Your search keyword '"Reticcioli, Michele"' showing total 4 results

1. Polarity compensation mechanisms on the perovskite surface KTaO3(001).

Author

Setvin, Martin, Reticcioli, Michele, Poelzleitner, Flora, Hulva, Jan, Schmid, Michael, Boatner, Lynn A., Franchini, Cesare, and Diebold, Ulrike

Subjects

*PEROVSKITE, *POTASSIUM, *TANTALATES, *ELECTRIC potential, *OXYGEN

Abstract

The stacking of alternating charged planes in ionic crystals creates a diverging electrostatic energyÑa Òpolar catastropheÓÑthat must be compensated at the surface. We used scanning probe microscopies and density functional theory to study compensation mechanisms at the perovskite potassium tantalate (KTaO3) (001) surface as increasing degrees of freedom were enabled.The as-cleaved surface in vacuum is frozen in place but immediately responds with an insulator-to-metal transition and possibly ferroelectric lattice distortions. Annealing in vacuum allows the formation of isolated oxygen vacancies, followed by a complete rearrangement of the top layers into an ordered pattern of KO and TaO2 stripes. The optimal solution is found after exposure to water vapor through the formation of a hydroxylated overlayer with ideal geometry and charge. [ABSTRACT FROM AUTHOR]

Published

2018

2. Real-space investigation of polarons in hematite Fe 2 O 3 .

Author

Redondo J, Reticcioli M, Gabriel V, Wrana D, Ellinger F, Riva M, Franceschi G, Rheinfrank E, Sokolović I, Jakub Z, Kraushofer F, Alexander A, Belas E, Patera LL, Repp J, Schmid M, Diebold U, Parkinson GS, Franchini C, Kocan P, and Setvin M

Abstract

In polarizable materials, electronic charge carriers interact with the surrounding ions, leading to quasiparticle behavior. The resulting polarons play a central role in many materials properties including electrical transport, interaction with light, surface reactivity, and magnetoresistance, and polarons are typically investigated indirectly through these macroscopic characteristics. Here, noncontact atomic force microscopy (nc-AFM) is used to directly image polarons in Fe 2 O 3 at the single quasiparticle limit. A combination of Kelvin probe force microscopy (KPFM) and kinetic Monte Carlo (KMC) simulations shows that the mobility of electron polarons can be markedly increased by Ti doping. Density functional theory (DFT) calculations indicate that a transition from polaronic to metastable free-carrier states can play a key role in migration of electron polarons. In contrast, hole polarons are significantly less mobile, and their hopping is hampered further by trapping centers.

Published

2024

3. Surface chemistry on a polarizable surface: Coupling of CO with KTaO 3 (001).

Author

Wang Z, Reticcioli M, Jakub Z, Sokolović I, Meier M, Boatner LA, Schmid M, Parkinson GS, Diebold U, Franchini C, and Setvin M

Abstract

Polarizable materials attract attention in catalysis because they have a free parameter for tuning chemical reactivity. Their surfaces entangle the dielectric polarization with surface polarity, excess charge, and orbital hybridization. How this affects individual adsorbed molecules is shown for the incipient ferroelectric perovskite KTaO 3 . This intrinsically polar material cleaves along (001) into KO- and TaO 2 -terminated surface domains. At TaO 2 terraces, the polarity-compensating excess electrons form a two-dimensional electron gas and can also localize by coupling to ferroelectric distortions. TaO 2 terraces host two distinct types of CO molecules, adsorbed at equivalent lattice sites but charged differently as seen in atomic force microscopy/scanning tunneling microscopy. Temperature-programmed desorption shows substantially stronger binding of the charged CO; in density functional theory calculations, the excess charge favors a bipolaronic configuration coupled to the CO. These results pinpoint how adsorption states couple to ferroelectric polarization.

Published

2022

4. Polarity compensation mechanisms on the perovskite surface KTaO 3 (001).

Author

Setvin M, Reticcioli M, Poelzleitner F, Hulva J, Schmid M, Boatner LA, Franchini C, and Diebold U

Abstract

The stacking of alternating charged planes in ionic crystals creates a diverging electrostatic energy-a "polar catastrophe"-that must be compensated at the surface. We used scanning probe microscopies and density functional theory to study compensation mechanisms at the perovskite potassium tantalate (KTaO 3 ) (001) surface as increasing degrees of freedom were enabled. The as-cleaved surface in vacuum is frozen in place but immediately responds with an insulator-to-metal transition and possibly ferroelectric lattice distortions. Annealing in vacuum allows the formation of isolated oxygen vacancies, followed by a complete rearrangement of the top layers into an ordered pattern of KO and TaO 2 stripes. The optimal solution is found after exposure to water vapor through the formation of a hydroxylated overlayer with ideal geometry and charge., (Copyright © 2018 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published

2018