Your search keyword '"Andrey F. Tsatsulnikov"' showing total 4 results

1. Impact of Local Composition on the Emission Spectra of InGaN Quantum-Dot LEDs

Author

Daniele Barettin, Alexei V. Sakharov, Andrey F. Tsatsulnikov, Andrey E. Nikolaev, Alessandro Pecchia, Matthias Auf der Maur, Sergey Yu. Karpov, and Nikolay Cherkashin

Subjects

quantum dots, \({\vec{k} \cdot \vec{p}}\), empirical tight-binding, modeling, Chemistry, QD1-999

Abstract

A possible solution for the realization of high-efficiency visible light-emitting diodes (LEDs) exploits InGaN-quantum-dot-based active regions. However, the role of local composition fluctuations inside the quantum dots and their effect of the device characteristics have not yet been examined in sufficient detail. Here, we present numerical simulations of a quantum-dot structure restored from an experimental high-resolution transmission electron microscopy image. A single InGaN island with the size of ten nanometers and nonuniform indium content distribution is analyzed. A number of two- and three-dimensional models of the quantum dot are derived from the experimental image by a special numerical algorithm, which enables electromechanical, continuum k→·p→, and empirical tight-binding calculations, including emission spectra prediction. Effectiveness of continuous and atomistic approaches are compared, and the impact of InGaN composition fluctuations on the ground-state electron and hole wave functions and quantum dot emission spectrum is analyzed in detail. Finally, comparison of the predicted spectrum with the experimental one is performed to assess the applicability of various simulation approaches.

Published

2023

2. Electromechanically Coupled III-N Quantum Dots

Author

Daniele Barettin, Alexei V. Sakharov, Andrey F. Tsatsulnikov, Andrey E. Nikolaev, and Nikolay Cherkashin

Subjects

quantum dots, electromechanical fields, modeling, epitaxial layer growth, Chemistry, QD1-999

Abstract

We exploit the three-dimensional (3D) character of the strain field created around InGaN islands formed within the multilayer structures spaced by a less than 1-nm-thick GaN layer for the creation of spatially correlated electronically coupled quantum dots (QDs). The laterally inhomogeneous vertical out-diffusion of In atoms during growth interruption is the basic mechanism for the formation of InGaN islands within as-deposited 2D layers. An anisotropic 3D strain field created in the first layer is sufficient to justify the vertical correlation of the islands formed in the upper layers spaced by a sufficiently thin GaN layer. When the thickness of a GaN spacer exceeds 1 nm, QDs from different layers under the same growth conditions emit independently and in the same wavelength range. When extremely thin (less than 1 nm), a GaN spacer is formed solely by applying short GI, and a double wavelength emission in the blue and green spectral ranges evidences the electromechanical coupling. With k→·p→ calculations including electromechanical fields, we model the optoelectronic properties of a structure with three InGaN lens-shaped QDs embedded in a GaN matrix, with three different configurations of In content. The profiles of the band structures are strongly dependent on the In content arrangement, and the quantum-confined Stark effect is significantly reduced in a structure with an increasing gradient of In content from the top to the bottom QD. This configuration exhibits carrier tunneling through the QDs, an increase of wave functions overlap, and evidence emerges of three distinct peaks in the spectral range.

Published

2023

3. SiC/Si Hybrid Substrate Synthesized by the Method of Coordinated Substitution of Atoms: A New Type of Substrate for LEDs

Author

Sviatets, Sergey A. Kukushkin, Lev K. Markov, Alexey S. Pavlyuchenko, Irina P. Smirnova, Andrey V. Osipov, Alexander S. Grashchenko, Andrey E. Nikolaev, Alexey V. Sakharov, Andrey F. Tsatsulnikov, and Genadii V.

Subjects

silicon-carbide LEDs on silicon, AlInGaN/GaN/SiC/Si heterostructures, wide-gap semiconductors, method of coordinated substitution of atoms

Abstract

This paper proposes a new type of substrate for manufacturing LEDs based on AlInGaN heterostructures. Instead of depositing SiC layers on the surface of Si using the conventional method, a new method involving the coordinated substitution of atoms (MCSA) to form the SiC layer is proposed. This new approach enables the growth of epitaxial GaN layers with low defect content and facilitates transfer to any surface. The paper details the technology of manufacturing LEDs on SiC/Si substrates obtained by the MCSA and elaborates on the benefits of using these substrates in LED production. Additionally, the advantages of the growth interface between SiC and Si materials are discussed. Moreover, it is found that thinner SiC layers (

Published

2023

4. AlGaN HEMT Structures Grown on Miscut Si(111) Wafers

Author

Statsenko, Alexei V. Sakharov, Dmitri S. Arteev, Evgenii E. Zavarin, Andrey E. Nikolaev, Wsevolod V. Lundin, Nikita D. Prasolov, Maria A. Yagovkina, Andrey F. Tsatsulnikov, Sergey D. Fedotov, Evgenii M. Sokolov, and Vladimir N.

Subjects

HEMT, carrier mobility, AlGaN, Si, MOVPE, miscut

Abstract

A complex study was performed on a set of AlGaN/GaN high-electron-mobility transistor structures grown by metalorganic vapor phase epitaxy on miscut Si(111) wafers with a highly resistive epitaxial Si layer to investigate the influence of substrate miscut on their properties. The results showed that wafer misorientation had an influence on the strain evolution during the growth and surface morphology, and could have a strong impact on the mobility of 2D electron gas, with a weak optimum at 0.5° miscut angle. A numerical analysis revealed that the interface roughness was a main parameter responsible for the variation in electron mobility.

Published

2023