Search

Your search keyword '"Côté, Michel"' showing total 441 results
Start Over Author "Côté, Michel"
441 results on '"Côté, Michel"'

1. Large Scale Raman Spectrum Calculations in Defective 2D Materials using Deep Learning

Author

Malenfant-Thuot, Olivier, Kabakiko, Dounia Shaman, Blackburn, Simon, Rousseau, Bruno, and Côté, Michel

Subjects
Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks
Abstract

We introduce a machine learning prediction workflow to study the impact of defects on the Raman response of 2D materials. By combining the use of machine-learned interatomic potentials, the Raman-active $\Gamma$-weighted density of states method and splitting configurations in independant patches, we are able to reach simulation sizes in the tens of thousands of atoms, with diagonalization now being the main bottleneck of the simulation. We apply the method to two systems, isotopic graphene and defective hexagonal boron nitride, and compare our predicted Raman response to experimental results, with good agreement. Our method opens up many possibilities for future studies of Raman response in solid-state physics., Comment: 9 pages, 6 figures

Published
2024

2. Effects of Spin-Orbit Coupling and Thermal Expansion on the Phonon-limited Resistivity of Pb from First Principles

Author

Goudreault, Félix Antoine, Poncé, Samuel, Giustino, Feliciano, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

Using density functional theory calculations with spin-orbit coupling (SOC), we report on the temperature-dependent thermodynamical properties of Pb: electrical resistivity, thermal expansion (TE), heat capacity, bulk modulus and its pressure derivative. For the former, we employed the state-of-the-art ab initio Boltzmann Transport Equation formalism, and we calculated the effect of TE. In accordance with previous work, we show that SOC improves the description of the phonon dispersion and the resistivity. We argue that this is caused by a joint mutual effect of an increase in the electronic nesting and an increase in the electron-phonon coupling. Interestingly, including TE incorporates non-linearity into the resistivity at high temperatures, whose magnitude depends on whether SOC is included or not. We suggest that mechanisms beyond the quasi-harmonic approximation should be considered to get a better description of Pb with SOC at high temperatures., Comment: 19 pages, 10 figures

Published
2024

3. Second-Order Raman Scattering in Exfoliated Black Phosphorus

Author

Favron, Alexandre, Goudreault, Félix Antoine, Gosselin, Vincent, Groulx, Julien, Côté, Michel, Leonelli, Richard, Germain, Jean-Francis, Phaneuf-L'Heureux, Anne-Laurence, Francoeur, Sébastien, and Martel, Richard

Subjects
Condensed Matter - Materials Science
Abstract

Second-order Raman scattering has been extensively studied in carbon-based nanomaterials, \emph{e.g.} nanotube and graphene, because it activates normally forbidden Raman modes that are sensitive to crystal disorder, such as defects, dopants, strain, etc. The sp$^2$-hybridized carbon systems are, however, the exception among most nanomaterials, where first-order Raman processes usually dominate. Here we report the identification of four second-order Raman modes, named $D_1$, $D_1'$, $D_2$ and $D_2'$, in exfoliated black phosphorus (P(black)), an elemental direct-gap semiconductor exhibiting strong mechanical and electronic anisotropies. Located in close proximity to the $A^1_g$ and $A^2_g$ modes, these new modes dominate at an excitation wavelength of 633 nm. Their evolutions as a function of sample thickness, excitation wavelength, and defect density indicate that they are defect-activated and involve high-momentum phonons in a doubly-resonant Raman process. \emph{Ab initio} simulations of a monolayer reveal that the $D'$ and $D$ modes occur through intravalley scatterings with split contributions in the armchair and zigzag directions, respectively. The high sensitivity of these $D$ modes to disorder helps explaining several discrepancies found in the literature., Comment: 18 pages, 5 figures, with supplementary file

Published
2024
Full Text
View/download PDF

4. Strontium Ferrite Under Pressure: Potential Analogue to Strontium Ruthenate

Author

Kazemi-Moridani, Azin, Beck, Sophie, Hampel, Alexander, Tremblay, A. -M. S., Côté, Michel, and Gingras, Olivier

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science
Abstract

Despite the significant attention it has garnered over the last thirty years, the paradigmatic material strontium ruthenate remains the focus of critical questions regarding strongly correlated materials. As an alternative platform to unravel some of its perplexing characteristics, we propose to study the isostructural and more correlated material strontium ferrite. Using density functional theory combined with dynamical mean-field theory, we attribute the experimentally observed insulating behavior at zero pressure to strong local electronic correlations generated by Mott and Hund's physics. At high pressure, our simulations reproduce the reported insulator-to-metal transition around 18 GPa. Along with distinctive features of a Hund's metal, the resulting metallic state is found to display an electronic structure analogous to that of strontium ruthenate, suggesting that it could exhibit similar low-energy properties., Comment: 7 pages, 3 figures + 8 pages, 4 figures

Published
2023
Full Text
View/download PDF

5. Effect of spin-orbit coupling on the zero-point renormalization of the electronic band gap in cubic materials: First-principles calculations and generalized Fr\'ohlich model

Author

Brousseau-Couture, Véronique, Gonze, Xavier, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

The electronic structure of semiconductors and insulators is affected by ionic motion through electron-phonon interaction, yielding temperature-dependent band gap energies and zero-point renormalization (ZPR) at absolute zero temperature. For polar materials, the most significant contribution to the band gap ZPR can be understood in terms of the Fr\"ohlich model, which focuses on the nonadiabatic interaction between an electron and the macroscopic electrical polarization created by a long-wavelength optical longitudinal phonon mode. On the other hand, spin-orbit interaction (SOC) modifies the bare electronic structure, which will, in turn, affect the electron-phonon interaction and the ZPR. We present a comparative investigation of the effect of SOC on the band gap ZPR of twenty semiconductors and insulators with cubic symmetry using first-principles calculations. We observe a SOC-induced decrease of the ZPR, up to 30%, driven by the valence band edge, which almost entirely originates from the modification of the bare electronic eigenenergies and the decrease of the hole effective masses near the $\Gamma$ point. We also incorporate SOC into a generalized Fr\"ohlich model, addressing the Dresselhaus splitting which occurs in noncentrosymmetric materials, and confirm that the predominance of nonadiabatic effects on the band gap ZPR of polar materials is unchanged when including SOC. Our generalized Fr\"ohlich model with SOC provides a reliable estimate of the SOC-induced decrease of the polaron formation energy obtained from first principles and brings to light some fundamental subtleties in the numerical evaluation of the effective masses with SOC for noncentrosymmetric materials. We finally warn about a possible breakdown of the parabolic approximation within the physically relevant energy range of the Fr\"ohlich interaction for materials with high phonon frequencies treated with SOC., Comment: 34 pages including Supplemental Material; 10 figures, 1 table, 3 Supplementary figures, 9 Supplementary tables

Published
2023
Full Text
View/download PDF

6. Zero-point lattice expansion and band gap renormalization: Gr\'uneisen approach versus free energy minimization

Author

Brousseau-Couture, Véronique, Godbout, Émile, Gonze, Xavier, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

The zero-point lattice expansion (ZPLE) is a small variation of the lattice parameters induced by the presence of phonons in a material compared to the static lattice picture. It contributes significantly to the zero-point renormalization (ZPR) of the band gap energy, but its consequences have not been investigated as thoroughly as those stemming from electron-phonon interactions. In the usual first-principles approach, one evaluates the ZPLE by minimizing the $T=0$ K Helmholtz free energy. In this work, we show that the formalism based on the Gr\"uneisen parameters, which commonly neglects zero-point effects, can be efficiently used to compute ZPLE for both isotropic and anisotropic materials at much lower computational cost. We systematically test this formalism on 22 cubic and wurtzite materials and obtain excellent agreement with free energy minimization results for both the ZPLE and the resulting band gap ZPR. We use our results to validate an empirical expression estimating the ZPLE-induced ZPR and unveil its sensitivity to the temperature range involved in estimating the ZPLE from experimental data. Our findings finally reveal that the ZPLE contribution to the band gap ZPR can reach 20% to more than 80% of the electron-phonon interaction contribution for heavier or more ionic materials, including materials containing light atoms. Considering both contributions on an equal footing is thus essential should one attempt to compare theoretical ZPR results with experimental data., Comment: 30 pages, 5 figures, 14 tables. Sec. II D expanded for internal consistency, typo corrected in Fig.4., clarified Tables captions, minor corrections to the text; results and conclusions unchanged

Published
2022
Full Text
View/download PDF

7. Superconductivity in Correlated Multi-Orbital Systems with Spin-Orbit Coupling: Coexistence of Even- and Odd-Frequency Pairing and the Case of Strontium Ruthenate

Author

Gingras, Olivier, Allaglo, Nikita, Nourafkan, Reza, Côté, Michel, and Tremblay, André-Marie S.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

The superconducting order parameter of strontium ruthenate is the center of a lasting puzzle calling for theoretical studies that include the seldom-considered effects of spin-orbit coupling and the frequency-dependence of the order parameters. Here we generalize the frequency-dependent theory of superconductivity mediated by spin and charge fluctuations to include spin-orbit coupling in multi-orbital systems and we characterize the superconducting states using the spin-parity-orbital-time $SPOT$ quantum numbers, group theory, and phase distributions in the complex plane. We derive a pseudospin formulation that maps the inter-pseudospin sector of the normal state Eliashberg equation to a pseudospin-diagonal one. Possible superconducting order parameters for strontium ruthenate are obtained starting from a realistic density-functional-theory normal state. We find that spin-orbit coupling leads to ubiquitous entanglement of spin and orbital quantum numbers, along with notable mixing between even- and odd-frequency correlations. We propose a phase diagram obtained from the temperature dependence of the leading and subleading symmetries in the pseudospin-orbital basis. An accidental degeneracy between leading inter-pseudospin symmetries in strontium ruthenate, B$_{1g}^+$ and A$_{2g}^-$, could resolve apparent experimental contradictions., Comment: 30 pages, 17 figures

Published
2022
Full Text
View/download PDF

8. Frequency-dependent Inter-pseudospin Solutions to Superconducting Strontium Ruthenate

Author

Gingras, Olivier, Allaglo, Nikita, Nourafkan, Reza, Côté, Michel, and Tremblay, André-Marie S.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Quantum Physics
Abstract

The lasting puzzle of the superconducting order parameter of Sr$_2$RuO$_4$ calls for theoretical studies that include seldom-considered effects. Here we include spin-orbit coupling effects on the electronic structure and then solve the linearized Eliashberg equation in a pseudospin basis, including the possibility that spin and charge fluctuations induce frequency-dependent superconducting order parameters. We find that spin-orbit coupling mixes even and odd contributions in orbital, spin and frequency spaces and that leading inter-pseudospin symmetries, B$_{1g}^+$ and A$_{2g}^-$, have intra-orbital components respectively even and odd in Matsubara frequency. An accidental degeneracy between these could resolve apparent experimental contradictions., Comment: 7 pages, 3 figures. Companion paper submitted separately: arXiv:2201.08918

Published
2022

9. Fr\'ohlich polaron effective mass and localization length in cubic materials: degenerate and anisotropic electronic bands

Author

Guster, Bogdan, Melo, Pedro, Martin, Bradley A. A., Brousseau-Couture, Véronique, Miglio, Anna, Giantomassi, Matteo, Côté, Michel, Frost, Jarvist M., Verstraete, Matthieu J., and Gonze, Xavier

Subjects
Condensed Matter - Materials Science
Abstract

Polarons, that is, charge carriers correlated with lattice deformations, are ubiquitous quasiparticles in semiconductors, and play an important role in electrical conductivity. To date most theoretical studies of so-called large polarons, in which the lattice can be considered as a continuum, have focused on the original Fr\"ohlich model: a simple (non-degenerate) parabolic isotropic electronic band coupled to one dispersionless longitudinal optical phonon branch. The Fr\"ohlich model allows one to understand characteristics such as polaron formation energy, radius, effective mass and mobility. Real cubic materials, instead, have electronic band extrema that are often degenerate or anisotropic and present several phonon modes. In the present work, we address such issues. We keep the continuum hypothesis inherent to the large polaron Fr\"ohlich model, but waive the isotropic and non-degeneracy hypotheses, and also include multiple phonon branches. For polaron effective masses, working at the lowest order of perturbation theory, we provide analytical results for the case of anisotropic electronic energy dispersion, with two distinct effective masses (uniaxial) and numerical simulations for the degenerate 3-band case, typical of III-V and II-VI semiconductor valence bands. We also deal with the strong-coupling limit, using a variational treatment: we propose trial wavefunctions for the above-mentioned cases, providing polaron radii and energies. Then, we evaluate the polaron formation energies, effective masses and localisation lengths using parameters representative of a dozen II-VI, III-V and oxide semiconductors, for both electron and hole polarons...In the non-degenerate case, we compare the perturbative approach with the Feynman path integral approach in characterisizing polarons in the weak coupling limit..., Comment: 18 pages, 10 figures in main text; 11 pages, 1 figure in supplementary material

Published
2021
Full Text
View/download PDF

10. Electronic Response Quantities of Solids and Deep Learning

Author

Ryczko, Kevin, Malenfant-Thuot, Olivier, Côté, Michel, and Tamblyn, Isaac

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We introduce a deep neural network (DNN) framework called the \textbf{r}eal-space \textbf{a}tomic \textbf{d}ecomposition \textbf{net}work (\textsc{radnet}), which is capable of making accurate polarization and static dielectric function predictions for solids. We use these predictions to calculate Born-effective charges, longitudinal optical transverse optical (LO-TO) splitting frequencies, and Raman tensors for two prototypical examples: GaAs and BN. We then compute the Raman spectra, and find excellent agreement with \textit{ab initio} techniques. \textsc{radnet} is as good or better than current methodologies. Lastly, we discuss how \textsc{radnet} scales to larger systems, paving the way for predictions of response functions on meso-scale structures with \textit{ab initio} accuracy.

Published
2021

11. Predominance of non-adiabatic effects in zero-point renormalization of the electronic band gap

Author

Miglio, Anna, Brousseau-Couture, Véronique, Godbout, Emile, Antonius, Gabriel, Chan, Yang-Hao, Louie, Steven G., Côté, Michel, Giantomassi, Matteo, and Gonze, Xavier

Subjects
Condensed Matter - Materials Science
Abstract

Electronic and optical properties of materials are affected by atomic motion through the electron-phonon interaction: not only band gaps change with temperature, but even at absolute zero temperature, zero-point motion causes band-gap renormalization. We present a large-scale first-principles evaluation of the zero-point renormalization of band edges beyond the adiabatic approximation. For materials with light elements, the band gap renormalization is often larger than 0.3 eV, and up to 0.7 eV. This effect cannot be ignored if accurate band gaps are sought. For infrared-active materials, global agreement with available experimental data is obtained only when non-adiabatic effects are taken into account. They even dominate zero-point renormalization for many materials, as shown by a generalized Fr\"ohlich model that includes multiple phonon branches, anisotropic and degenerate electronic extrema, whose range of validity is established by comparison with first-principles results., Comment: Note that the supplementary material, included in the main file, is structured differently than in the published version, with a different numbering scheme

Published
2020
Full Text
View/download PDF

12. Temperature dependence of the topological phase transition of BiTeI from first principles

Author

Brousseau-Couture, Véronique, Antonius, Gabriel, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

A topological phase transition from a trivial insulator to a $\mathbb{Z}_2$ topological insulator requires the bulk band gap to vanish. In the case of noncentrosymmetric materials, these phases are separated by a gapless Weyl semimetal phase. However, at finite temperature, the gap is affected by atomic motion, through electron-phonon interaction, and by thermal expansion of the lattice. As a consequence, the phase space of topologically nontrivial phases is affected by temperature. In this paper, the pressure and temperature dependence of the indirect band gap of BiTeI is investigated from first principles. We evaluate the contribution from both electron-phonon interaction and thermal expansion, and show that their combined effect drives the topological phase transition towards higher pressures with increasing temperature. Notably, we find that the sensitivity of both band extrema to pressure and topology for electron-phonon interaction differs significantly according to their leading orbital character. Our results indicate that the Weyl semimetal phase width is increased by temperature, having almost doubled by 100 K when compared to the static lattice results. Our findings thus provide a guideline for experimental detection of the nontrivial phases of BiTeI and illustrate how the phase space of the Weyl semimetal phase in noncentrosymmetric materials can be significantly affected by temperature., Comment: 20 pages, 10 figures, 6 tables

Published
2020
Full Text
View/download PDF

13. Superconducting Symmetries of Sr$_2$RuO$_4$ from First-Principles Electronic Structure

Author

Gingras, Olivier, Nourafkan, Reza, Tremblay, André-Marie S., and Côté, Michel

Subjects
Condensed Matter - Superconductivity
Abstract

Although correlated electronic-structure calculations explain very well the normal state of Sr$_2$RuO$_4$, its superconducting symmetry is still unknown. Here we construct the spin and charge fluctuation pairing interactions based on its correlated normal state. Correlations significantly reduce ferromagnetic in favor of antiferromagnetic fluctuations and increase inter-orbital pairing. From the normal-state Eliashberg equations, we find spin-singlet $d$-wave pairing close to magnetic instabilities. Away from these instabilities, where charge fluctuations increase, we find two time-reversal symmetry-breaking spin-triplets: an odd-frequency $s$-wave, and a doubly-degenerate inter-orbital pairing between $d_{xy}$ and ($d_{yz},d_{xz}$)., Comment: 12 pages, 10 figures (including Supplementary Materials)

Published
2018
Full Text
View/download PDF

14. Unconventional field induced phases in a quantum magnet formed by free radical tetramers

Author

Saul, Andres, Gauthier, Nicolas, Askari, Reza Moosavi, Cote, Michel, Maris, Thierry, Reber, Christian, Lannes, Anthony, Luneau, Dominique, Nicklas, Michael, Law, Joseph M., Green, Elizabeth Lauren, Wosnitza, Jochen, Bianchi, Andrea Daniele, and Feiguin, Adrian

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We report experimental and theoretical studies on the magnetic and thermodynamic properties of NIT-2Py, a free radical-based organic magnet. From magnetization and specific heat measurements we establish the temperature versus magnetic field phase diagram which includes two Bose-Einstein condensates (BEC) and an infrequent half magnetization plateau. Calculations based on density functional theory demonstrates that magnetically this system can be mapped to a quasi-two-dimensional structure of weakly coupled tetramers. Density matrix renormalization group calculations show the unusual characteristics of the BECs where the spins forming the low-field condensate are different than those participating in the high-field one., Comment: 12 pages, 12 figures

Published
2018
Full Text
View/download PDF

17. Dynamical and anharmonic effects on the electron-phonon coupling and the zero-point renormalization of the electronic structure

Author

Antonius, Gabriel, Poncé, Samuel, Lantagne-Hurtubise, Étienne, Auclair, Gabriel, Gonze, Xavier, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

The renormalization of the band structure at zero temperature due to electron-phonon coupling is investigated in diamond, BN, LiF and MgO crystals. We implement a dynamical scheme to compute the frequency-dependent self-energy and the resulting quasiparticle electronic structure. Our calculations reveal the presence of a satellite band below the Fermi level of LiF and MgO. We show that the renormalization factor (Z), which is neglected in the adiabatic approximation, can reduce the zero-point renormalization (ZPR) by as much as 40%. Anharmonic effects in the renormalized eigenvalues at finite atomic displacements are explored with the frozen-phonon method. We use a non-perturbative expression for the ZPR, going beyond the Allen-Heine-Cardona theory. Our results indicate that high-order electron-phonon coupling terms contribute significantly to the zero-point renormalization for certain materials.

Published
2015
Full Text
View/download PDF

19. The Abinit project: Impact, environment and recent developments

Author

Gonze, Xavier, Amadon, Bernard, Antonius, Gabriel, Arnardi, Frédéric, Baguet, Lucas, Beuken, Jean-Michel, Bieder, Jordan, Bottin, François, Bouchet, Johann, Bousquet, Eric, Brouwer, Nils, Bruneval, Fabien, Brunin, Guillaume, Cavignac, Théo, Charraud, Jean-Baptiste, Chen, Wei, Côté, Michel, Cottenier, Stefaan, Denier, Jules, Geneste, Grégory, Ghosez, Philippe, Giantomassi, Matteo, Gillet, Yannick, Gingras, Olivier, Hamann, Donald R., Hautier, Geoffroy, He, Xu, Helbig, Nicole, Holzwarth, Natalie, Jia, Yongchao, Jollet, François, Lafargue-Dit-Hauret, William, Lejaeghere, Kurt, Marques, Miguel A.L., Martin, Alexandre, Martins, Cyril, Miranda, Henrique P.C., Naccarato, Francesco, Persson, Kristin, Petretto, Guido, Planes, Valentin, Pouillon, Yann, Prokhorenko, Sergei, Ricci, Fabio, Rignanese, Gian-Marco, Romero, Aldo H., Schmitt, Michael Marcus, Torrent, Marc, van Setten, Michiel J., Van Troeye, Benoit, Verstraete, Matthieu J., Zérah, Gilles, and Zwanziger, Josef W.

Published
2020
Full Text
View/download PDF

20. Efficient dielectric matrix calculations using the Lanczos algorithm for fast many-body $G_0W_0$ implementations

Author

Janssen, Jonathan Laflamme, Rousseau, Bruno, and Côté, Michel

Subjects
Condensed Matter - Materials Science
Abstract

We present a $G_0W_0$ implementation that assesses the two major bottlenecks of traditional plane-waves implementations, the summations over conduction states and the inversion of the dielectric matrix, without introducing new approximations in the formalism. The first bottleneck is circumvented by converting the summations into Sternheimer equations. Then, the novel avenue of expressing the dielectric matrix in a Lanczos basis is developed, which reduces the matrix size by orders of magnitude while being computationally efficient. We also develop a model dielectric operator that allows us to further reduce the size of the dielectric matrix without accuracy loss. Furthermore, we develop a scheme that reduces the numerical cost of the contour deformation technique to the level of the lightest plasmon pole model. Finally, the use of the simplified quasi-minimal residual scheme in replacement of the conjugate gradients algorithm allows a direct evaluation of the $G_0W_0$ corrections at the desired real frequencies, without need for analytical continuation. The performance of the resulting $G_0W_0$ implementation is demonstrated by comparison with a traditional plane-waves implementation, which reveals a 500-fold speedup for the silane molecule. Finally, the accuracy of our $G_0W_0$ implementation is demonstrated by comparison with other $G_0W_0$ calculations and experimental results., Comment: 19 pages, 2 figures

Published
2014
Full Text
View/download PDF

21. The temperature dependence of electronic eigenenergies in the adiabatic harmonic approximation

Author

Poncé, Samuel, Antonius, Gabriel, Gillet, Yannick, Boulanger, Paul, Janssen, Jonathan Laflamme, Marini, Andrea, Côté, Michel, and Gonze, Xavier

Subjects
Condensed Matter - Materials Science
Abstract

The renormalization of electronic eigenenergies due to electron-phonon interactions (temperature dependence and zero-point motion effect) is important in many materials. We address it in the adiabatic harmonic approximation, based on first principles (e.g. Density-Functional Theory), from different points of view: directly from atomic position fluctuations or, alternatively, from Janak's theorem generalized to the case where the Helmholtz free energy, including the vibrational entropy, is used. We prove their equivalence, based on the usual form of Janak's theorem and on the dynamical equation. We then also place the Allen-Heine-Cardona (AHC) theory of the renormalization in a first-principle context. The AHC theory relies on the rigid-ion approximation, and naturally leads to a self-energy (Fan) contribution and a Debye-Waller contribution. Such a splitting can also be done for the complete harmonic adiabatic expression, in which the rigid-ion approximation is not required. A numerical study within the Density-Functional Perturbation theory framework allows us to compare the AHC theory with frozen-phonon calculations, with or without the rigid-ion terms. For the two different numerical approaches without rigid-ion terms, the agreement is better than 7 $\mu$eV in the case of diamond, which represent an agreement to 5 significant digits. The magnitude of the non rigid-ion terms in this case is also presented, distinguishing specific phonon modes contributions to different electronic eigenenergies.

Published
2014
Full Text
View/download PDF

22. Phonon-Induced Transparency in Functionalized Single Layer Graphene

Author

Rousseau, Bruno, Lapointe, François, Nguyen, Minh, Biron, Maxime, Gaufrès, Etienne, Choubak, Saman, Han, Zheng, Bouchiat, Vincent, Desjardins, Patrick, Côté, Michel, and Martel, Richard

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

Herein, intervalley scattering is exploited to account for anomalous antiresonances in the infrared spectra of doped and disordered single layer graphene. We present infrared spectroscopy measurements of graphene grafted with iodophenyl moieties in both reflection microscopy and transmission configurations. Asymmetric transparency windows at energies corresponding to phonon modes near the {\Gamma} and K points are observed, in contrast to the featureless spectrum of pristine graphene. These asymmetric antiresonances are demonstrated to vary as a function of the chemical potential. We propose a model which involves coherent intraband scattering with defects and phonons, thus relaxing the optical selection rule forbidding access to ${\bf q} \neq$ {\Gamma} phonons. This interpretation of the new phenomenon is supported by our numerical simulations that reproduce the experimental features.

Published
2014

23. Direct observation of ultrafast long-range charge separation at polymer:fullerene heterojunctions

Author

Provencher, Françoise, Bérubé, Nicolas, Parker, Anthony W., Greetham, Gregory M., Towrie, Michael, Hellmann, Christoph, Côté, Michel, Stingelin, Natalie, Silva, Carlos, and Hayes, Sophia C.

Subjects
Condensed Matter - Materials Science, Physics - Chemical Physics
Abstract

In polymeric semiconductors, charge carriers are polarons, which means that the excess charge deforms the molecular structure of the polymer chain that hosts it. This effect results in distinctive signatures in the vibrational modes of the polymer. We probe polaron photo- generation dynamics at polymer:fullerene heterojunctions by monitoring its time-resolved resonance-Raman spectrum following ultrafast photoexcitation. We conclude that polarons emerge within 200 fs, which is nearly two orders of magnitude faster than exciton localisation in the neat polymer film. Surprisingly, further vibrational evolution on <50-ps timescales is modest, indicating that the polymer conformation hosting nascent polarons is not signif- icantly different from that in equilibrium. This suggests that charges are free from their mutual Coulomb potential, under which vibrational dynamics would report charge-pair relaxation. Our work addresses current debates on the photocarrier generation mechanism at organic semiconductor heterojunctions, and is, to our knowledge, the first direct probe of molecular conformation dynamics during this fundamentally important process in these materials., Comment: 33 pages, please download separately PDF files containing figures (3 figures) and supplementary information

Published
2013
Full Text
View/download PDF

24. Two-dimensional spatial coherence of excitons in semicrystalline polymeric semiconductors: The effect of molecular weight

Author

Paquin, Francis, Yamagata, Hajime, Hestand, Nicholas J., Sakowicz, Maciej, Bérubé, Nicolas, Côté, Michel, Reynolds, Luke X., Haque, Saif A., Stingelin, Natalie, Spano, Frank C., and Silva, Carlos

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter, Physics - Chemical Physics
Abstract

The electronic properties of macromolecular semiconductor thin films depend profoundly on their solid-state microstructure, which in turn is governed, among other things, by the processing conditions selected and the polymer chemical nature and molecular weight. Specifically, low-molecular-weight materials form crystalline domains of cofacially $\pi$-stacked molecules, while the usually entangled nature of higher molecular-weight polymers leads to microstructures comprised of molecularly ordered crystallites interconnected by amorphous regions. Here, we examine the interplay between extended exciton states delocalized along the polymer backbones and across polymer chains within the $\pi$-stack, depending on the structural development with molecular weight. We combine optical spectroscopies, thermal probes, and theoretical modeling, focusing on neat poly(3-hexylthiophene) (P3HT), one of the most extensively studied polymer semiconductors, of weight-average molecular weight of 3-450\,kg/mol. The spatial coherence within the chain is significantly reduced (by nearly 30\%). These observations give valuable structural information; they suggest that the macromolecules in aggregated regions of high-molecular-weight P3HT adopt a more planar conformation compared to low-molecular-weight materials. This results in the observed increase in intrachain exciton coherence. In contrast, shorter chains seem to lead to torsionally more disordered architectures. A rigorous, fundamental description of primary photoexcitations in $\pi$-conjugated polymers is hence developed: two-dimensional excitons are defined by the chain-length dependent molecular arrangement and interconnectivity of the conjugated macromolecules, leading to interplay between intramolecular and intermolecular spatial coherence., Comment: Submitted to Physical Review X on 6 June 2013, 38 pages, 10 figures

Published
2013
Full Text
View/download PDF

25. Bromophenyl functionalization of carbon nanotubes : an ab initio study

Author

Beaudin, Jason, Janssen, Jonathan Laflamme, Hine, Nicholas D. M., Haynes, Peter D., and Côté, Michel

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

We study the thermodynamics of bromophenyl functionalization of carbon nanotubes with respect to diameter and metallic/insulating character using density-functional theory (DFT). On one hand, we show that the activation energy for the grafting of a bromophenyl molecule onto a semiconducting zigzag nanotube ranges from 0.73 eV to 0.76 eV without any clear trend with respect to diameter within numerical accuracy. On the other hand, the binding energy of a single bromophenyl molecule shows a clear diameter dependence and ranges from 1.51 eV for a (8,0) zigzag nanotube to 0.83 eV for a (20,0) zigzag nanotube. This is in part explained by the transition from sp2 to sp3 bonding occurring to a carbon atom of a nanotube when a phenyl is grafted to it and the fact that smaller nanotubes are closer to a sp3 hybridization than larger ones due to increased curvature. Since a second bromophenyl unit can attach without energy barrier next to an isolated grafted unit, they are assumed to exist in pairs. The para configuration is found to be favored for the pairs and their binding energy decreases with increasing diameter, ranging from 4.34 eV for a (7,0) nanotube to 2.27 eV for a (29,0) nanotube. An analytic form for this radius dependence is derived using a tight binding hamiltonian and first order perturbation theory. The 1/R^2 dependance obtained (where R is the nanotube radius) is verified by our DFT results within numerical accuracy. Finally, metallic nanotubes are found to be more reactive than semiconducting nanotubes, a feature that can be explained by a non-zero density of states at the Fermi level for metallic nanotubes., Comment: 7 pages, 5 figures and 3 tables

Published
2012
Full Text
View/download PDF

26. Electron-phonon coupling in the C60 fullerene within the many-body GW approach

Author

Faber, Carina, Janssen, Jonathan Laflamme, Côté, Michel, Runge, E., and Blase, X.

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

We study the electron-phonon coupling in the C60 fullerene within the first-principles GW approach, focusing on the lowest unoccupied t1u three-fold electronic state which is relevant for the superconducting transition in electron doped fullerides. It is shown that the strength of the coupling is significantly enhanced as compared to standard density functional theory calculations with (semi)local functionals, with a 48% increase of the electron-phonon potential Vep. The calculated GW value for the contribution from the Hg modes of 93 meV comes within 4% of the most recent experimental values. The present results call for a reinvestigation of previous density functional based calculations of electron-phonon coupling in covalent systems in general., Comment: 4 pages, 0 figure

Published
2011
Full Text
View/download PDF

27. DFT+U study of magnetic order in doped La$_2$CuO$_4$ crystals

Author

Pesant, Simon and Côté, Michel

Subjects
Condensed Matter - Superconductivity
Abstract

This article presents the results of several magnetic phases of doped La$_{2-x}$Sr$_x$CuO$_4$ using density-functional theory with an added Hubbard term (DFT+U). Doping factors from $x=0$ to 0.25 were examined. We found that a bond centered stripe is the magnetic ground state for $x=1/8$ and $x=1/4$. No stable stripe order was found for $x=1/6$. Analysis of the electron density revealed that apical oxygen atoms, those located above and below the copper atoms in the CuO$_2$ planes, hold a non negligible part of the holes at large doping and present a small spin polarization. Finally, the charge reorganization caused by the magnetic stripe modulation was studied for bond centered and atom centered stripes., Comment: 7 pages, 6 figures (submitted to PRB)

Published
2011
Full Text
View/download PDF

28. Peierls Instability in Carbon Nanotubes

Author

Dumont, Guillaume, Boulanger, Paul, Côté, Michel, and Ernzerhof, Matthias

Subjects
Condensed Matter - Materials Science
Abstract

We present a first-principles study of Peierls distortions in \emph{trans}-polyacetylene, polyacene, and armchair $(n,n)$ carbon nanotubes. Our findings suggest that the ground-state geometries of armchair $(n,n)$ carbon nanotubes, with $n$ up to 6, exhibit a Peierls distortion as it is found for \emph{trans}-polyactetylene. In contrast to previous studies in which no Peierls distortion is found with conventional local and semi-local density functionals, we use a hybrid functional whose exact-exchange admixture has been specifically optimized for the problem at hand., Comment: 4 pages, 2 figures, 2 tables

Published
2010
Full Text
View/download PDF

29. Study of Diketo-Pyrrolo-Pyrrole Polymers for Photovoltaic Applications

Author

Lévesque, Simon, Trevisanutto, Paolo E., Laprade, Jean Frédéric, and Cote, Michel

Subjects
Condensed Matter - Materials Science
Abstract

Using density-functional theory with the hybrid functional B3LYP, we investigate the electronic properties of polymers with diketo-pyrrolo-pyrrole (DPP) unit. We note that some of the polymers studied have LUCO energy similar to the C70-PCBM, or even lower, making them promising candidates for electron transport in organic photovoltaic devices. The homopolymer of DPP is predicted to have a band gap around 1.2 eV and shows a good dispersion of the conduction band.

Published
2009

30. Doping of C$_{60}$-induced electronic states in BN nanopeapods

Author

Timoshevskii, Vladimir and Cote, Michel

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

We report the results of \textit{ab initio} simulations of the electronic properties of a chain of C$_{60}$ molecules encapsulated in a boron nitride nanotube - so called BN-nanopeapod. It is demonstrated that this structure can be effectively doped by depositing potassium atoms on the external wall of the BN-nanotube. The resulting material becomes a true metallic one-dimensional crystal, where the conduction states are formed solely by the fullerene chain. At the doping rate of one K atom per C$_{60}$ molecule, the system shows the density of states at the Fermi level considerably higher than in any of the fullerene crystals presently made. This makes the doped BN-peapod structure an interesting candidate to study a possible superconducting state., Comment: Submitted to Physical Review B

Published
2009
Full Text
View/download PDF

31. Superconductivity near lattice instability: the case of NbC$_{1-x}$N$_x$ and NbN

Author

Blackburn, Simon, Côté, Michel, Louie, Steven G., and Cohen, Marvin L.

Subjects
Condensed Matter - Superconductivity
Abstract

Using density functional theory within the local density approximation we report a study of the electron-phonon coupling in NbC$_{1-x}$N$_x$ and NbN crystals in the rocksalt structure. The Fermi surface of these systems exhibits important nesting. The associated Kohn anomaly greatly increases the electron-phonon coupling and induces a structural instability when the electronic density of states reaches a critical value. Our results reproduce the observed rise in $T_{c}$ from 11.2 K to 17.3 K as the nitrogen doping is increased in NbC$_{1-x}$N$_x$. To further understand the contribution of the structural instability to the rise of the superconducting temperature, we develop a model for the Eliashberg spectral function in which the effect of the unstable phonons is set apart. We show that this model together with the McMillan formula can reproduce the increase of $T_{c}$ near the structural phase transition., Comment: 6 pages, 5 figures, submission PRB

Published
2009
Full Text
View/download PDF

32. Large electronic bandwidth in solution-processable pyrene crystals: The role of close-packed crystal structure

Author

Provencher, Francoise, Laprade, Jean-Frederic, Simard, Gabrielle, Berube, Nicolas, Cote, Michel, and Silva, Carlos

Subjects
Condensed Matter - Materials Science
Abstract

We examine the interdependence of structural and electronic properties of two substituted pyrene crystals by means of combined spectroscopic probes and density-functional theory calculations. One derivative features n-hexyl side groups, while the other one contains branched silanyl groups. Both derivatives form triclinic crystal structures when grown from solution, but the electronic dispersion behavior is significantly different due to differences in $\pi$-$\pi$ overlap along the $a$ crystal axis. Both systems display dispersion of 0.40-0.45 eV in the valence band, suggesting a high intrinsic hole mobility. However, the dispersion is primarily along the a-axis in the silanyl-substituted derivative, but less aligned with this crystal axis in the hexyl-substituted material. This is a direct consequence of the diferences in co-facial $\pi$ electron overlap revealed by the crystallographic studies. We find that photophysical defects, ascribed to excimer-like states, point to the importance of localized trap states. Substituted pyrenes are useful model systems to unravel the interplay of crystal structure and electronic properties in organic semiconductors., Comment: 25 pages, 8 figures

Published
2009
Full Text
View/download PDF

33. High-energy excitonic effects in graphite and graphene

Author

Trevisanutto, Paolo E., Holzmann, Markus, Cote, Michel, and Olevano, Valerio

Subjects
Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter
Abstract

We present ab initio many-body calculations of the optical absorption in bulk graphite, graphene and bilayer of graphene. Electron-hole interaction is included solving the Bethe-Salpeter equation on top of a GW quasiparticle electronic structure. For all three systems, we observe strong excitonic effects at high energy, well beyond the continuum of \pi -> \pi * transitions. In graphite, these affect the onset of \sigma -> \sigma * transitions. In graphene, we predict an excitonic resonance at 8.3 eV arising from a background continuum of dipole forbidden transitions. In the graphene bilayer, the resonance is shifted to 9.6 eV. Our results for graphite are in good agreement with experiments., Comment: 4 pages, 4 figures

Published
2009
Full Text
View/download PDF

34. Colossal C130 Fullertubes: Soluble [5,5] C130-D5h(1) Pristine Molecules with 70 Nanotube Carbons and Two 30-Atom Hemifullerene End-caps

Author

Bourret, Emmanuel, primary, Liu, Xiaoyang, additional, Noble, Cora A., additional, Cover, Kevin, additional, Davidson, Tanisha P., additional, Huang, Rong, additional, Koenig, Ryan M., additional, Reeves, K. Shawn, additional, Vlassiouk, Ivan V., additional, Côté, Michel, additional, Baxter, Jefferey S., additional, Lupini, Andrew R., additional, Geohegan, David B., additional, Dorn, Harry C., additional, and Stevenson, Steven, additional

Published
2023
Full Text
View/download PDF

36. Ab initio study of ladder-type polymers polythiophene and polypyrrole

Author

Pesant, Simon, Boulanger, Paul, Côté, Michel, and Ernzerhof, Matthias

Subjects
Condensed Matter - Materials Science
Abstract

This article presents an \textit{ab initio} study of four polymers, polythiophene, polypyrrole, ladder-type polythiophene, and ladder-type polypyrrole. Upon an analysis of the variation of the band gap when comparing the unconstrained and the ladder-type polymers, a discrepancy was found between the thiophene and the pyrrole polymer families. For polythiophene, the ladder-type polymer has a larger gap than the unconstrained polymer whereas the opposite is found for the pyrrole polymers. The structural properties and the charge densities using the Bader charge analysis of these four compounds are investigated. The different band gap behaviors in thiophene and pyrrole polymers can be explained in terms of the competition between the bond length alternation and the effect of the charge density in the carbon backbone.

Published
2006

40. Colossal C130Fullertubes: Soluble [5,5] C130-D5h(1) Pristine Molecules with 70 Nanotube Carbons and Two 30-Atom Hemifullerene End-caps

Author

Bourret, Emmanuel, Liu, Xiaoyang, Noble, Cora A., Cover, Kevin, Davidson, Tanisha P., Huang, Rong, Koenig, Ryan M., Reeves, K. Shawn, Vlassiouk, Ivan V., Côté, Michel, Baxter, Jefferey S., Lupini, Andrew R., Geohegan, David B., Dorn, Harry C., and Stevenson, Steven

Abstract

We report the seminal experimental isolation and DFT characterization of pristine [5,5] C130-D5h(1) fullertubes. This achievement represents the largest soluble carbon molecule obtained in its pristine form. The [5,5] C130species is the highest aspect ratio fullertube purified to date and now surpasses the recent gigantic [5,5] C120-D5d(1). In contrast to C90, C100, and C120fullertubes, the longer C130-D5hhas morenanotubular carbons (70) than end-cap fullerenyl atoms (60). Starting from 39,393 possible C130isolated pentagon rule (IPR) structures and after analyzing polarizability, retention time, and UV–vis spectra, these three layers of data remarkably predict a single candidate isomer and fullertube, [5,5] C130-D5h(1). This structural assignment is augmented by atomic resolution STEM data showing distinctive and tubular “pill-like” structures with diameters and aspect ratios consistent with [5,5] C130-D5h(1) fullertubes. The high selectivity of the aminopropanol reaction with spheroidal fullerenes permits facile separation and removal of fullertubes from soot extracts. Experimental analyses (HPLC retention time, UV–vis, and STEM) were synergistically used (with polarizability and DFT property calculations) to down select and confirm the C130fullertube structure. Achieving the isolation of a new [5,5] C130-D5hfullertube opens the door to application development and fundamental studies of electron confinement, fluorescence, and metallic character for a fullertube series of molecules with systematic tubular elongation. This [5,5] fullertube family also invites comparative studies with single-walled carbon nanotubes (SWCNTs), nanohorns (SWCNHs), and fullerenes.

Published
2023
Full Text
View/download PDF

42. ABINIT: Overview and focus on selected capabilities.

Author

Romero, Aldo H., Allan, Douglas C., Amadon, Bernard, Antonius, Gabriel, Applencourt, Thomas, Baguet, Lucas, Bieder, Jordan, Bottin, François, Bouchet, Johann, Bousquet, Eric, Bruneval, Fabien, Brunin, Guillaume, Caliste, Damien, Côté, Michel, Denier, Jules, Dreyer, Cyrus, Ghosez, Philippe, Giantomassi, Matteo, Gillet, Yannick, and Gingras, Olivier

Subjects
ELECTRIC properties, BETHE-Salpeter equation, PERTURBATION theory, ELASTIC constants, FINITE fields, RAMAN effect, PSEUDOPOTENTIAL method, POSITRON annihilation
Abstract

abinit is probably the first electronic-structure package to have been released under an open-source license about 20 years ago. It implements density functional theory, density-functional perturbation theory (DFPT), many-body perturbation theory (GW approximation and Bethe–Salpeter equation), and more specific or advanced formalisms, such as dynamical mean-field theory (DMFT) and the "temperature-dependent effective potential" approach for anharmonic effects. Relying on planewaves for the representation of wavefunctions, density, and other space-dependent quantities, with pseudopotentials or projector-augmented waves (PAWs), it is well suited for the study of periodic materials, although nanostructures and molecules can be treated with the supercell technique. The present article starts with a brief description of the project, a summary of the theories upon which abinit relies, and a list of the associated capabilities. It then focuses on selected capabilities that might not be present in the majority of electronic structure packages either among planewave codes or, in general, treatment of strongly correlated materials using DMFT; materials under finite electric fields; properties at nuclei (electric field gradient, Mössbauer shifts, and orbital magnetization); positron annihilation; Raman intensities and electro-optic effect; and DFPT calculations of response to strain perturbation (elastic constants and piezoelectricity), spatial dispersion (flexoelectricity), electronic mobility, temperature dependence of the gap, and spin-magnetic-field perturbation. The abinit DFPT implementation is very general, including systems with van der Waals interaction or with noncollinear magnetism. Community projects are also described: generation of pseudopotential and PAW datasets, high-throughput calculations (databases of phonon band structure, second-harmonic generation, and GW computations of bandgaps), and the library libpaw. abinit has strong links with many other software projects that are briefly mentioned. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

46. Zero-point lattice expansion and band gap renormalization: Grüneisen approach versus free energy minimization

Author

UCL - SST/IMCN/MODL - Modelling, Brousseau-Couture, Véronique, Godbout, Émile, Côté, Michel, Gonze, Xavier, UCL - SST/IMCN/MODL - Modelling, Brousseau-Couture, Véronique, Godbout, Émile, Côté, Michel, and Gonze, Xavier

Abstract

The zero-point lattice expansion (ZPLE) is a small variation of the lattice parameters induced by the presence of phonons in a material compared to the static lattice picture. It contributes significantly to the zero-point renormalization (ZPR) of the band gap energy, but its consequences have not been investigated as thoroughly as those stemming from electron-phonon interactions. In the usual first-principles approach, one evaluates the ZPLE by minimizing the T = 0 K Helmholtz free energy. In this work, we show that the formalism based on the Grüneisen parameters, which commonly neglects zero-point effects, can be efficiently used to compute ZPLE for both isotropic and anisotropic materials at much lower computational cost. We systematically test this formalism on 22 cubic and wurtzite materials and obtain excellent agreement with free energy minimization results for both the ZPLE and the resulting band gap ZPR. We use our results to validate an empirical expression estimating the ZPLE-induced ZPR and unveil its sensitivity to the temperature range involved in estimating the ZPLE from experimental data. Our findings finally reveal that the ZPLE contribution to the band gap ZPR can reach 20% to more than 80% of the electron-phonon interaction contribution for heavier or more ionic materials, including materials containing light atoms. Considering both contributions on an equal footing is thus essential should one attempt to compare theoretical ZPR results with experimental data.

Published
2022

49. Visible Out-of-plane Polarized Luminescence and Electronic Resonance in Black Phosphorus

Author

Schué, Léonard, primary, Goudreault, Félix A., additional, Righi, Ariete, additional, Resende, Geovani C., additional, Lefebvre, Valérie, additional, Godbout, Émile, additional, Tie, Monique, additional, Ribeiro, Henrique B., additional, Heinz, Tony F., additional, Pimenta, Marcos A., additional, Côté, Michel, additional, Francœur, Sébastien, additional, and Martel, Richard, additional

Published
2022
Full Text
View/download PDF

50. Erratum: Fröhlich polaron effective mass and localization length in cubic materials: Degenerate and anisotropic electronic bands [Phys. Rev. B 104 , 235123 (2021)]

Author

Guster, Bogdan, primary, Melo, Pedro, additional, Martin, Bradley A. A., additional, Brousseau-Couture, Véronique, additional, de Abreu, Joao C., additional, Miglio, Anna, additional, Giantomassi, Matteo, additional, Côté, Michel, additional, Frost, Jarvist M., additional, Verstraete, Matthieu J., additional, and Gonze, Xavier, additional

Published
2022
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results