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1. Ab initio theory of the non-resonant Raman effect in crystals at finite temperature in comparison to experiment: The examples of GaN and BaZrS3

Author

Knoop, Florian, Benshalom, Nimrod, Menahem, Matan, Gartner, Paul, Salzillo, Tommaso, Yaffe, Omer, and Hellman, Olle

Subjects
Condensed Matter - Materials Science
Abstract

We present an ab initio theory of the non-resonant Raman scattering process in crystals at finite temperature in direct comparison with experiments. The theory incorporates the scattering geometry and polarization dependence of the Raman process and the small but finite wave vectors of the phonons for correctly describing the scattering with longitudinal optical (LO) modes in optically anisotropic solids. We implement the theory for first-order Raman scattering and showcase the approach for wurtzite Gallium Nitride and the complex chalcogenide perovskite BaZrS3 in comparison to experiment. We subsequently discuss several common estimates for second-order Raman scattering in complex materials, and highlight similarities and differences to established theoretical approaches and simulation protocols both from phonon theory and molecular dynamics., Comment: 16 pages, 8 figures

Published
2024

2. Noncollinear electric dipoles in a polar, chiral phase of CsSnBr$_3$ perovskite

Author

Fabini, Douglas H., Honasoge, Kedar, Cohen, Adi, Bette, Sebastian, McCall, Kyle M., Stoumpos, Constantinos C., Klenner, Steffen, Zipkat, Mirjam, Hoang, Le Phuong, Nuss, Jürgen, Kremer, Reinhard K., Kanatzidis, Mercouri G., Yaffe, Omer, Kaiser, Stefan, and Lotsch, Bettina V.

Subjects
Condensed Matter - Materials Science
Abstract

Polar and chiral crystal symmetries confer a variety of potentially useful functionalities upon solids by coupling otherwise noninteracting mechanical, electronic, optical, and magnetic degrees of freedom. We describe two unstudied phases of the 3D perovskite, CsSnBr$_3$, which emerge below 85 K due to the formation of Sn(II) lone pairs and their interaction with extant octahedral tilts. Phase II (77 K<$T$<85 K, space group $P2_1/m$) exhibits ferroaxial order driven by a noncollinear pattern of lone pair-driven distortions within the plane normal to the unique octahedral tilt axis, preserving the inversion symmetry observed at higher temperatures. Phase I ($T$<77 K, space group $P2_1$) additionally exhibits ferroelectric order due to distortions along the unique tilt axis, breaking both inversion and mirror symmetries. This polar and chiral phase exhibits second harmonic generation from the bulk and a large, intrinsic polarization$-$electrostriction coefficient along the polar axis ($Q_{22}\approx$1.1 m$^4$ C$^{-2}$), resulting in acute negative thermal expansion ($\alpha_V=-9\times10^{-5}$ K$^{-1}$) through the onset of spontaneous polarization. The unprecedented structures of phases I and II were predicted by recursively following harmonic phonon instabilities to generate a tree of candidate structures and subsequently corroborated by synchrotron X-ray powder diffraction and polarized Raman and $^{81}$Br nuclear quadrupole resonance spectroscopies. Relativistic electronic structure scenarios compatible with reported photoluminescence measurements are discussed. Together, the polar symmetry, small bandgap, large spin-orbit splitting of Sn 5$p$ orbitals, and predicted strain sensitivity of the symmetry-breaking distortions suggest bulk samples and epitaxial films of CsSnBr$_3$ or its neighboring solid solutions as strong candidates for bulk Rashba effects.

Published
2024

5. Disentangling the Effects of Structure and Lone-Pair Electrons in the Lattice Dynamics of Halide Perovskites

Author

Caicedo-Dávila, Sebastián, Cohen, Adi, Motti, Silvia G., Isobe, Masahiko, McCall, Kyle M., Grumet, Manuel, Kovalenko, Maksym V., Yaffe, Omer, Herz, Laura M., Fabini, Douglas H., and Egger, David A.

Subjects
Condensed Matter - Materials Science
Abstract

Metal halide perovskites have shown great performance as solar energy materials, but their outstanding optoelectronic properties are paired with unusually strong anharmonic effects. It has been proposed that this intriguing combination of properties derives from the "lone pair" 6$s^2$ electron configuration of the Pb$^{2+}$ cations, and associated weak pseudo-Jahn-Teller effect, but the precise impact of this chemical feature remains unclear. Here we show that in fact an $ns^2$ electron configuration is not a prerequisite for the strong anharmonicity and low-energy lattice dynamics encountered in this class of materials. We combine X-ray diffraction, infrared and Raman spectroscopies, and first-principles molecular dynamics calculations to directly contrast the lattice dynamics of CsSrBr$_3$ with those of CsPbBr$_3$, two compounds which bear close structural similarity but with the former lacking the propensity to form lone pairs on the 5$s^0$ octahedral cation. We exploit low-frequency diffusive Raman scattering, nominally symmetry-forbidden in the cubic phase, as a fingerprint to detect anharmonicity and reveal that low-frequency tilting occurs irrespective of octahedral cation electron configuration. This work highlights the key role of structure in perovskite lattice dynamics, providing important design rules for the emerging class of soft perovskite semiconductors for optoelectronic and light-harvesting devices.

Published
2023

6. Anharmonic Fluctuations Govern the Band Gap of Halide Perovskites

Author

Seidl, Stefan A., Zhu, Xiangzhou, Reuveni, Guy, Aharon, Sigalit, Gehrmann, Christian, Caicedo-Dávila, Sebastián, Yaffe, Omer, and Egger, David A.

Subjects
Condensed Matter - Materials Science
Abstract

We determine the impact of anharmonic thermal vibrations on the fundamental band gap of CsPbBr$_3$, a prototypical model system for the broader class of halide perovskite semiconductors. Through first-principles molecular dynamics and stochastic calculations, we find that anharmonic fluctuations are a key effect in the electronic structure of these materials. We present experimental and theoretical evidence that important characteristics, such as a mildly changing band-gap value across a temperature range that includes phase-transitions, cannot be explained by harmonic phonons thermally perturbing an average crystal structure and symmetry. Instead, the thermal characteristics of the electronic structure are microscopically connected to anharmonic vibrational contributions to the band gap that reach a fairly large magnitude of 450 meV at 425 K.

Published
2023

7. Static and Dynamic Disorder in Formamidinium Lead Bromide Single Crystals

Author

Reuveni, Guy, Diskin-Posner, Yael, Gehrmann, Christian, Godse, Shravan, Gkikas, Giannis G., Buchine, Isaac, Aharon, Sigalit, Korobko, Roman, Stoumpos, Constantinos C., Egger, David A., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

We show that formamidinium lead bromide is unique among the halide perovskite crystals because its inorganic sub-lattice exhibits intrinsic local static disorder that co-exists with a well-defined average crystal structure. Our study combines THz-range Raman-scattering with single-crystal X-ray diffraction and first-principles calculations to probe the inorganic sub-lattice dynamics evolution with temperature in the range of 10-300 K. The temperature evolution of the Raman spectra shows that low-temperature, local static disorder strongly affects the crystal's structural dynamics and phase transitions at higher temperatures., Comment: Total 16 pages, 8 figures (including SI). Submitted to The Journal of Physical Chemistry Letters

Published
2022

8. The Disorder Origin of Raman Scattering In Perovskites Single Crystals

Author

Menahem, Matan, Benshalom, Nimrod, Asher, Maor, Aharon, Sigalit, Korobko, Roman, Safran, Sam, Hellman, Olle, and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

The anharmonic lattice dynamics of oxide and halide perovskites play a crucial role in their mechanical and optical properties. Raman spectroscopy is one of the key methods used to study these structural dynamics. However, despite decades of research, existing interpretations cannot explain the temperature dependence of the observed Raman spectra. We demonstrate the non-monotonic evolution with temperature of the scattering intensity and present a model for 2nd-order Raman scattering that accounts for this unique trend. By invoking a low-frequency anharmonic feature, we are able to reproduce the Raman spectral line-shapes and integrated intensity temperature dependence. Numerical simulations support our interpretation of this low-frequency mode as a transition between two minima of a double-well potential surface. The model can be applied to other dynamically disordered crystal phases, providing a better understanding of the structural dynamics, leading to favorable electronic, optical, and mechanical properties in functional materials.

Published
2022
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9. Dynamic disorder in Bi sub-lattice of $\delta$-Bi$_2$O$_3$

Author

Sharma, Rituraj, Benshalom, Nimrod, Asher, Maor, Brenner, Thomas M., Kossi, Anna, Yaffe, Omer, and Korobko, Roman

Subjects
Condensed Matter - Materials Science
Abstract

$\delta$-Bi$_2$O$_3$ is one of the fastest known solid oxide ion conductors owing to its intrinsically defective fluorite-like structure with 25\% vacant sites in the O sub-lattice. Numerous diffraction measurements and molecular dynamics simulations indicate that the Bi ions construct a cubic, fcc lattice, and the O ions are %distributing and migrating through it. Nonetheless, in this study we present Raman scattering measurements that clearly show that the Bi sub-lattice preserves the monoclinic symmetry of the low temperature phase ($\alpha$-Bi$_2$O$_3$) up to the melting temperature of the crystal. The apparent contradiction between our observations and previous findings suggests that Bi ions oscillate between local minima of the effective potential energy surface. These minima represent the monoclinic phase while the time-averaged structure is the cubic phase. We discuss the implication of these low-frequency oscillations on ion conduction., Comment: 4 pages, 4 figures

Published
2022

10. Phonon-phonon interactions in the polarizarion dependence of Raman scattering

Author

Benshalom, Nimrod, Asher, Maor, Jouclas, Rémy, Korobko, Roman, Schweicher, Guillaume, Liu, Jie, Geerts, Yves, Hellman, Olle, and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

We have found that the polarization dependence of Raman scattering in organic crystals at finite temperatures can only be described by a fourth-rank formalism. This generalization of the second-rank Raman tensor $\mathcal{R}$ stems from the effect of off-diagonal components in the crystal self-energy on the light scattering mechanism. We thus establish a novel manifestation of phonon-phonon interaction in inelastic light scattering, markedly separate from the better-known phonon lifetime.

Published
2022

11. Anharmonic Lattice Dynamics in Sodium Ion Conductors

Author

Brenner, Thomas M., Grumet, Manuel, Till, Paul, Asher, Maor, Zeier, Wolfgang G., Egger, David A., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

We employ THz-range temperature-dependent Raman spectroscopy and first-principles lattice-dynamical calculations to show that the undoped sodium ion conductors Na$_3$PS$_4$ and isostructural Na$_3$PSe$_4$ both exhibit anharmonic lattice dynamics. The anharmonic effects in the compounds involve coupled host lattice -- Na$^+$ ion dynamics that drive the tetragonal-to-cubic phase transition in both cases, but with a qualitative difference in the anharmonic character of the transition. Na$_3$PSe$_4$ shows almost purely displacive character with the soft modes disappearing in the cubic phase as the change of symmetry shifts these modes to the Raman-inactive Brillouin zone boundary. Na$_3$PS$_4$ instead shows order-disorder character in the cubic phase, with the soft modes persisting through the phase transition and remaining active in Raman in the cubic phase, violating Raman selection rules for that phase. Our findings highlight the important role of coupled host lattice -- mobile ion dynamics in vibrational instabilities that are coincident with the exceptional conductivity in these Na$^+$ ion conductors.

Published
2022
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12. The dielectric response of rock-salt crystals at finite temperatures from first principles

Author

Benshalom, Nimrod, Reuveni, Guy, Korobko, Roman, Yaffe, Omer, and Hellman, Olle

Subjects
Condensed Matter - Materials Science
Abstract

We combine ab initio simulations and Raman scattering measurements to demonstrate explicit anharmonic effects in the temperature dependent dielectric response of a NaCl single crystal. We measure the temperature evolution of its Raman spectrum and compare it to both a quasi-harmonic and anharmonic model. Results demonstrate the necessity of including anharmonic lattice dynamics to explain the dielectric response of NaCl, as it is manifested in Raman scattering. Our model fully captures the linear dielectric response of a crystal at finite temperatures and may therefore be used to calculate the temperature dependence of other material properties governed by it., Comment: Manuscript: 8 pages, 4 figures. Supplememtary material: 16 pages, 7 figures

Published
2021
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13. Nanofibers coated with Rare-Earth complexes

Author

Mor, Ori Ezrah, Ohana, Tal, Borne, Adrien, Posner, Yael Diskin, Asher, Maor, Yaffe, Omer, Shanzer, Abraham, and Dayan, Barak

Subjects
Physics - Optics
Abstract

Crystals and fibers doped with Rare Earth (RE) ions provide the basis to most of today's solid-state optical systems, from lasers and telecom devices to emerging potential quantum applications such as quantum memories and optical to microwave conversion. The two platforms, doped crystals and doped fibers, seem mutually exclusive, each having its own strengths and limitations- the former providing high homogeneity and coherence, and the latter offering the advantages of robust optical waveguides. Here we present a hybrid platform that does not rely on doping but rather on coating the waveguide - a tapered silica optical fiber - with a monolayer of complexes, each containing a single RE ion. The complexes offer an identical, tailored environment to each ion, thus minimizing inhomogeneity and allowing tuning of their properties to the desired application. Specifically, we use highly luminescent Yb$^{+3}$[Zn(II)$_{MC}$(QXA)] complexes, which isolate the RE ion from the environment and suppress non-radiative decay channels. We demonstrate that the beneficial optical transitions of the Yb$^{+3}$ are retained after deposition on the tapered fiber, and observe an excited-state lifetime of over 0.9 ms, on par with state-of-the-art Yb doped inorganic crystals.

Published
2021

14. Fast and anomalous exciton diffusion in two-dimensional hybrid perovskites

Author

Ziegler, Jonas D., Zipfel, Jonas, Meisinger, Barbara, Menahem, Matan, Zhu, Xiangzhou, Taniguchi, Takashi, Watanabe, Kenji, Yaffe, Omer, Egger, David A., and Chernikov, Alexey

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Two-dimensional hybrid perovskites are currently in the spotlight of condensed matter and nanotechnology research due to their intriguing optoelectronic and vibrational properties with emerging potential for light-harvesting and -emitting applications. While it is known that these natural quantum wells host tightly bound excitons, the mobilities of these fundamental optical excitations at the heart of the optoelectronic applications are still largely unexplored. Here, we directly monitor the diffusion of excitons through ultrafast emission microscopy from liquid helium to room temperature in hBN-encapsulated two-dimensional hybrid perovskites. We find very fast diffusion with characteristic hallmarks of free exciton propagation for all temperatures above 50 K. In the cryogenic regime we observe nonlinear, anomalous behavior with an exceptionally rapid expansion of the exciton cloud followed by a very slow and even negative effective diffusion. We discuss our findings in view of efficient exciton-phonon coupling, highlighting two-dimensional hybrids as promising platforms for many-body physics research and optoelectronic applications on the nanoscale.

Published
2020
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15. The tetragonal phase of CH$_{3}$NH$_{3}$PbI$_{3}$ is strongly anharmonic

Author

Sharma, Rituraj, Dai, Zhenbang, Gao, Lingyuan, Brenner, Thomas M., Yadgarov, Lena, Zhang, Jiahao, Rakita, Yevgeny, Korobko, Roman, Rappe, Andrew M., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

Halide perovskite (HP) semiconductors exhibit unique strong coupling between the electronic and structural dynamics. The high-temperature cubic phase of HPs is known to be entropically stabilized, with imaginary frequencies in the calculated phonon dispersion relation. Similar calculations, based on the static average crystal structure, predict a stable tetragonal phase with no imaginary modes. This work shows that in contrast to standard theory predictions, the room-temperature tetragonal phase of CH$_{3} $NH$_{3} $PbI$_{3}$ is strongly anharmonic. We use Raman polarization-orientation (PO) measurements and \textit{ab initio} molecular dynamics (AIMD) to investigate the origin and temperature evolution of the strong structural anharmonicity throughout the tetragonal phase. Raman PO measurements reveal a new spectral feature that resembles a soft mode. This mode shows an unusual continuous increase in damping with temperature which is indicative of an anharmonic potential surface. The analysis of AIMD trajectories identifies two major sources of anharmonicity: the orientational unlocking of the [CH$_{3} $NH$_{3}$]$^+$ ions and large amplitude octahedral tilting that continuously increases with temperature. Our work suggests that the standard phonon picture cannot describe the structural dynamics of tetragonal CH$_{3} $NH$_{3} $PbI$_{3}$., Comment: 3 figures

Published
2020
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16. Anharmonic Lattice Vibrations in Small-Molecule Organic Semiconductors

Author

Asher, Maor, Angerer, Daniel, Korobko, Roman, Diskin-Posner, Yael, Egger, David A., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

The intermolecular lattice vibrations in small-molecule organic semiconductors have a strong impact on their functional properties. Existing models treat the lattice vibrations within the harmonic approximation. In this work, we use polarization-orientation (PO) Raman measurements to monitor the temperature-evolution of the symmetry of lattice vibrations in anthracene and pentacene single crystals. Combined with first-principles calculations, we show that at 10 K the lattice dynamics of the crystals are indeed harmonic. However, as the temperature is increased specific lattice modes gradually lose their PO dependence and become more liquid-like. This finding is indicative of a dynamic symmetry breaking of the crystal structure and shows clear evidence of the strongly anharmonic nature of these vibrations. Pentacene also shows a subtle phase transition between 80-150 K, indicated by a change in the vibrational symmetry of one of the lattice modes. Our findings lay the groundwork for accurate predictions and new design rules for high-mobility organic semiconductors at room temperature.

Published
2019
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17. Halide perovskites under polarized light: Vibrational symmetry analysis using polarized Raman

Author

Sharma, Rituraj, Menahem, Matan, Dai, Zhenbang, Gao, Lingyuan, Brenner, Thomas M., Yadgarov, Lena, Zhang, Jiahao, Rakita, Yevgeny, Korobko, Roman, Pinkas, Iddo, Rappe, Andrew M., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

In the last decade, hybrid organic-inorganic halide perovskites have emerged as a new type of semiconductor for photovoltaics and other optoelectronic applications. Unlike standard, tetrahedrally bonded semiconductors (e.g. Si and GaAs), the ionic thermal fluctuations in the halide perovskites (i.e. structural dynamics) are strongly coupled to the electronic dynamics. Therefore, it is crucial to obtain accurate and detailed knowledge about the nature of atomic motions within the crystal. This has proved to be challenging due to low thermal stability and the complex, temperature dependent structural phase sequence of the halide perovskites. Here, these challenges are overcome and a detailed analysis of the mode symmetries is provided in the low-temperature orthorhombic phase of methylammonium-lead iodide. Raman measurements using linearly- and circularly- polarized light at 1.16 eV excitation are combined with density functional perturbation theory (DFPT). By performing an iterative analysis of Raman polarization-orientation dependence and DFPT mode analysis, the crystal orientation is determined. Subsequently, accounting for birefringence effects detected using circularly polarized light excitation, the symmetries of all the observed Raman-active modes at 10 K are assigned.

Published
2019
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18. Anharmonic Host Lattice Dynamics Enable Fast Ion Conduction in Superionic AgI

Author

Brenner, Thomas M., Gehrmann, Christian, Korobko, Roman, Livneh, Tsachi, Egger, David A., and Yaffe, Omer

Subjects
Condensed Matter - Materials Science
Abstract

Basic understanding of the driving forces of ion conduction in solids is critical to the development of new solid-state ion conductors. Physical understanding of ion conduction is limited due to strong deviations from harmonic vibrational dynamics in these systems that are difficult to characterize experimentally and theoretically. We overcome this challenge in superionic AgI by combining THz-frequency Raman polarization-orientation measurements and ab-initio molecular dynamics computations. Our findings demonstrate clear signatures of strong coupling between the mobile ions and host lattice that are of importance to the diffusion process. We first derive a dynamic structural model from the Raman measurements that captures the simultaneous crystal-like and fluid-like properties of this fast-ion conductor. Then we show and discuss the importance of anharmonic relaxational motion that arises from the iodine host lattice by demonstrating its strong impact on ion conduction in superionic AgI.

Published
2019
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20. Liquid-like Free Carrier Solvation and Band Edge Luminescence in Lead-Halide Perovskites

Author

Guo, Yinsheng, Yaffe, Omer, Hull, Trevor D., Owen, Jonathan S., Reichman, David R., and Brus, Louis E.

Subjects
Condensed Matter - Materials Science
Abstract

We report a strongly temperature dependent luminescence Stokes shift in the electronic spectra of both hybrid and inorganic lead-bromide perovskite single crystals. This behavior stands in stark contrast to that exhibited by more conventional crystalline semiconductors. We correlate the electronic spectra with the anti-Stokes and Stokes Raman vibrational spectra. Dielectric solvation theories, originally developed for excited molecules dissolved in polar liquids, reproduce our experimental observations. Our approach, which invokes a classical Debye-like relaxation process, captures the dielectric response originating from an anharmonic LO phonon at about 20 meV (160 cm-1) in the lead-bromide framework. We reconcile the liquid-like picture with more standard solid-state theories of the Stokes shift in crystalline semiconductors.

Published
2018

21. Interplay between organic cations and inorganic framework and incommensurability in hybrid lead-halide perovskite CH3NH3PbBr3

Author

Guo, Yinsheng, Yaffe, Omer, Paley, Daniel W., Beecher, Alexander N., Hull, Trevor D., Szpak, Guilherme, Owen, Jonathan S., Brus, Louis E., and Pimenta, Marcos A.

Subjects
Condensed Matter - Materials Science
Abstract

Organic-inorganic coupling in the hybrid lead-halide perovskite is a central issue in rationalizing the outstanding photovoltaic performance of these emerging materials. Here we compare and contrast the evolution of structure and dynamics of the hybrid CH3NH3PbBr3 and the inorganic CsPbBr3 lead-halide perovskites with temperature, using Raman spectroscopy and single-crystal X-ray diffraction. Results reveal a stark contrast between their order-disorder transitions, abrupt for the hybrid whereas smooth for the inorganic perovskite. X-ray diffraction observes an intermediate incommensurate phase between the ordered and the disordered phases in CH3NH3PbBr3. Low-frequency Raman scattering captures the appearance of a sharp soft mode in the incommensurate phase, ascribed to the theoretically predicted amplitudon mode. Our work highlights the interaction between the structural dynamics of organic cation CH3NH3+ and the lead-halide framework, and unravels the competition between tendencies of the organic and inorganic moieties to minimize energy in the incommensurate phase of the hybrid perovskite structure.

Published
2017
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22. Local polar fluctuations in lead halide perovskite crystals

Author

Yaffe, Omer, Guo, Yinsheng, Tan, Liang Z., Egger, David A., Hull, Trevor, Stoumpos, Constantinos C., Zheng, Fan, Heinz, Tony F., Kronik, Leeor, Kanatzidis, Mercouri G., Owen, Jonathan S, Rappe, Andrew M., Pimenta, Marcos A., and Brus, Louis E.

Subjects
Condensed Matter - Materials Science
Abstract

Hybrid lead-halide perovskites have emerged as an excellent class of photovoltaic materials. Recent reports suggest that the organic molecular cation is responsible for local polar fluctuations that inhibit carrier recombination. We combine low frequency Raman scattering with first-principles molecular dynamics (MD) to study the fundamental nature of these local polar fluctuations. Our observations of a strong central peak in both hybrid (CH$_3$NH$_3$PbBr$_3$) and all-inorganic (CsPbBr$_3$) lead-halide perovskites show that anharmonic, local polar fluctuations are intrinsic to the general lead-halide perovskite structure, and not unique to the dipolar organic cation. MD simulations show that head-to-head Cs motion coupled to Br face expansion, on a few hundred femtosecond time scale, drives the local polar fluctuations in CsPbBr$_3$.

Published
2016
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23. Charge transport across metal/molecular (alkyl) monolayer-Si junctions is dominated by the LUMO level

Author

Yaffe, Omer, Qi, Yabing, Segev, Lior, Scheres, Luc, Puniredd, Sreenivasa Reddy, Ely, Tal, Haick, Hossam, Zuilhof, Han, Kronik, Leeor, Kahn, Antoine, Vilan, Ayelet, and Cahen, David

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

We compare the charge transport characteristics of heavy doped p- and n-Si-alkyl chain/Hg junctions. Photoelectron spectroscopy (UPS, IPES and XPS) results for the molecule-Si band alignment at equilibrium show the Fermi level to LUMO energy difference to be much smaller than the corresponding Fermi level to HOMO one. This result supports the conclusion we reach, based on negative differential resistance in an analogous semiconductor-inorganic insulator/metal junction, that for both p- and n-type junctions the energy difference between the Fermi level and LUMO, i.e., electron tunneling, controls charge transport. The Fermi level-LUMO energy difference, experimentally determined by IPES, agrees with the non-resonant tunneling barrier height deduced from the exponential length-attenuation of the current.

Published
2011
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24. Molecular electronics at Metal / Semiconductor Junctions Si inversion by Sub-nm Molecular Films

Author

Yaffe, Omer, Scheres, Luc, Puniredd, Sreenivasa Reddy, Stein, Nir, Biller, Ariel, Lavan, Rotem Har, Shpaisman, Hagay, Zuilhof, Han, Haick, Hossam, Cahen, David, and Vilan, Ayelet

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Other Condensed Matter
Abstract

Electronic transport across n-Si-alkyl monolayer/Hg junctions is, at reverse and low forward bias, independent of alkyl chain-length from 18 down to 1 or 2 carbons! This and further recent results indicate that electron transport is minority, rather than majority carrier-dominated, occurs via generation and recombination, rather than (the earlier assumed) thermionic emission and, as such is rather insensitive to interface properties. The (m)ethyl results show that binding organic molecules directly to semiconductors provides semiconductor/metal interface control options, not accessible otherwise.

Published
2009
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26. Phonon-Phonon Interactions in the Polarization Dependence of Raman Scattering

Author

Benshalom, Nimrod, Asher, Maor, Jouclas, Remy, Korobko, Roman, Schweicher, Guillaume, Liu, Jie, Geerts, Yves, Hellman, Olle, Yaffe, Omer, Benshalom, Nimrod, Asher, Maor, Jouclas, Remy, Korobko, Roman, Schweicher, Guillaume, Liu, Jie, Geerts, Yves, Hellman, Olle, and Yaffe, Omer

Abstract

We have found that the polarization dependence of Raman scattering in organic crystals at finite temperatures can only be described by a fourth-rank tensor formalism. This generalization of the second-rank Raman tensor stems from the effect of off diagonal components in the crystal self-energy on the light scattering mechanism. We thus establish a novel manifestation of phonon-phonon interaction in inelastic light scattering, markedly separate from the better-known phonon lifetime., Funding Agencies|European Research Counsel [850041]; Swedish Research Council (VR) [2020-04630]; Belgian National Fund for Scientific Research (FNRS) [T.0072.18, T.0094.22, U.G001.19, O.005018F, O.00322]; French Community of Belgian (ARC) [20061]

Published
2023
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27. Submillimeter-Long WS2 Nanotubes: The Pathway to Inorganic Buckypaper

Author

Kundrát, Vojtěch, Rosentveig, Rita, Bukvišová, Kristýna, Citterberg, Daniel, Kolíbal, Miroslav, Keren, Shachar, Pinkas, Iddo, yaffe, Omer, Zak, Alla, Tenne, Reshef, Kundrát, Vojtěch, Rosentveig, Rita, Bukvišová, Kristýna, Citterberg, Daniel, Kolíbal, Miroslav, Keren, Shachar, Pinkas, Iddo, yaffe, Omer, Zak, Alla, and Tenne, Reshef

Abstract

WS2 nanotubes present many new technologies under development, including reinforced biocompatible polymers, membranes, photovoltaic-based memories, ferroelectric devices, etc. These technologies depend on the aspect ratio (length/diameter) of the nanotubes, which was limited to 100 or so. A new synthetic technique is presented, resulting in WS2 nanotubes a few hundred micrometers long and diameters below 50 nm (aspect ratios of 2000-5000) in high yields. Preliminary investigation into the mechanistic aspects of the two-step synthesis reveals that W5O14 nanowhisker intermediates are formed in the first step of the reaction instead of the ubiquitous W18O49 nanowhiskers used in the previous syntheses. The electrical and photoluminescence properties of the long nanotubes were studied. WS2 nanotube-based paper-like material was prepared via a wet-laying process, which could not be realized with the 10 mu m long WS2 nanotubes. Ultrafiltration of gold nanoparticles using the nanotube-paper membrane was demonstrated.

Published
2023

28. A Mechanistic View On The Order-Disorder Phase Transition In Amphidynamic Crystals

Author

Asher, Maor, Bardini, Marco, Catalano, Luca, Jouclas, Remy, Schweicher, Guillaume, Liu, Jie, Korobko, Roman, Cohen, A., Geerts, Yves, Beljonne, David, Yaffe, Omer, Asher, Maor, Bardini, Marco, Catalano, Luca, Jouclas, Remy, Schweicher, Guillaume, Liu, Jie, Korobko, Roman, Cohen, A., Geerts, Yves, Beljonne, David, and Yaffe, Omer

Abstract

We combine temperature-dependent low-frequency Raman measurements and first-principles calculations to obtain a mechanistic understanding of the order–disorder phase transition of 2,7-di-tert-butylbenzo[b]benzo[4,5]thieno[2,3-d]thiophene (ditBu-BTBT) and 6,13-bis(triisopropylsilylethynyl) pentacene (TIPS-pentacene) semiconducting amphidynamic crystals. We identify the lattice normal modes associated with the phase transition by following the position and width of the Raman peaks with temperature and identifying peaks that exhibit nonlinear dependence toward the phase transition temperature. Our findings are interpreted according to the “hardcore mode” model previously used to describe order–disorder phase transitions in inorganic and hybrid crystals with a Brownian sublattice. Within the framework of this model, ditBu-BTBT exhibits an ideal behavior where only one lattice mode is associated with the phase transition. TIPS-pentacene deviates strongly from the model due to strong interactions between lattice modes. We discuss the origin of the different behaviors and suggest side-chain engineering as a tool to control polymorphism in amphidynamic crystals., SCOPUS: ar.j, info:eu-repo/semantics/published

Published
2023

29. Chemical Modifications Suppress Anharmonic Effects in the Lattice Dynamics of Organic Semiconductors

Author

Asher, Maor, primary, Jouclas, Rémy, additional, Bardini, Marco, additional, Diskin-Posner, Yael, additional, Kahn, Nitzan, additional, Korobko, Roman, additional, Kennedy, Alan R., additional, Silva de Moraes, Lygia, additional, Schweicher, Guillaume, additional, Liu, Jie, additional, Beljonne, David, additional, Geerts, Yves, additional, and Yaffe, Omer, additional

Published
2022
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30. Dielectric response of rock-salt crystals at finite temperatures from first principles

Author

Benshalom, Nimrod, Reuveni, Guy, Korobko, Roman, Yaffe, Omer, Hellman, Olle, Benshalom, Nimrod, Reuveni, Guy, Korobko, Roman, Yaffe, Omer, and Hellman, Olle

Abstract

We combine ab initio simulations and Raman scattering measurements to demonstrate explicit anharmonic effects in the temperature-dependent dielectric response of a NaCl single crystal. We measure the temperature evolution of its Raman spectrum and compare it to both a quasiharmonic and anharmonic model. Results demonstrate the necessity of including anharmonic lattice dynamics to explain the dielectric response of NaCl, as it is manifested in Raman scattering. Our model fully captures the linear dielectric response of a crystal at finite temperatures and may therefore be used to calculate the temperature dependence of other material properties governed by it., Funding Agencies|ISFIsrael Science Foundation [1861/17]; BSFUS-Israel Binational Science Foundation [2016650]; ERCEuropean Research Council (ERC)European Commission [850041-ANHARMONIC]; Swedish Research Council (VR)Swedish Research Council [2020-04630]

Published
2022
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31. Diverging Expressions of Anharmonicity in Halide Perovskites

Author

Cohen, Adi, Brenner, Thomas M., Klarbring, Johan, Sharma, Rituraj, Fabini, Douglas H., Korobko, Roman, Nayak, Pabitra K., Hellman, Olle, Yaffe, Omer, Cohen, Adi, Brenner, Thomas M., Klarbring, Johan, Sharma, Rituraj, Fabini, Douglas H., Korobko, Roman, Nayak, Pabitra K., Hellman, Olle, and Yaffe, Omer

Abstract

Lead-based halide perovskite crystals are shown to have strongly anharmonic structural dynamics. This behavior is important because it may be the origin of their exceptional photovoltaic properties. The double perovskite, Cs2AgBiBr6, has been recently studied as a lead-free alternative for optoelectronic applications. However, it does not exhibit the excellent photovoltaic activity of the lead-based halide perovskites. Therefore, to explore the correlation between the anharmonic structural dynamics and optoelectronic properties in lead-based halide perovskites, the structural dynamics of Cs2AgBiBr6 are investigated and are compared to its lead-based analog, CsPbBr3. Using temperature-dependent Raman measurements, it is found that both materials are indeed strongly anharmonic. Nonetheless, the expression of their anharmonic behavior is markedly different. Cs2AgBiBr6 has well-defined normal modes throughout the measured temperature range, while CsPbBr3 exhibits a complete breakdown of the normal-mode picture above 200 K. It is suggested that the breakdown of the normal-mode picture implies that the average crystal structure may not be a proper starting point to understand the electronic properties of the crystal. In addition to our main findings, an unreported phase of Cs2AgBiBr6 is also discovered below approximate to 37 K., Funding Agencies|European Research Concil [850041 - ANHARMONIC]; Alexander von Humboldt FoundationAlexander von Humboldt Foundation; Department of Atomic Energy, Government of IndiaDepartment of Atomic Energy (DAE) [RTI 4007]; SERB IndiaDepartment of Science & Technology (India)Science Engineering Research Board (SERB), India [CRG/2020/003877]; Swedish Research Council (VR)Swedish Research Council [2020-04630, 2021-00486]; Swedish Research CouncilSwedish Research CouncilEuropean Commission [2018-05973]

Published
2022
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33. Effect of Molecule–Surface Reaction Mechanism on the Electronic Characteristics and Photovoltaic Performance of Molecularly Modified Si

Author

Yaffe, Omer, Ely, Tal, Har-Lavan, Rotem, Egger, David A., Johnston, Steve, Cohen, Hagai, Kronik, Leeor, Vilan, Ayelet, and Cahen, David

Subjects
Article
Abstract

We report on the passivation properties of molecularly modified, oxide-free Si(111) surfaces. The reaction of 1-alcohol with the H-passivated Si(111) surface can follow two possible paths, nucleophilic substitution (SN) and radical chain reaction (RCR), depending on adsorption conditions. Moderate heating leads to the SN reaction, whereas with UV irradiation RCR dominates, with SN as a secondary path. We show that the site-sensitive SN reaction leads to better electrical passivation, as indicated by smaller surface band bending and a longer lifetime of minority carriers. However, the surface-insensitive RCR reaction leads to more dense monolayers and, therefore, to much better chemical stability, with lasting protection of the Si surface against oxidation. Thus, our study reveals an inherent dissonance between electrical and chemical passivation. Alkoxy monolayers, formed under UV irradiation, benefit, though, from both chemical and electronic passivation because under these conditions both SN and RCR occur. This is reflected in longer minority carrier lifetimes, lower reverse currents in the dark, and improved photovoltaic performance, over what is obtained if only one of the mechanisms operates. These results show how chemical kinetics and reaction paths impact electronic properties at the device level. It further suggests an approach for effective passivation of other semiconductors.

Published
2013

34. A Similarity Based Model for Ordered Categorical Data

Author

Gayer, Gabi, Offer Lieberman, and Yaffe, Omer

Abstract

In a large variety of applications the data for a variable we wish to explain is ordered and categorical. In this paper we present a new similarity-based model for the scenario and investigate its properties. We establish that the process is ψ-mixing and strictly stationary and derive the explicit form of the autocorrelation function (ACF) in some special cases. Consistency and asymptotic normality of the maximum likelihood estimator (MLE) of the model’s parameters are proven. A simulation study supports our findings. The results are applied to the Netflix data set, comprised of a survey on users’ grading of movies.

Published
2017
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36. Engineering plastic phase transitions via solid solutions: the case of 'reordering frustration' in ionic plastic crystals of hydroxyquinuclidinium salts

Author

Samet Ocak, Rebecca Birolo, Gianluca Carì, Simone Bordignon, Michele R. Chierotti, Dario Braga, Roberto Gobetto, Tommaso Salzillo, Elisabetta Venuti, Omer Yaffe, Simone d'Agostino, Ocak, Samet, Birolo, Rebecca, Carì, Gianluca, Bordignon, Simone, Chierotti, Michele R., Braga, Dario, Gobetto, Roberto, Salzillo, Tommaso, Venuti, Elisabetta, Yaffe, Omer, and d'Agostino, Simone

Subjects
plastic crystals, crystalline solid solutions, reordering-frustration, crystal engineering, Process Chemistry and Technology, Biomedical Engineering, Energy Engineering and Power Technology, Solid-state NMR, Industrial and Manufacturing Engineering, Ionic Plastic Crystalline Materials, Crystal Engineering, Chemistry (miscellaneous), Materials Chemistry, Crystal Engineering, Ionic Plastic Crystalline Materials, Plastic Crystals, Solid-state NMR, Hydroxyquinuclidinium salts, Hydroxyquinuclidinium salts, Chemical Engineering (miscellaneous), Plastic Crystals
Abstract

A family of salts of R-(+)-(3)-hydroxyquinuclidinium [QH]+, with SO42−, BPh4−, BF4− and PF6− counter-anions, have been prepared by the metathesis of [QH]Cl and metal salts of the corresponding anions. Solid solutions of formula [QH](PF6)x(BF4)1−x for x = 0.9, 0.8, 0.7 have also been obtained. The crystalline materials have been investigated by a combination of solid-state techniques, including variable temperature XRD, thermal analyses, multinuclear (11B, 13C, 15N, 19F, and 31P) solid-state NMR spectroscopy, variable temperature wideline 19F T1 relaxation measurements, and micro-Raman spectroscopy to investigate their thermal stability and phase transition behaviors. It has been shown that the salts [QH]PF6 and [QH]BF4 undergo an order–disorder solid–solid phase transition to plastic phases, whereas [QH]2SO4·H2O and [QH]BPh4 do not display any plastic phase transition. Doping [QH]BF4 into the [QH]PF6 lattice up to 30% results in the formation of a solid solution that is plastic in an expanded thermal range, thanks to a phenomenon that we describe here for the first time as “reordering frustration”.

Published
2022

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