Growth and Optical Properties of Highly Uniform and Periodic InGaN Nanostructures

Chen, Peng; Chen, Ao; Chua, Soo Jin; Tan, Jen Ngee

doi:10.1002/adma.200602110

Cited by 34 publications

(21 citation statements)

References 34 publications

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“…[11] To control the position of a III-N QD, various approaches have been explored. [12][13][14][15][16][17][18] To date, QD-like emission has only been reported from dots formed at the apex of a sitecontrolled GaN pyramid [12,17] and dots at the top of a site-controlled AlGaN nanowire. [18] But no single photon emission has been reported from these systems yet.…”

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confidence: 99%

Single photon emission from site-controlled InGaN/GaN quantum dots

Zhang

Teng

Hill

et al. 2013

Applied Physics Letters

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Single photon emission was observed from site-controlled InGaN/GaN quantum dots. The singlephoton nature of the emission was verified by the second-order correlation function up to 90 K, the highest temperature to date for site-controlled quantum dots. Micro-photoluminescence study on individual quantum dots showed linearly polarized single exciton emission with a lifetime of a few nanoseconds. The dimensions of these quantum dots were well controlled to the precision of state-of-the-art fabrication technologies, as reflected in the uniformity of their optical properties. The yield of optically active quantum dots was greater than 90%, among which 13%-25% exhibited single photon emission at 10 K.Semiconductor quantum dots (QDs) have diverse quantum photonic applications [1,2] [2] However, most work to date has been based on self-assembled QDs in III-As and III-P materials, which face severe limitations in operating temperature and scalability. III-As and III-P QDs typically operate at cryogenic temperatures due to the relatively small exciton binding energies and QD-barrier band offsets. Furthermore, self-assembled QDs are formed at random locations and suffer from large inhomogeneity in size and spectral distribution, which prevents controlled coupling of multiple QDs or coupling of QDs with cavities. In this letter, we report single photon emission from sitecontrolled single InGaN/GaN QDs that are scalable for manufacturing and can be readily integrated with cavities.To achieve cryo-free operation, III-N QDs with large QD-barrier band offsets and exciton binding energies have emerged as one of the most promising solutions. Single photon emission has been reported up to 200 K, although only in a self-assembled GaN/AlN QD[10] and an InGaN QD in a self-organized AlGaN nanowire. [11] To control the position of a III-N QD, various approaches have been explored. [12][13][14][15][16][17][18] To date, QD-like emission has only been reported from dots formed at the apex of a sitecontrolled GaN pyramid [12,17] and dots at the top of a site-controlled AlGaN nanowire.[18] But no single photon emission has been reported from these systems yet.In this work, we fabricated site-controlled InGaN/GaN QDs by dry etching of a planar single quantum well * dengh@umich.edu † peicheng@umich.edu (QW). This structure has been applied to III-As systems but with very limited success, due to the detrimental surface effects introduced by the etched sidewall. [19] In contrast, the surface recombination velocity of III-N is 2-3 orders of magnitude slower than that of IIIAs. [20,21] Bright luminescence has been observed from ensembles of III-N nano-pillars etched from multiple QW structures, [13][14][15] and from a single quantum disk at the room temperature.[22] Yet no clear evidence of single photon emission from these structures have been reported so far. Here we not only show single photon emission from our lithographically defined, scalable single InGaN/GaN QDs but also show that this quantum phenomenon survives at temperatures up to 90...

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confidence: 99%

Single photon emission from site-controlled InGaN/GaN quantum dots

Zhang

Teng

Hill

et al. 2013

Applied Physics Letters

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“…2). Nanoring structures are observed in this stage [16][17][18]. As growth proceeded, the effect of growth rate anisotropy started to coalesce different crystal planes around the edge toward the center of the nanoring (Stage II, Fig.…”

Section: Comparison Of Simulations and Experimental Resultsmentioning

confidence: 99%

Origin of broad luminescence from site‐controlled InGaN nanodots fabricated by selective‐area epitaxy

Lee

Aagesen

Thornton

et al. 2014

Physica Status Solidi (a)

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We investigated the origin of broad luminescence observed from an array of site-controlled InGaN nanodots grown by selective area epitaxy (SAE). Epitaxially grown site-controlled nanodots with lateral dimensions <50 nm and an array density of 10 10 cm À2 have been studied. During the nanoscale SAE, incorporation of adatoms from the SiO 2 mask has greater relative importance, resulting in a non-uniform growth profile. This non-uniform growth profile leads to significant broadening of the InGaN nano-heterostructure luminescence. Later in the SAE process, an orientation-dependent growth rate coalesces various crystal planes and transforms these nanostructures into a more uniform array.1 Introduction III-nitride nanostructures possess unique properties, such as a wide tuning range for the emission wavelength [1, 2] large exciton binding energy (!26 meV in bulk) [3,4], and robust spin coherence [5], making them particularly attractive for applications in nanophotonics [6,7], spintronics [5,8], and quantum information processing [7,9]. In many of these applications, it is critical to be able to control the dimension and location of the nanostructures. For example, exciton-cavity coupling requires the precise placement of a single quantum dot heterostructure at the anti-node of an optical cavity [10]. To date, most of the III-nitride nanostructures have been fabricated by the self-assembled Stranski-Krastanow (SK) growth [11], which does not enforce control over the structures' position or dimension, demotivating their practical use on the device level. In recent years, selective area epitaxy (SAE) using metal-organic chemical vapor deposition (MOCVD) has been proven to be feasible for the fabrication of a variety of site-controlled III-nitride nanostructures, such as nanowires [12] and nanodots [2,[13][14][15][16][17][18]. During SAE, the morphology of the three-dimensional epistructure grown within the mask opening evolves according to the growth dynamics [12,19], source supply mechanisms [20,21], and growth rate anisotropy [22,23]. Because optical properties of III-nitride heterostructures strongly

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“…At the low growth temperature of 90 1C, probably only the nuclei formed at the nanohole edges can grow into crystallites, leading to the formation of doughnut-like nanostructures. This kind of doughnut-like nanostructures were also observed in the selective growth of III-nitride materials by MOCVD [18,19]. The positional variation of nucleation probability in nanometer scale can also lead to the growth of ZnO nanotubes with single or multiple channels [20].…”

Section: Methodsmentioning

confidence: 95%