Your search keyword '"Kuc, Agnieszka Beata"' showing total 11 results

1. Non-Equilibrium First-Order Exciton Mott Transition at Monolayer Lateral Heterojunctions Visualized by Ultrafast Microscopy

Author

Yuan, Long, Zheng, Biyuan, Zhao, Qiuchen, Kempt, Roman, Brumme, Thomas, Kuc, Agnieszka Beata, Ma, Chao, Deng, Shibin, Pan, Anlian, and Huang, Libai

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Atomically precise lateral heterojunctions based on transition metal dichalcogenides provide a new platform for exploring exciton Mott transition in one-dimension. To investigate the intrinsically non-equilibrium Mott transition, we employed ultrafast microscopy with ~ 200 fs temporal resolution to image the transport of different exciton phases in a type II WSe2-WS1.16Se0.84 lateral heterostructure. These measurements visualized the extremely rapid expansion of a highly non-equilibrium electron-hole (e-h) plasma phase with a Fermi velocity up to 3.2*10^6 cm*s-1. An abrupt first-order exciton Mott transition at a density of ~ 5*10^12 cm-2 at room temperature was revealed by ultrafast microscopy, which could be disguised as a continuous transition in conventional steady-state measurements. These results point to exciting new opportunities for designing atomically thin lateral heterojunctions as novel highways of excitons and collective e-h plasma for high-speed electronic applications.

Published

2021

2. Anomalous Interlayer Exciton Diffusion in Twist-Angle-Dependent Moir\'{e} Potentials of WS$_2$-WSe$_2$ Heterobilayers

Author

Yuan, Long, Zheng, Biyuan, Kunstmann, Jens, Brumme, Thomas, Kuc, Agnieszka Beata, Ma, Chao, Deng, Shibin, Blach, Daria, Pan, Anlian, and Huang, Libai

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The nanoscale periodic potentials introduced by moir\'{e} patterns in semiconducting van der Waals (vdW) heterostructures provide a new platform for designing exciton superlattices. To realize these applications, a thorough understanding of the localization and delocalization of interlayer excitons in the moir\'{e} potentials is necessary. Here, we investigated interlayer exciton dynamics and transport modulated by the moir\'{e} potentials in WS$_2$-WSe$_2$ heterobilayers in time, space, and momentum domains using transient absorption microscopy combined with first-principles calculations. Experimental results verified the theoretical prediction of energetically favorable K-Q interlayer excitons and unraveled exciton-population dynamics that was controlled by the twist-angle-dependent energy difference between the K-Q and K-K excitons. Spatially- and temporally-resolved exciton-population imaging directly visualizes exciton localization by twist-angle-dependent moir\'{e} potentials of ~100 meV. Exciton transport deviates significantly from normal diffusion due to the interplay between the moir\'{e} potentials and strong many-body interactions, leading to exciton-density- and twist-angle-dependent diffusion length. These results have important implications for designing vdW heterostructures for exciton and spin transport as well as for quantum communication applications.

Published

2019

3. Electronic Properties of Defective MoS$_{2}$ Monolayers Subject to Mechanical Deformations: A First-Principles Approach

Author

Bahmani, Mohammad, Faghihnasiri, Mahdi, Lorke, Michael, Kuc, Agnieszka-Beata, and Frauenheim, Thomas

Subjects

Physics - Computational Physics, Condensed Matter - Materials Science

Abstract

Monolayers (ML) of Group-6 transition-metal dichalcogenides (TMDs) are semiconducting two-dimensional materials with direct bandgap, showing promising applications in various fields of science and technology, such as nanoelectronics and optoelectronics. These monolayers can undergo strong elastic deformations, up to about 10\%, without any bond breaking. Moreover, the electronic structure and transport properties, which define the performance of these TMDs monolayers in nanoelectronic devices, can be strongly affected by the presence of point defects, which are often present in the synthetic samples. Thus, it is important to understand both effects on the electronic properties of such monolayers. In this work, we have investigated the electronic structure and energetic properties of defective MoS$_{2}$ monolayers, as subject to various strains, using density functional theory simulations. Our results indicated that strain leads to strong modifications of the defect levels inside the bandgap and their orbital characteristics. Strain also splits the degenerate defect levels up to an amount of 450~meV, proposing novel applications., Comment: 10 pages, 12 figures + SI: 7 pages, 9 figures

Published

2019

4. Two-Dimensional Platinum Diselenide for Nanoelectromechanical Sensors

Author

Heine, Thomas, Miró, Pere, Kuc, Agnieszka Beata, Technische Universität Dresden, Kempt, Roman, Heine, Thomas, Miró, Pere, Kuc, Agnieszka Beata, Technische Universität Dresden, and Kempt, Roman

Abstract

From computation to sensing, two-dimensional materials are revolutionizing the field of nanoscale electronics and devices. They enable the engineering of membranes, circuits and coatings with tailored electronic properties at ultimate, atomic thinness. Yet, the manufacturing processes to obtain these materials are not sufficiently advanced to meet industrial demands. The next step for them to push into the consumer market is the successful, large-scale integration with existing silicon technology. For many two-dimensional materials, this proves challenging due to high synthesis temperatures or low mechanical stability in transfer processes. Not so for two-dimensional noble-metal chalcogenides: PtSe2 is an exemplary candidate because it can be grown at temperatures below 500 ℃, rendering it suitable for facile integration at the back end of the line. Additionally, it features very high stability with respect to moisture, irradiation, and mechanical strain, high carrier mobilities, and electronic properties that can be fine-tuned with the number of layers. These properties collectively make it a very promising material for free-standing nanoelectromechanical sensors, such as piezoresistive pressure sensors and motion detectors for the Internet of Things. Unfortunately, one cannot have their cake and eat it too: The broadly tunable properties of PtSe2 lead to challenges in fabricating devices with reproducible performance. This issue can be overcome with sufficient understanding and control of the nanostructure of PtSe2 thin films. The aim of this thesis is to study these nanostructures in depth, employing state-of-the-art density-functional theory and a machine learning approach to get closer to modelling PtSe2 under realistic conditions. Firstly, the family of noble-metal dichalcogenides is introduced and discussed. Secondly, the role of stacking disorder in PtSe2 is taken into account and its impact on electromechanical properties is analyzed. Lastly, a machine lear

Published

2024

5. Twist-angle-dependent interlayer exciton diffusion in WS2–WSe2 heterobilayers

Author

Yuan, Long, Zheng, Biyuan, Kunstmann, Jens, Brumme, Thomas, Kuc, Agnieszka Beata, Ma, Chao, Deng, Shibin, Blach, Daria, Pan, Anlian, and Huang, Libai

Published

2020

6. Nature and Surface Interactions of Sulfur-Containing Deposits on V2O5-WO3/TiO2 Catalysts for SCR-DeNOx

Author

Rammelt, Thomas, Kuc, Agnieszka-Beata, Böhm, Jürgen, Heine, Thomas, and Gläser, Roger

Published

2019

7. Electronic Properties of Defective MoS2 Monolayers Subject to Mechanical Deformations: A First‐Principles Approach

Author

Bahmani, Mohammad, primary, Faghihnasiri, Mahdi, additional, Lorke, Michael, additional, Kuc, Agnieszka-Beata, additional, and Frauenheim, Thomas, additional

Published

2020

8. Electronic Properties of Defective MoS2 Monolayers Subject to Mechanical Deformations: A First‐Principles Approach.

Author

Bahmani, Mohammad, Faghihnasiri, Mahdi, Lorke, Michael, Kuc, Agnieszka-Beata, and Frauenheim, Thomas

Subjects

DEFORMATIONS (Mechanics), SEMICONDUCTORS, MONOMOLECULAR films, DENSITY functional theory, ELECTRONIC structure

Abstract

Monolayers (MLs) of group‐6 transition‐metal dichalcogenides (TMDs) are semiconducting 2D materials with direct bandgap, showing promising applications in various fields of science and technology, such as nanoelectronics and optoelectronics. These MLs can undergo strong elastic deformations, up to about 10%, without any bond breaking. Moreover, the electronic structure and transport properties, which define the performance of these TMD MLs in nanoelectronic devices, can be strongly affected by the presence of point defects, which are often present in the synthetic samples. Thus, it is important to understand both effects on the electronic properties of such MLs. Herein, the electronic structure and energetic properties of defective MoS2 MLs are investigated as subject to various strains, using density functional theory simulations. The results indicate that strain leads to strong modifications of the defect levels inside the bandgap and their orbital characteristics. Strain also splits the degenerate defect levels up to an amount of 450 meV, proposing novel applications. [ABSTRACT FROM AUTHOR]

Published

2020

9. Nature and Surface Interactions of Sulfur-Containing Deposits on V2O5-WO3/TiO2 Catalysts for SCR-DeNOx.

Author

Rammelt, Thomas, Kuc, Agnieszka-Beata, Böhm, Jürgen, Heine, Thomas, and Gläser, Roger

Published

2019

10. Probing charge transfer characteristics in a donor–acceptor metal–organic framework by Raman spectroelectrochemistry and pressure-dependence studies

Author

Usov, Pavel M., primary, Leong, Chanel F., additional, Chan, Bun, additional, Hayashi, Mikihiro, additional, Kitagawa, Hiroshi, additional, Sutton, Joshua J., additional, Gordon, Keith C., additional, Hod, Idan, additional, Farha, Omar K., additional, Hupp, Joseph T., additional, Addicoat, Matthew, additional, Kuc, Agnieszka Beata, additional, Heine, Thomas, additional, and D’Alessandro, Deanna M., additional

Published

2018

11. Nature and Surface Interactions of Sulfur-Containing Deposits on V2O5-WO3/TiO2Catalysts for SCR-DeNOx

Author

Rammelt, Thomas, Kuc, Agnieszka-Beata, Böhm, Jürgen, Heine, Thomas, and Gläser, Roger

Abstract

Sulfur-containing deposits form on a monolithic V2O5-WO3/TiO2(VWT) catalyst during SCR-DeNOxwith NH3at 473 and 523 K and pressures up to 500 kPa in the presence of SO2with sulfate contents of 1.7 to 13.0 wt%. Using thermogravimetric analysis and diffuse reflectance infrared spectroscopy, these deposits are determined to be mainly NH4HSO4for SCR temperatures > 523 K. At lower temperatures, (NH4)2SO4is formed. The thermal stability of NH4HSO4supported on different transition metal oxides including V2O5, WO3, TiO2, MoO3, and Al2O3varies with decomposition temperatures from 620 to 820 K. Using DFT calculations, it is shown that the thermal stability of supported NH4HSO4is mainly determined by hydrogen bonding of the HSO4−anions with the metal oxide surface. Increasing electronegativity of the metal atoms of the support oxide leads to weakening of the S-O bonds in the HSO4−anions and to lower decomposition temperatures of the supported NH4HSO4.

Published

2019