Your search keyword '"Tiutiunnyk, Anton"' showing total 5 results

1. Resonant and Non-Resonant Impurity States Related to GaAs/AlGaAs Quantum Well Sub-Bands.

Author

Akimov, Volodymyr, Tulupenko, Viktor, Demediuk, Roman, Tiutiunnyk, Anton, Duque, Carlos A., Morales, Alvaro L., Laroze, David, and Mora-Ramos, Miguel Eduardo

Subjects

CENTER of mass, RESONANT states, BINDING energy, WAVE functions, SEMICONDUCTOR defects

Abstract

The energy positions and wave function shapes of the ground and excited states of impurities, including resonance states, are studied using the expansion of the impurity wave function in basis functions. The structures under study are rectangular GaAs/AlGaAs quantum wells with four different widths. In all cases, the impurity binding energy (relative to the corresponding sub-band) has a maximum at or near the center of the quantum well, decreases as the heterointerface is approached, and apparently has a limit of 0 if the impurity moves deeper into the barrier. If the impurity moves away from the center of the quantum well, then the "center of mass" of the electron charge of non-resonant impurity states follows the impurity atom, and the "center of mass" of the electron charge of the resonant impurity states moves away from it. The effect is more pronounced for the ground and first resonance states for wider quantum wells, and the shifts reach a maximum when the impurity atom is positioned near the midpoint of the path between the quantum well center and the heterointerface. [ABSTRACT FROM AUTHOR]

Published

2025

2. Optoelectronic Response to the Fluor Ion Bond on 4-(4,4,5,5-Tetramethyl-1,3,2-dioxoborolan-2-yl)benzaldehyde.

Author

Guevara, Ulises J., Núñez, Jesús, Pérez, Laura M., Tiutiunnyk, Anton, Urdaneta, Neudo, Cisternas, Eduardo, and Laroze, David

Subjects

CHEMICAL shift (Nuclear magnetic resonance), BORON isotopes, ELECTRON transitions, BORONIC esters, NUCLEAR magnetic resonance, PHOTON emission, FLUORITE

Abstract

Boronate esters are a class of compounds containing a boron atom bonded to two oxygen atoms in an ester group, often being used as precursors in the synthesis of other materials. The characterization of the structure and properties of esters is usually carried out by UV-visible, infrared, and nuclear magnetic resonance (NMR) spectroscopic techniques. With the aim to better understand our experimental data, in this article, the density functional theory (DFT) is used to analyze the UV-visible and infrared spectra, as well as the isotropic shielding and chemical shifts of the hydrogen atoms 1H, carbon 13C and boron 11B in the compound 4-(4,4,5,5-tetramethyl-1,3,2-dioxoborolan-2-yl)benzaldehyde. Furthermore, this study considers the change in its electronic and spectroscopic properties of this particular ester, when its boron atom is coordinated with a fluoride anion. The calculations were carried out using the LSDA and B3LYP functionals in Gaussian-16, and PBE in CASTEP. The results show that the B3LYP functional gives the best approximation to the experimental data. The formation of a coordinated covalent B–F bond highlights the remarkable sensitivity of the NMR chemical shifts of carbon, oxygen, and boron atoms and their surroundings. Furthermore, this bond also highlights the changes in the electron transitions bands n → π* and π → π* during the absorption and emission of a photon in the UV-vis, and in the stretching bands of the C=C bonds, and bending of BO2 in the infrared spectrum. This study not only contributes to the understanding of the properties of boronate esters but also provides important information on the interactions and responses optoelectronic of the compound when is bonded to a fluorine atom. [ABSTRACT FROM AUTHOR]

Published

2024

3. Characterization of the 1-(5-(4,5-Dimethyl-1,3,2-dioxoborolan-2-yl)thiophen-2-yl)ethanone Using NMR 13 C, 1 H and 11 B through the Density Functional Theory.

Author

Guevara, Ulises J., R., Jesús B. Núñez, Lozada-Yavina, Rafael, Tiutiunnyk, Anton, Pérez, Laura M., Díaz, Pablo, Urdaneta, Neudo, and Laroze, David

Subjects

CHEMICAL shift (Nuclear magnetic resonance), DENSITY functional theory, NUCLEAR magnetic resonance, MATERIALS science, WAVE functions, MOLECULAR structure

Abstract

The use of computational methods that allow us to perform characterization on new compounds is not a novelty; nevertheless, the degree of complexity of the structures makes their study more challenging since new techniques and methods are required to adjust to the new structural model. The case of nuclear magnetic resonance characterization of boronate esters is fascinating because of its widespread use in materials science. In this paper, we use density functional theory to characterize the structure of the compound 1-[5-(4,5-Dimethyl-1,3,2-dioxaborolan-2-yl)thiophen-2-yl]ethanonea by means of nuclear magnetic resonance. We studied the compound in its solid form with the PBE–GGA and PBEsol–GGA functionals, with a set of plane wave functions and an augmented wave projector, which included gauge in CASTEP and its molecular structure with the B3LYP functional using the package Gaussian 09. In addition, we performed the optimization and calculation of the chemical shifts and isotropic nuclear magnetic resonance shielding of 1 H, 13 C, and 11 B. Finally, we analyzed and compared the theoretical results with experimental diffractometric data observing a good approximation. [ABSTRACT FROM AUTHOR]

Published

2023

4. Adjustment of Terahertz Properties Assigned to the First Lowest Transition of (D + , X) Excitonic Complex in a Single Spherical Quantum Dot Using Temperature and Pressure.

Author

Aghoutane, Noreddine, Pérez, Laura M., Tiutiunnyk, Anton, Laroze, David, Baskoutas, Sotirios, Dujardin, Francis, Fatimy, Abdelouahad El, El-Yadri, Mohamed, and Feddi, El Mustapha

Subjects

EXCITON theory, PHOTODETECTORS, APPROXIMATION theory, OPTICAL control, REFRACTIVE index, BINDING energy, QUANTUM dots

Abstract

This theoretical study is devoted to the effects of pressure and temperature on the optoelectronic properties assigned to the first lowest transition of the (D + , X) excitonic complex (exciton-ionized donor) inside a single A l A s / G a A s / A l A s spherical quantum dot. Calculations are performed within the effective mass approximation theory using the variational method. Optical absorption and refractive index as function of the degree of confinement, pressure, and temperature are investigated. Numerical calculation shows that the pressure favors the electron-hole and electron-ionized donor attractions which leads to an enhancement of the binding energy, while an increasing of the temperature tends to reduce it. Our investigations show also that the resonant peaks of the absorption coefficient and the refractive index are located in the terahertz region and they undergo a shift to higher (lower) therahertz frequencies when the pressure (temperature) increases. The opposite effects caused by temperature and pressure have great practical importance because they offer an alternative approach for the adjustment and the control of the optical frequencies resulting from the transition between the fundamental and the first excited state of exciton bound to an ionized dopant. The comparison of the optical properties of exciton, impurity and (D + , X) facilitates the experimental identification of these transitions which are often close. Our investigation shows that the optical responses of (D + , X) are located between the exciton (high energy region) and donor impurity (low energy region) peaks. The whole of these conclusions may lead to the novel light detector or source of terahertz range. [ABSTRACT FROM AUTHOR]

Published

2021

5. Strain Effects on the Electronic and Optical Properties of Kesterite Cu 2 ZnGeX 4 (X = S, Se): First-Principles Study.

Author

El Hamdaoui, Jawad, El-Yadri, Mohamed, Farkous, Mohamed, Kria, Mohamed, Courel, Maykel, Ojeda, Miguel, Pérez, Laura M., Tiutiunnyk, Anton, Laroze, David, and Feddi, El Mustapha

Subjects

OPTICAL properties, KESTERITE, POLAR effects (Chemistry), BAND gaps, STRAIN energy

Abstract

Following the chronological stages of calculations imposed by the WIEN2K code, we have performed a series of density functional theory calculations, from which we were able to study the effect of strain on the kesterite structures for two quaternary semiconductor compounds Cu 2 ZnGeS 4 and Cu 2 ZnGeSe 4 . Remarkable changes were found in the electronic and optical properties of these two materials during the application of biaxial strain. Indeed, the band gap energy of both materials decreases from the equilibrium state, and the applied strain is more pronounced. The main optical features are also related to the applied strain. Notably, we found that the energies of the peaks present in the dielectric function spectra are slightly shifted towards low energies with strain, leading to significant refraction and extinction index responses. The obtained results can be used to reinforce the candidature of Cu 2 ZnGeX 4 (X = S, Se) in the field of photovoltaic devices. [ABSTRACT FROM AUTHOR]

Published

2021