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Authors’ contributions RT carried out the experiments studied on the device fabrication and drafted the manuscript. KH designed the research programs and guided the experiment’s progress. HL, CL, ZW, and JK participated in the mechanism development. All authors read and approved the final manuscript.”
“Background

Self-assembled InAs/GaAs quantum dots (QDs) have been widely investigated due to their applications Pazopanib molecular weight in a variety of optoelectronic devices. High-density QD-based structures are usually needed for devices like lasers and solar cells [1–5], while low-density QD-based structures are preferred for devices such as single-photon sources [6]. Due to the great effects of growth kinetics on QDs’ density and size, both high- and low-density QDs may be acquired by choosing suitable growth techniques and carefully tuning growth conditions. In fact, high-density QDs can be acquired quite easily by the Stranski-Krastanov (S-K) growth mode despite of random QDs’ nucleation and size distribution [7, 8]. However, low-density QDs are relatively harder to acquire. Still several approaches have been developed to obtain low-density QDs structures by extremely low growth rate or precise control of the coverage close to the onset of two-dimensional (2D) to three-dimensional (3D) transition [9, 10]. Additionally, some novel approaches such as modified droplet epitaxy [11, 12] and pre-patterning by electron beam lithography combined with etching techniques [13, 14] are also used to grow low-density QDs. Nevertheless, the growth conditions for low-density QDs structures are accordingly very different from those for high-density QDs structures.