Search

Your search keyword '"Yaniv, Gili"' showing total 17 results
Start Over Author "Yaniv, Gili"
17 results on '"Yaniv, Gili"'

1. Resolving the controversy in biexciton binding energy of cesium lead halide perovskite nanocrystals through heralded single-particle spectroscopy

Author

Lubin, Gur, Yaniv, Gili, Kazes, Miri, Ulku, Arin Can, Antolovic, Ivan Michel, Burri, Samuel, Bruschini, Claudio, Charbon, Edoardo, Yallapragada, Venkata Jayasurya, and Oron, Dan

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Chemical Physics, Physics - Optics, Quantum Physics
Abstract

Understanding exciton-exciton interaction in multiply-excited nanocrystals is crucial to their utilization as functional materials. Yet, for lead halide perovskite nanocrystals, which are promising candidates for nanocrystal-based technologies, numerous contradicting values have been reported for the strength and sign of their exciton-exciton interaction. In this work we unambiguously determine the biexciton binding energy in single cesium lead halide perovskite nanocrystals at room temperature. This is enabled by the recently introduced SPAD array spectrometer, capable of temporally isolating biexciton-exciton emission cascades while retaining spectral resolution. We demonstrate that CsPbBr$_3$ nanocrystals feature an attractive exciton-exciton interaction, with a mean biexciton binding energy of 10 meV. For CsPbI$_3$ nanocrystals we observe a mean biexciton binding energy that is close to zero, and individual nanocrystals show either weakly attractive or weakly repulsive exciton-exciton interaction. We further show that within ensembles of both materials, single-nanocrystal biexciton binding energies are correlated with the degree of charge-carrier confinement., Comment: 7+7 pages, 4+4 figures

Published
2021

4. Heralded spectroscopy: a new single-particle probe for nanocrystal photophysics

Author

Lubin, Gur, primary, Tenne, Ron, additional, Ulku, Arin C., additional, Antolović, Ivan M., additional, Burri, Samuel, additional, Karg, Sean, additional, Yallapragada, Venkata Jayasurya, additional, Yaniv, Gili, additional, Kazes, Miri, additional, Amgar, Daniel, additional, Frenkel, Nadav, additional, Bruschini, Claudio E., additional, Charbon, Edoardo, additional, and Oron, Dan, additional

Published
2023
Full Text
View/download PDF

12. Explanation of structural differences and similarities between the AT2Al10 phases (where A=actinide, lanthanide or rare earth element and T=transition metal).

Author

Yaniv, Gili, Fuks, David, and Meshi, Louisa

Subjects
*RARE earth metals, *DENSITY functional theory, *TRANSITION metals, *MAGNETIC properties, *METALS
Abstract

In the current work we have studied the crystallographic relationship between the AT2Al10 phases (where A = actinide, lanthanide and rare earth element and T = transition metal). It is known that with this stoichiometry two structure types exist: tetragonal CaCr2Al10 and orthorhombic YbFe2Al10. It was found that both CaCr2Al10 and YbFe2Al10 types are structural derivatives of the ThMn12 type structure (which has more general formula of ATxAl12−x, with x > 2). CaCr2Al10 structure has a group-subgroup relationship with the ThMn12 structure, while the relationship of the YbFe2Al10 to the ThMn12 was proved applying the strong reflection approach, suggested initially for approximants of quasi-crystals. Proposed here relationship between the studied structures explains the small difference in total energies, calculated using Density Functional Theory. Understanding the connection between these phases allows regarding AT2Al10 composition as somewhat extension of the ATxAl12−x compositional range. Due to the unique magnetic properties of the ATxAl12−x phases, tunable as a function of crystallographic structure, study of structural stability and crystallographic relationships of related phases are of outmost importance. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

14. Radiation Resistance of the U(Al, Si)2 Alloy: Ion-Induced Disordering.

Author

Meshi, Louisa, Yaniv, Gili, Horak, Pavel, Vacik, Jiri, Mykytenko, Natalia, Rafailov, Gennady, Dahan, Itzchak, Fuks, David, and Kiv, Arik

Subjects
*ALUMINUM-silicon alloys, *NUCLEAR reactors, *METAL cladding, *TRANSMISSION electron microscopy, *IRRADIATION
Abstract

During the exploitation of nuclear reactors, various U-Al based ternary intermetallides are formed in the fuel-cladding interaction layer. Structure and physical properties of these intermetallides determine the radiation resistance of cladding and, ultimately, the reliability and lifetime of the nuclear reactor. In current research, U(Al, Si)3 composition was studied as a potential constituent of an interaction layer. Phase content of the alloy of an interest was ordered U(Al, Si)3, structure of which was reported earlier, and pure Al (constituting less than 20 vol % of the alloy). This alloy was investigated prior and after the irradiation performed by Ar ions at 30 keV. The irradiation was performed on the transmission electron microscopy (TEM, JEOL, Japan) samples, characterized before and after the irradiation process. Irradiation induced disorder accompanied by stress relief. Furthermore, it was found that there is a dose threshold for disordering of the crystalline matter in the irradiated region. Irradiation at doses equal or higher than this threshold resulted in almost solely disordered phase. Using the program “Stopping and Range of Ions in Matter” (SRIM), the parameters of penetration of Ar ions into the irradiated samples were estimated. Based on these estimations, the dose threshold for ion-induced disordering of the studied material was assessed. [ABSTRACT FROM AUTHOR]

Published
2018
Full Text
View/download PDF

15. Explanation of structural differences and similarities between the AT2Al10phases (where A=actinide, lanthanide or rare earth element and T=transition metal)

Author

Yaniv, Gili, Fuks, David, and Meshi, Louisa

Abstract

In the current work we have studied the crystallographic relationship between the AT2Al10phases (where A = actinide, lanthanide and rare earth element and T = transition metal). It is known that with this stoichiometry two structure types exist: tetragonal CaCr2Al10and orthorhombic YbFe2Al10. It was found that both CaCr2Al10and YbFe2Al10types are structural derivatives of the ThMn12type structure (which has more general formula of ATxAl12−x, with x> 2). CaCr2Al10structure has a group-subgroup relationship with the ThMn12structure, while the relationship of the YbFe2Al10to the ThMn12was proved applying the strong reflection approach, suggested initially for approximants of quasi-crystals. Proposed here relationship between the studied structures explains the small difference in total energies, calculated using Density Functional Theory. Understanding the connection between these phases allows regarding AT2Al10composition as somewhat extension of the ATxAl12−xcompositional range. Due to the unique magnetic properties of the ATxAl12−xphases, tunable as a function of crystallographic structure, study of structural stability and crystallographic relationships of related phases are of outmost importance.

Published
2019
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results