultraviolet to near infrared by adjusting the In composition in the InGaN. Third, a high polarization degree is more easily achieved in InGaN QDs compared to other semiconductor materials, even if the crystalline orientation is [0001]. Otherwise, semipolar or non-polar III-N layers must be used to achieve a high polarization degree.34 Fourth, our approach is compatible with current large-area wafers and processing techniques.35 If the number of QDs on a GaN EHPs is reduced, site-controlled QDs with controlled separation will facilitate the fabrication of ultracompact single-photon emitters with controllable photon polarization vectors on a single chip.

Author contributions

AL and CWH designed and performed the experiments, meanwhile analyzed the results and wrote the manuscript. KFK guided the optical investigations, conducted the numerical calculations and edited the manuscript. SA analyzed the results of the numerical calculations. DN performed the cathodoluminescence measurements. UF guided the material growth in metal organic chemical vapor deposition. EJ and POH guided the project and finalized the manuscript.