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101. Ultrafast modification of the electronic structure of a correlated insulator

Author

Vaskivskyi, O. Grånäs I., Wang, X., Thunström, P., Ghimire, S., Knut, R., Söderström, J., Kjellsson, L., Turenne, D., Engel, R. Y., Beye, M., Lu, J., Reid, A. H., Schlotter, W., Coslovich, G., Hoffmann, M., Kolesov, G., Schüßler-Langeheine, C., Styervoyedov, A., Tancogne-Dejean, N., Sentef, M. A., Reis, D. A., Rubio, A., Parkin, S. S. P., Karis, O., Nordgren, J., Rubensson, J. -E., Eriksson, O., and Dürr, H. A.

Subjects
Condensed Matter - Materials Science
Abstract

A non-trivial balance between Coulomb repulsion and kinematic effects determines the electronic structure of correlated electron materials. The use electromagnetic fields strong enough to rival these native microscopic interactions allows us to study the electronic response as well as the timescales and energies involved in using quantum effects for possible applications. We use element-specific transient x-ray absorption spectroscopy and high-harmonic generation to measure the response to ultrashort off-resonant optical fields in the prototypical correlated electron insulator NiO. Surprisingly, fields of up to 0.22 V/{\AA} leads to no detectable changes on the correlated Ni 3d-orbitals contrary to previous predictions. A transient directional charge transfer is uncovered, a behavior that is captured by first-principles theory. Our results highlight the importance of retardation effects in electronic screening, and pinpoints a key challenge in functionalizing correlated materials for ultrafast device operation., Comment: 6 pages, 3 figure, supplemental material not included in document

Published
2020

102. The role of intraband dynamics in the generation of circularly polarized high harmonics from solids

Author

Klemke, Nicolai, Tancogne-Dejean, Nicolas, Rubio, Angel, Kärtner, Franz X., and Mücke, Oliver D.

Subjects
Physics - Optics
Abstract

Recent studies have demonstrated that the polarization states of high harmonics from solids can differ from those of the driving pulses. To gain insights on the microscopic origin of this behavior, we perform one-particle intraband-only calculations and reproduce some of the most striking observations. For instance, our calculations yield circularly polarized harmonics from elliptically polarized pulses that sensitively depend on the driving conditions. Furthermore, we perform experiments on ZnS and find partly similar characteristics as reported from silicon. Comparison to our intraband-only calculations shows reasonable qualitative agreement for a below-band-gap harmonic. We show that intraband dynamics predict depolarization effects for higher field strengths. For harmonics above the band gap, interband dynamics become important and the high-harmonic response to elliptical excitation looks systematically different. Our work proposes a method to distinguish between different high-harmonic generation mechanisms and it could pave the way to compact solid-state high-harmonic sources with controllable polarization states.

Published
2020
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103. Nonlinear twistoptics at symmetry-broken interfaces

Author

Yao, Kaiyuan, Finney, Nathan R., Zhang, Jin, Moore, Samuel L., Xian, Lede, Tancogne-Dejean, Nicolas, Liu, Fang, Ardelean, Jenny, Xu, Xinyi, Halbertal, Dorri, Watanabe, K., Taniguchi, T., Ochoa, Hector, Asenjo-Garcia, Ana, Zhu, Xiaoyang, Basov, D. N., Rubio, Angel, Dean, Cory R., Hone, James, and Schuck, P. James

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

Broken symmetries induce strong nonlinear optical responses in materials and at interfaces. Twist angle can give complete control over the presence or lack of inversion symmetry at a crystal interface, and is thus an appealing knob for tuning nonlinear optical systems. In contrast to conventional nonlinear crystals with rigid lattices, the weak interlayer coupling in van der Waals (vdW) heterostructures allows for arbitrary selection of twist angle, making nanomechanical manipulation of fundamental interfacial symmetry possible within a single device. Here we report highly tunable second harmonic generation (SHG) from nanomechanically rotatable stacks of bulk hexagonal boron nitride (BN) crystals, and introduce the term twistoptics to describe studies of optical properties in dynamically twistable vdW systems. We observe SHG intensity modulated by a factor of more than 50, polarization patterns determined by moir\'e interface symmetry, and enhanced conversion efficiency for bulk crystals by stacking multiple pieces of BN joined by symmetry-broken interfaces. Our study provides a foundation for compact twistoptics architectures aimed at efficient, scalable, and tunable frequency-conversion, and demonstrates SHG as a robust probe of buried vdW interfaces., Comment: 23 Pages, 17 Figures

Published
2020
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104. The CECAM Electronic Structure Library and the modular software development paradigm

Author

Oliveira, Micael J. T., Papior, Nick, Pouillon, Yann, Blum, Volker, Artacho, Emilio, Caliste, Damien, Corsetti, Fabiano, de Gironcoli, Stefano, Elena, Alin M., Garcia, Alberto, Garcia-Suarez, Victor M., Genovese, Luigi, Huhn, William P., Huhs, Georg, Kokott, Sebastian, Kucukbenli, Emine, Larsen, Ask H., Lazzaro, Alfio, Lebedeva, Irina V., Li, Yingzhou, Lopez-Duran, David, Lopez-Tarifa, Pablo, Luders, Martin, Marques, Miguel A. L., Minar, Jan, Mohr, Stephan, Mostofi, Arash A., O'Cais, Alan, Payne, Mike C., Ruh, Thomas, Smith, Daniel G. A., Soler, Jose M., Strubbe, David A., Tancogne-Dejean, Nicolas, Tildesley, Dominic, Torrent, Marc, and Yu, Victor Wen-zhe

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

First-principles electronic structure calculations are very widely used thanks to the many successful software packages available. Their traditional coding paradigm is monolithic, i.e., regardless of how modular its internal structure may be, the code is built independently from others, from the compiler up, with the exception of linear-algebra and message-passing libraries. This model has been quite successful for decades. The rapid progress in methodology, however, has resulted in an ever increasing complexity of those programs, which implies a growing amount of replication in coding and in the recurrent re-engineering needed to adapt to evolving hardware architecture. The Electronic Structure Library (\esl) was initiated by CECAM (European Centre for Atomic and Molecular Calculations) to catalyze a paradigm shift away from the monolithic model and promote modularization, with the ambition to extract common tasks from electronic structure programs and redesign them as free, open-source libraries. They include "heavy-duty" ones with a high degree of parallelisation, and potential for adaptation to novel hardware within them, thereby separating the sophisticated computer science aspects of performance optimization and re-engineering from the computational science done by scientists when implementing new ideas. It is a community effort, undertaken by developers of various successful codes, now facing the challenges arising in the new model. This modular paradigm will improve overall coding efficiency and enable specialists (computer scientists or computational scientists) to use their skills more effectively. It will lead to a more sustainable and dynamic evolution of software as well as lower barriers to entry for new developers., Comment: Revised version as finally accepted by J. Chem. Phys. to appear within the Special Topic in Electronic Structure Software (version prior to JCP's typesetting and proofs)

Published
2020
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105. Role of electron scattering on the high-order harmonic generation from solids

Author

Wang, Chang-Ming, Tancogne-Dejean, Nicolas, Altarelli, Massimo, Rubio, Angel, and Sato, Shunsuke A.

Subjects
Physics - Optics, Condensed Matter - Materials Science
Abstract

We extend the semi-classical trajectory description for the high-order harmonic generation~(HHG) from solids by integrating the effect of electron-scattering. Comparing the extended semi-classical trajectory model with a one-dimensional quantum mechanical simulation, we find that the multi-plateau feature of the HHG spectrum is formed by Umklapp scattering under the electron-hole acceleration dynamics by laser fields. Furthermore, by tracing the scattered trajectories in real-space, the model fairly describes the emitted photon energy and the emission timing of the HHG even in the higher plateau regions. We further consider the loss of trajectories by scattering processes with a mean-free-path approximation and evaluate the HHG cutoff energy as a function of laser wavelength. As a result, we find that the trajectory loss by scattering causes the wavelength independence of the HHG from solids.

Published
2020
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106. Ultrafast Dynamical Lifshitz Transition

Author

Beaulieu, Samuel, Dong, Shuo, Tancogne-Dejean, Nicolas, Dendzik, Maciej, Pincelli, Tommaso, Maklar, Julian, Xian, R. Patrick, Sentef, Michael A., Wolf, Martin, Rubio, Angel, Rettig, Laurenz, and Ernstorfer, Ralph

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

Fermi surface is at the heart of our understanding of metals and strongly correlated many-body systems. An abrupt change in the Fermi surface topology, also called Lifshitz transition, can lead to the emergence of fascinating phenomena like colossal magnetoresistance and superconductivity. While Lifshitz transitions have been demonstrated for a broad range of materials by equilibrium tuning of macroscopic parameters such as strain, doping, pressure and temperature, a non-equilibrium dynamical route toward ultrafast modification of the Fermi surface topology has not been experimentally demonstrated. Combining time-resolved multidimensional photoemission spectroscopy with state-of-the-art TDDFT+$U$ simulations, we introduce a novel scheme for driving an ultrafast Lifshitz transition in the correlated type-II Weyl semimetal T$\mathrm{_{d}}$-MoTe$_{2}$. We demonstrate that this non-equilibrium topological electronic transition finds its microscopic origin in the dynamical modification of the effective electronic correlations. These results shed light on a novel ultrafast scheme for controlling the Fermi surface topology in correlated quantum materials.

Published
2020

107. Photo-molecular high temperature superconductivity

Author

Buzzi, M., Nicoletti, D., Fechner, M., Tancogne-Dejean, N., Sentef, M. A., Georges, A., Dressel, M., Henderson, A., Siegrist, T., Schlueter, J. A., Miyagawa, K., Kanoda, K., Nam, M. -S., Ardavan, A., Coulthard, J., Tindall, J., Schlawin, F., Jaksch, D., and Cavalleri, A.

Subjects
Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons
Abstract

Superconductivity in organic conductors is often tuned by the application of chemical or external pressure. With this type of tuning, orbital overlaps and electronic bandwidths are manipulated, whilst the properties of the molecular building blocks remain virtually unperturbed.Here, we show that the excitation of local molecular vibrations in the charge-transfer salt $\kappa-(BEDT-TTF)_2Cu[N(CN)_2]Br$ induces a colossal increase in carrier mobility and the opening of a superconducting-like optical gap. Both features track the density of quasi-particles of the equilibrium metal, and can be achieved up to a characteristic coherence temperature $T^* \approxeq 50 K$, far higher than the equilibrium transition temperature $T_C = 12.5 K$. Notably, the large optical gap achieved by photo-excitation is not observed in the equilibrium superconductor, pointing to a light induced state that is different from that obtained by cooling. First-principle calculations and model Hamiltonian dynamics predict a transient state with long-range pairing correlations, providing a possible physical scenario for photo-molecular superconductivity., Comment: 11 pages, 7 figures, supplementary material

Published
2020
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108. Enhanced high-harmonic generation from chromium-doped magnesium oxide

Author

Nefedova, V. E., Fröhlich, S., Tancogne-Dejean, N., Boutu, W., Navarrete, F., Ciappina, M. F., Franz, D., Gauthier, D., Hamdou, A., Kaassamani, S., Nicolas, R., Ripault, Q., Jargot, G., Thumm, U., Hanna, M., Georges, P., Rubio, A., and Merdji, H.

Subjects
Physics - Optics
Abstract

High-order harmonic generation (HHG) from crystals offers a new source of coherent extreme ultraviolet (XUV) attosecond radiation., Comment: Significant change of content

Published
2020
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109. Light-induced renormalization of the Dirac quasiparticles in the nodal-line semimetal ZrSiSe

Author

Gatti, G., Crepaldi, A., Puppin, M., Tancogne-Dejean, N., Xian, L., Roth, S., Polishchuk, S., Bugnon, Ph., Magrez, A., Berger, H., Frassetto, F., Poletto, L., Moreschini, L., Moser, S., Bostwick, A., Rotenberg, E., Rubio, A., Chergui, M., and Grioni, M.

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

In nodal-line semimetals linearly dispersing states form Dirac loops in the reciprocal space, with high degree of electron-hole symmetry and almost-vanishing density of states near the Fermi level. The result is reduced electronic screening and enhanced correlations between Dirac quasiparticles. Here we investigate the electronic structure of ZrSiSe, by combining time- and angle-resolved photoelectron spectroscopy with ab initio density functional theory (DFT) complemented by an extended Hubbard model (DFT +U +V). We show that electronic correlations are reduced on an ultrashort timescale by optical excitation of high-energy electrons-hole pairs, which transiently screen the Coulomb interaction. Our findings demonstrate an all-optical method for engineering the band structure of a quantum material., Comment: 6 pages, 3 figures

Published
2019
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110. Octopus, a computational framework for exploring light-driven phenomena and quantum dynamics in extended and finite systems

Author

Tancogne-Dejean, Nicolas, Oliveira, Micael J. T., Andrade, Xavier, Appel, Heiko, Borca, Carlos H., Breton, Guillaume Le, Buchholz, Florian, Castro, Alberto, Corni, Stefano, Correa, Alfredo A., De Giovannini, Umberto, Delgado, Alain, Eich, Florian G., Flick, Johannes, Gil, Gabriel, Gomez, Adrián, Helbig, Nicole, Hübener, Hannes, Jestädt, René, Jornet-Somoza, Joaquim, Larsen, Ask H., Lebedeva, Irina V., Lüders, Martin, Marques, Miguel A. L., Ohlmann, Sebastian T., Pipolo, Silvio, Rampp, Markus, Rozzi, Carlo A., Strubbe, David A., Sato, Shunsuke A., Schäfer, Christian, Theophilou, Iris, Welden, Alicia, and Rubio, Angel

Subjects
Physics - Computational Physics
Abstract

Over the last years extraordinary advances in experimental and theoretical tools have allowed us to monitor and control matter at short time and atomic scales with a high-degree of precision. An appealing and challenging route towards engineering materials with tailored properties is to find ways to design or selectively manipulate materials, especially at the quantum level. To this end, having a state-of-the-art ab initio computer simulation tool that enables a reliable and accurate simulation of light-induced changes in the physical and chemical properties of complex systems is of utmost importance. The first principles real-space-based Octopus project was born with that idea in mind, providing an unique framework allowing to describe non-equilibrium phenomena in molecular complexes, low dimensional materials, and extended systems by accounting for electronic, ionic, and photon quantum mechanical effects within a generalized time-dependent density functional theory framework. The present article aims to present the new features that have been implemented over the last few years, including technical developments related to performance and massive parallelism. We also describe the major theoretical developments to address ultrafast light-driven processes, like the new theoretical framework of quantum electrodynamics density-functional formalism (QEDFT) for the description of novel light-matter hybrid states. Those advances, and other being released soon as part of the Octopus package, will enable the scientific community to simulate and characterize spatial and time-resolved spectroscopies, ultrafast phenomena in molecules and materials, and new emergent states of matter (QED-materials).

Published
2019
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111. Why I killed my copper -- Highlights about the FTTO in the ESR

Author

Moreau, Gabriel, Maire-Amiot, Bernard, Gras, David, Colasuonno, Hervé, Bamberger, Julien, Minet, Aurélien, Péan, Alain, and Dejean, Marie-Goretti

Subjects
Computer Science - Networking and Internet Architecture
Abstract

FTTO means Fiber To The Office, in reference to FTTH (Fibre To The Home), deployed in France for individuals. The principle of FTTO is to cable a building totally in fibre optic, to remove as much copper cabling as possible and install microswitches in each office (duct or adjacent), as near the machines as possible. Users are still connected with standard RJ45 copper wiring. Through questions and answers, we will highlight the reasons why FFTO is a controlled and future-oriented technology.Over the last six years, several building projects within the perimeter of Higher Education and Research have chosen this technology and have seen or will see the light of day. Depending on the project, different topologies and technologies are possible. What is the feedback after these years? Is the result as expected? How is the solution experienced on a day-to-day basis? What security, how is a large switch assembly configured and maintained, what high availability is possible? How is Wi-Fi, IP telephony and all PoE devices integrated? Does FTTO contribute to eco-consumption? How can a FTTO call for tender be set up for a project, what are the essential elements to be included and what are the errors to be avoided at all costs? In the future, what is the life expectancy for its infrastructure and what speeds can be envisaged? The RESINFO FTTO Group is working to provide clear answers to all these questions and to share its experience with the community., Comment: Vid{\'e}o https://replay.jres.org/videos/watch/6de5f575-9da1-4cb7-82af-f3f90aca9b6e Congr\`es , in French, JRES : Les Journ\'ees R\'eseaux de l'Enseignement et de la Recherche, RENATER, Dec 2019, Dijon, France

Published
2019

112. Forward and Backward Feature Selection for Query Performance Prediction

Author

Déjean, Sébastien, Ionescu, Radu Tudor, Mothe, Josiane, and Ullah, Md Zia

Subjects
Computer Science - Information Retrieval, Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

The goal of query performance prediction (QPP) is to automatically estimate the effectiveness of a search result for any given query, without relevance judgements. Post-retrieval features have been shown to be more effective for this task while being more expensive to compute than pre-retrieval features. Combining multiple post-retrieval features is even more effective, but state-of-the-art QPP methods are impossible to interpret because of the black-box nature of the employed machine learning models. However, interpretation is useful for understanding the predictive model and providing more answers about its behavior. Moreover, combining many post-retrieval features is not applicable to real-world cases, since the query running time is of utter importance. In this paper, we investigate a new framework for feature selection in which the trained model explains well the prediction. We introduce a step-wise (forward and backward) model selection approach where different subsets of query features are used to fit different models from which the system selects the best one. We evaluate our approach on four TREC collections using standard QPP features. We also develop two QPP features to address the issue of query-drift in the query feedback setting. We found that: (1) our model based on a limited number of selected features is as good as more complex models for QPP and better than non-selective models; (2) our model is more efficient than complex models during inference time since it requires fewer features; (3) the predictive model is readable and understandable; and (4) one of our new QPP features is consistently selected across different collections, proving its usefulness., Comment: Accepted at SAC 2020

Published
2019

117. The Analytical Validity of Stride Detection and Gait Parameters Reconstruction Using the Ankle-Mounted Inertial Measurement Unit Syde®

Author

Mona Michaud, Alexandre Guérin, Marguerite Dejean de La Bâtie, Léopold Bancel, Laurent Oudre, and Alexis Tricot

Subjects
IMU, wearable, analytical validation, motion capture, gait monitoring, controlled environment, Chemical technology, TP1-1185
Abstract

The increasing use of inertial measurement units (IMU) in biomedical sciences brings new possibilities for clinical research. The aim of this paper is to demonstrate the accuracy of the IMU-based wearable Syde® device, which allows day-long and remote continuous gait recording in comparison to a reference motion capture system. Twelve healthy subjects (age: 23.17 ± 2.04, height: 174.17 ± 6.46 cm) participated in a controlled environment data collection and performed a series of gait tasks with both systems attached to each ankle. A total of 2820 strides were analyzed. The results show a median absolute stride length error of 1.86 cm between the IMU-based wearable device reconstruction and the motion capture ground truth, with the 75th percentile at 3.24 cm. The median absolute stride horizontal velocity error was 1.56 cm/s, with the 75th percentile at 2.63 cm/s. With a measurement error to the reference system of less than 3 cm, we conclude that there is a valid physical recovery of stride length and horizontal velocity from data collected with the IMU-based wearable Syde® device.

Published
2024
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118. Parameter-free hybrid functional based on an extended Hubbard model: DFT+U+V

Author

Tancogne-Dejean, Nicolas and Rubio, Angel

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

In this article, we propose an energy functional at the level of DFT+U+V that allows us to compute self-consistently the values of the on-site interaction, Hubbard U and Hund J, as well as the intersite interaction V. This functional extends the previously proposed ACBN0 functional [Phys. Rev. X 5, 011006 (2015)] including both on-site and intersite interactions. We show that this ab initio self-consistent functional yields improved electronic properties for a wide range of materials, ranging from $sp$ materials to strongly-correlated materials. This functional can also be seen as an alternative general and systematic way to construct parameter-free hybrid functionals, based on the extended Hubbard model and a selected set of Coulomb integrals, and might be used to develop novel approximations. By extending the DFT+U method to materials where strong local and nonlocal interactions are relevant, this work opens the door to the ab initio study the electronic, ionic, and optical properties of a larger class of strongly correlated materials in and out of equilibrium.

Published
2019
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120. Ultrafast Transient Absorption Spectroscopy of the Charge-Transfer Insulator NiO: Beyond the Dynamical Franz-Keldysh Effect

Author

Tancogne-Dejean, Nicolas, Sentef, Michael A., and Rubio, Angel

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

We demonstrate that a dynamical modification of the Hubbard U in the model charge-transfer insulator NiO can be observed with state-of-the-art time-resolved absorption spectroscopy. Using a self-consistent time-dependent density functional theory plus U computational framework, we show that the dynamical modulation of screening and Hubbard U significantly changes the transient optical spectroscopy. Whereas we find the well-known dynamical Franz-Keldysh effect when the U is frozen, we observe a dynamical band-gap renormalization for dynamical U. The renormalization of the optical gap is found to be smaller than the renormalization of U. This work opens up the possibility of driving a light-induced transition from a charge-transfer into a Mott insulator phase.

Published
2019
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121. High-Harmonic generation from spin-polarised defects in solids

Author

S., Mrudul M., Tancogne-Dejean, Nicolas, Rubio, Angel, and Dixit, Gopal

Subjects
Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Strongly Correlated Electrons, Physics - Atomic Physics
Abstract

Generation of high-order harmonics in gases enabled to probe the attosecond electron dynamics in atoms and molecules with unprecedented resolution. Extending the techniques developed originally for atomic and molecular gases to solid state materials requires a fundamental understanding of the physics that has been partially addressed theoretically. Here we employ time-dependent density-functional theory to investigate how the electron dynamics resulting in high-harmonic emission in monolayer hexagonal boron nitride is affected by the presence of vacancies. We show how these realistic spin-polarised defects modify the harmonic emission, and demonstrate that important differences exist between harmonics from a pristine solid and a defected-solid. In particular, we found that the different spin channels are affected differently because of the presence of the spin-polarized point defect, and that localisation of the wavefunction, the geometry of the defect and the electron-electron interaction are all important ingredients to describe high-harmonic generation in defected-solids. We show that different vacancies lead to qualitatively different effects, thus opening the door to the high-harmonic imaging of spin-polarised defects in solids., Comment: 29 pages, 6 figures

Published
2019
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122. Comparing Machine Learning Approaches for Table Recognition in Historical Register Books

Author

Clinchant, Stéphane, Déjean, Hervé, Meunier, Jean-Luc, Lang, Eva, and Kleber, Florian

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Information Retrieval, Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

We present in this paper experiments on Table Recognition in hand-written registry books. We first explain how the problem of row and column detection is modeled, and then compare two Machine Learning approaches (Conditional Random Field and Graph Convolutional Network) for detecting these table elements. Evaluation was conducted on death records provided by the Archive of the Diocese of Passau. Both methods show similar results, a 89 F1 score, a quality which allows for Information Extraction. Software and dataset are open source/data., Comment: DAS 2018

Published
2019

125. Let more big fish sink: Fisheries prevent blue carbon sequestration—half in unprofitable areas

Author

Mariani, Gaël, Cheung, William WL, Lyet, Arnaud, Sala, Enric, Mayorga, Juan, Velez, Laure, Gaines, Steven D, Dejean, Tony, Troussellier, Marc, and Mouillot, David

Subjects
Environmental Sciences, International and Comparative Law, Law and Legal Studies, Environmental Management, Life Below Water, Life on Land
Abstract

Contrary to most terrestrial organisms, which release their carbon into the atmosphere after death, carcasses of large marine fish sink and sequester carbon in the deep ocean. Yet, fisheries have extracted a massive amount of this "blue carbon," contributing to additional atmospheric CO2 emissions. Here, we used historical catches and fuel consumption to show that ocean fisheries have released a minimum of 0.73 billion metric tons of CO2 (GtCO2) in the atmosphere since 1950. Globally, 43.5% of the blue carbon extracted by fisheries in the high seas comes from areas that would be economically unprofitable without subsidies. Limiting blue carbon extraction by fisheries, particularly on unprofitable areas, would reduce CO2 emissions by burning less fuel and reactivating a natural carbon pump through the rebuilding of fish stocks and the increase of carcasses deadfall.

Published
2020

126. Light-Induced Renormalization of the Dirac Quasiparticles in the Nodal-Line Semimetal ZrSiSe

Author

Gatti, G, Crepaldi, A, Puppin, M, Tancogne-Dejean, N, Xian, L, De Giovannini, U, Roth, S, Polishchuk, S, Bugnon, Ph, Magrez, A, Berger, H, Frassetto, F, Poletto, L, Moreschini, L, Moser, S, Bostwick, A, Rotenberg, Eli, Rubio, A, Chergui, M, and Grioni, M

Subjects
Quantum Physics, Physical Sciences, Condensed Matter Physics, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences
Abstract

In nodal-line semimetals, linearly dispersing states form Dirac loops in the reciprocal space with a high degree of electron-hole symmetry and a reduced density of states near the Fermi level. The result is reduced electronic screening and enhanced correlations between Dirac quasiparticles. Here we investigate the electronic structure of ZrSiSe, by combining time- and angle-resolved photoelectron spectroscopy with ab initio density functional theory (DFT) complemented by an extended Hubbard model (DFT+U+V) and by time-dependent DFT+U+V. We show that electronic correlations are reduced on an ultrashort timescale by optical excitation of high-energy electrons-hole pairs, which transiently screen the Coulomb interaction. Our findings demonstrate an all-optical method for engineering the band structure of a quantum material.

Published
2020

127. The CECAM electronic structure library and the modular software development paradigm

Author

Oliveira, Micael JT, Papior, Nick, Pouillon, Yann, Blum, Volker, Artacho, Emilio, Caliste, Damien, Corsetti, Fabiano, de Gironcoli, Stefano, Elena, Alin M, García, Alberto, García-Suárez, Víctor M, Genovese, Luigi, Huhn, William P, Huhs, Georg, Kokott, Sebastian, Küçükbenli, Emine, Larsen, Ask H, Lazzaro, Alfio, Lebedeva, Irina V, Li, Yingzhou, López-Durán, David, López-Tarifa, Pablo, Lüders, Martin, Marques, Miguel AL, Minar, Jan, Mohr, Stephan, Mostofi, Arash A, O’Cais, Alan, Payne, Mike C, Ruh, Thomas, Smith, Daniel GA, Soler, José M, Strubbe, David A, Tancogne-Dejean, Nicolas, Tildesley, Dominic, Torrent, Marc, and Yu, Victor Wen-zhe

Subjects
Networking and Information Technology R&D (NITRD), cond-mat.mtrl-sci, physics.comp-ph, Physical Sciences, Chemical Sciences, Engineering, Chemical Physics
Abstract

First-principles electronic structure calculations are now accessible to a very large community of users across many disciplines, thanks to many successful software packages, some of which are described in this special issue. The traditional coding paradigm for such packages is monolithic, i.e., regardless of how modular its internal structure may be, the code is built independently from others, essentially from the compiler up, possibly with the exception of linear-algebra and message-passing libraries. This model has endured and been quite successful for decades. The successful evolution of the electronic structure methodology itself, however, has resulted in an increasing complexity and an ever longer list of features expected within all software packages, which implies a growing amount of replication between different packages, not only in the initial coding but, more importantly, every time a code needs to be re-engineered to adapt to the evolution of computer hardware architecture. The Electronic Structure Library (ESL) was initiated by CECAM (the European Centre for Atomic and Molecular Calculations) to catalyze a paradigm shift away from the monolithic model and promote modularization, with the ambition to extract common tasks from electronic structure codes and redesign them as open-source libraries available to everybody. Such libraries include "heavy-duty" ones that have the potential for a high degree of parallelization and adaptation to novel hardware within them, thereby separating the sophisticated computer science aspects of performance optimization and re-engineering from the computational science done by, e.g., physicists and chemists when implementing new ideas. We envisage that this modular paradigm will improve overall coding efficiency and enable specialists (whether they be computer scientists or computational scientists) to use their skills more effectively and will lead to a more dynamic evolution of software in the community as well as lower barriers to entry for new developers. The model comes with new challenges, though. The building and compilation of a code based on many interdependent libraries (and their versions) is a much more complex task than that of a code delivered in a single self-contained package. Here, we describe the state of the ESL, the different libraries it now contains, the short- and mid-term plans for further libraries, and the way the new challenges are faced. The ESL is a community initiative into which several pre-existing codes and their developers have contributed with their software and efforts, from which several codes are already benefiting, and which remains open to the community.

Published
2020

128. Octopus, a computational framework for exploring light-driven phenomena and quantum dynamics in extended and finite systems

Author

Tancogne-Dejean, Nicolas, Oliveira, Micael JT, Andrade, Xavier, Appel, Heiko, Borca, Carlos H, Le Breton, Guillaume, Buchholz, Florian, Castro, Alberto, Corni, Stefano, Correa, Alfredo A, De Giovannini, Umberto, Delgado, Alain, Eich, Florian G, Flick, Johannes, Gil, Gabriel, Gomez, Adrián, Helbig, Nicole, Hübener, Hannes, Jestädt, René, Jornet-Somoza, Joaquim, Larsen, Ask H, Lebedeva, Irina V, Lüders, Martin, Marques, Miguel AL, Ohlmann, Sebastian T, Pipolo, Silvio, Rampp, Markus, Rozzi, Carlo A, Strubbe, David A, Sato, Shunsuke A, Schäfer, Christian, Theophilou, Iris, Welden, Alicia, and Rubio, Angel

Subjects
Quantum Physics, Chemical Sciences, Physical Sciences, physics.comp-ph, Engineering, Chemical Physics, Chemical sciences, Physical sciences
Abstract

Over the last few years, extraordinary advances in experimental and theoretical tools have allowed us to monitor and control matter at short time and atomic scales with a high degree of precision. An appealing and challenging route toward engineering materials with tailored properties is to find ways to design or selectively manipulate materials, especially at the quantum level. To this end, having a state-of-the-art ab initio computer simulation tool that enables a reliable and accurate simulation of light-induced changes in the physical and chemical properties of complex systems is of utmost importance. The first principles real-space-based Octopus project was born with that idea in mind, i.e., to provide a unique framework that allows us to describe non-equilibrium phenomena in molecular complexes, low dimensional materials, and extended systems by accounting for electronic, ionic, and photon quantum mechanical effects within a generalized time-dependent density functional theory. This article aims to present the new features that have been implemented over the last few years, including technical developments related to performance and massive parallelism. We also describe the major theoretical developments to address ultrafast light-driven processes, such as the new theoretical framework of quantum electrodynamics density-functional formalism for the description of novel light-matter hybrid states. Those advances, and others being released soon as part of the Octopus package, will allow the scientific community to simulate and characterize spatial and time-resolved spectroscopies, ultrafast phenomena in molecules and materials, and new emergent states of matter (quantum electrodynamical-materials).

Published
2020

129. Multi-flat bands and strong correlations in Twisted Bilayer Boron Nitride

Author

Xian, Lede, Kennes, Dante M., Tancogne-Dejean, Nicolas, Altarelli, Massimo, and Rubio, Angel

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity
Abstract

In a groundbreaking experimental advance it was recently shown that by stacking two sheets of graphene atop of each other at a twist angle close to one of the so called "magic angles", an effective two-dimensional correlated system emerges. In this system the kinetic energy of the low-energy electrons is much reduced and consequently interactions become very relevant, providing a new platform into the physics of two-dimensional correlated materials. Evidence of a proposed Mott insulating as well as superconducting state in these highly tunable systems has spurred much attention as they could pave the way to understanding long-standing questions of high-$T_c$ superconductivity or provide candidate systems for topological chiral superconductors; key to highly relevant quantum technologies. Here, we demonstrate that twisted bilayer boron nitride (TBBN) is an exciting and even richer alternative to twisted bilayer graphene (TBG). Crucially, we show that in TBBN multiple flat bands emerge without having to fine tuning close to a "magic angle" that upon doping lead to correlated phases of matter (insulating and superconducting). TBBN could thus be much less sensitive to small deviations in the twist angle and therefore provide a particularly suited experimental platform to study correlation physics in two dimensions. Furthermore, we find that in marked contrast to TBG at small twist angle families of 2,4 and 6-fold degenerate, well separated, bands emerge within the gap, considerably broadening the addressable physics., Comment: The first two authors contributed equally

Published
2018
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130. Exchange-only virial relation from the adiabatic connection.

Author

Laestadius, Andre, Csirik, Mihály A., Penz, Markus, Tancogne-Dejean, Nicolas, Ruggenthaler, Michael, Rubio, Angel, and Helgaker, Trygve

Subjects
DENSITY, DEFINITIONS
Abstract

The exchange-only virial relation due to Levy and Perdew is revisited. Invoking the adiabatic connection, we introduce the exchange energy in terms of the right-derivative of the universal density functional w.r.t. the coupling strength λ at λ = 0. This agrees with the Levy–Perdew definition of the exchange energy as a high-density limit of the full exchange–correlation energy. By relying on v-representability for a fixed density at varying coupling strength, we prove an exchange-only virial relation without an explicit local-exchange potential. Instead, the relation is in terms of a limit (λ ↘ 0) involving the exchange–correlation potential v x c λ , which exists by assumption of v-representability. On the other hand, a local-exchange potential vx is not warranted to exist as such a limit. [ABSTRACT FROM AUTHOR]

Published
2024
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131. Exchange energies with forces in density-functional theory.

Author

Tancogne-Dejean, Nicolas, Penz, Markus, Laestadius, Andre, Csirik, Mihály A., Ruggenthaler, Michael, and Rubio, Angel

Subjects
*FORCE & energy, *POTENTIAL energy, *PSEUDOPOTENTIAL method, *ATOMIC structure, *GROUND state energy, *FUNCTIONALS
Abstract

We propose exchanging the energy functionals in ground-state density-functional theory with physically equivalent exact force expressions as a new promising route toward approximations to the exchange–correlation potential and energy. In analogy to the usual energy-based procedure, we split the force difference between the interacting and auxiliary Kohn–Sham system into a Hartree, an exchange, and a correlation force. The corresponding scalar potential is obtained by solving a Poisson equation, while an additional transverse part of the force yields a vector potential. These vector potentials obey an exact constraint between the exchange and correlation contribution and can further be related to the atomic shell structure. Numerically, the force-based local-exchange potential and the corresponding exchange energy compare well with the numerically more involved optimized effective potential method. Overall, the force-based method has several benefits when compared to the usual energy-based approach and opens a route toward numerically inexpensive nonlocal and (in the time-dependent case) nonadiabatic approximations. [ABSTRACT FROM AUTHOR]

Published
2024
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144. Haitian State Hospital Orthopedic Grand Rounds Series: A Virtual Curriculum to Address Global Surgery Needs

Author

Lindsay Hock, Melissa Zahl, Pierre-Marie Woolley, Christina Barau Dejean, Christian A. Pean, and Ronald Israelski

Subjects
orthopedic surgery, trauma, global surgery, haiti, surgical education, Infectious and parasitic diseases, RC109-216, Public aspects of medicine, RA1-1270
Abstract

Background: Orthopedic Relief Services International (ORSI), in partnership with the Foundation for Orthopedic Trauma and the department of Orthopedic Surgery of La Paix University Hospital in Haiti, has developed a year-round Orthopedic Grand Round series. This series is moderated by Haitian faculty, features presentations by American orthopedic surgeons, and is broadcast to major state hospitals in Haiti for residents and attendings. Objective: To introduce clinical concepts and increase knowledge in an area that is medically underserved, especially in the field of orthopedics, through lectures that tailor to the educational needs of Haiti. Methods: Topics for lecture series are requested by Haitian attending orthopedic surgeons and residents in collaboration with American orthopedic surgeons to meet the educational needs of the residents in Haiti. These lectures reflect the case mix typically seen at state hospitals in Haiti and consider the infrastructural capacity of participating centers. Grand rounds are held an average of twice per month for an hour each, encompassing an educational lesson followed by an open forum for questions and case discussion. Feedback is taken from Haitian residents to ensure the sessions are beneficial to their learning. Findings and Conclusions: To date 95 sessions hosted by 32 lecturers have been completed over Zoom between the US and Haiti. The fourth year of the lecture series is currently ongoing with an expansion of topics. In an underserved medical area such as Haiti, programs that educate local surgeons are crucial to continuing the growth and development of the medical community. Programs like this have the potential to contribute to the educational infrastructure of countries in need, regardless of the specialty. The model of this program can be used to produce similar curricula in various specialties and areas around the world.

Published
2023
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145. Bench-Marking Information Extraction in Semi-Structured Historical Handwritten Records

Author

Prasad, Animesh, Déjean, Hervé, Meunier, Jean-Luc, Weidemann, Max, Michael, Johannes, and Leifert, Gundram

Subjects
Computer Science - Computer Vision and Pattern Recognition, Computer Science - Computation and Language
Abstract

In this report, we present our findings from benchmarking experiments for information extraction on historical handwritten marriage records Esposalles from IEHHR - ICDAR 2017 robust reading competition. The information extraction is modeled as semantic labeling of the sequence across 2 set of labels. This can be achieved by sequentially or jointly applying handwritten text recognition (HTR) and named entity recognition (NER). We deploy a pipeline approach where first we use state-of-the-art HTR and use its output as input for NER. We show that given low resource setup and simple structure of the records, high performance of HTR ensures overall high performance. We explore the various configurations of conditional random fields and neural networks to benchmark NER on given certain noisy input. The best model on 10-fold cross-validation as well as blind test data uses n-gram features with bidirectional long short-term memory.

Published
2018

146. High-harmonic generation from few layer hexagonal boron nitride: evolution from the monolayer to the bulk response

Author

Breton, Guillaume Le, Rubio, Angel, and Tancogne-Dejean, Nicolas

Subjects
Condensed Matter - Materials Science, Physics - Optics
Abstract

Two-dimensional materials offer a versatile platform to study high-harmonic generation (HHG), encompassing as limiting cases bulk-like and atomic-like harmonic generation [Tancogne-Dejean and Rubio, Science Advance \textbf{4}, eaao5207 (2018)]. Understanding the high-harmonic response of few-layer semiconducting systems is important, and might open up possible technological applications. Using extensive first-principle calculations within a time-dependent density functional theory framework, we show how the in-plane and out-of-plane nonlinear non-perturbative response of two-dimensional materials evolve from the monolayer to the bulk. We illustrate this phenomenon for the case of multilayer hexagonal BN layered systems. Whereas the in-plane HHG is found not to be strongly altered by the stacking of the layers, we found that the out-of-plane response is strongly affected by the number of layers considered. This is explained by the interplay between the induced electric field by electron-electron interactions and the interlayer delocalization of the wave-functions contributing most to the HHG signal. The gliding of a bilayer is also found to affect the high-harmonic emission. Our results will have important ramifications for the experimental study of monolayer and few-layer two-dimensional materials beyond the case of hexagonal BN studied here as the result we found arew generic and applicable to all 2D semiconducting multilayer systems.

Published
2018
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147. Polarization-state-resolved high-harmonic spectroscopy of solids

Author

Klemke, Nicolai, Tancogne-Dejean, Nicolas, Rossi, Giulio M., Yang, Yudong, Mainz, Roland E., Di Sciacca, Giuseppe, Rubio, Angel, Kärtner, Franz X., and Mücke, Oliver D.

Subjects
Physics - Optics
Abstract

Attosecond metrology sensitive to sub-optical-cycle electronic and structural dynamics is opening up new avenues for ultrafast spectroscopy of condensed matter. Using intense lightwaves to precisely control the extremely fast carrier dynamics in crystals holds great promise for next-generation electronics and devices operating at petahertz bandwidth. The carrier dynamics can produce high-order harmonics of the driving light field extending up into the extreme-ultraviolet region. Here, we introduce polarization-state-resolved high-harmonic spectroscopy of solids, which provides deeper insights into both electronic and structural dynamics occuring within a single cycle of light. Performing high-harmonic generation measurements from silicon and quartz samples, we demonstrate that the polarization states of high-order harmonics emitted from solids are not only determined by crystal symmetries, but can be dynamically controlled, as a consequence of the intertwined interband and intraband electronic dynamics, responsible for the harmonic generation. We exploit this symmetry-dynamics duality to efficiently generate circularly polarized harmonics from elliptically polarized driver pulses. Our experimental results are supported by ab-initio simulations, providing clear evidence for the microscopic origin of the phenomenon. This spectroscopy technique might find important applications in future studies of novel quantum materials such as strongly correlated materials. Compact sources of bright circularly polarized harmonics in the extreme-ultraviolet regime will advance our tools for the spectroscopy of chiral systems, magnetic materials, and 2D materials with valley selectivity.

Published
2018
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148. All-optical nonequilibrium pathway to stabilizing magnetic Weyl semimetals in pyrochlore iridates

Author

Topp, Gabriel E., Tancogne-Dejean, Nicolas, Kemper, Alexander F., Rubio, Angel, and Sentef, Michael A.

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

Nonequilibrium many-body dynamics is becoming one of the central topics of modern condensed matter physics. Floquet topological states were suggested to emerge in photodressed band structures in the presence of periodic laser driving. Here we propose a viable nonequilibrium route without requiring coherent Floquet states to reach the elusive magnetic Weyl semimetallic phase in pyrochlore iridates by ultrafast modification of the effective electron-electron interaction with short laser pulses. Combining \textit{ab initio} calculations for a time-dependent self-consistent reduced Hubbard $U$ controlled by laser intensity and nonequilibrium magnetism simulations for quantum quenches, we find dynamically modified magnetic order giving rise to transiently emerging Weyl cones that are probed by time- and angle-resolved photoemission spectroscopy. Our work offers a unique and realistic pathway for nonequilibrium materials engineering beyond Floquet physics to create and sustain Weyl semimetals. This may lead to ultrafast, tens-of-femtoseconds switching protocols for light-engineered Berry curvature in combination with ultrafast magnetism., Comment: 27 pages including methods and supplementary information, 4 figures, 4 supplementary figures

Published
2018
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149. Ultrafast modification of Hubbard $U$ in a strongly correlated material: ab initio high-harmonic generation in NiO

Author

Tancogne-Dejean, Nicolas, Sentef, Michael A., and Rubio, Angel

Subjects
Condensed Matter - Strongly Correlated Electrons
Abstract

Engineering effective electronic parameters is a major focus in condensed matter physics. Their dynamical modulation opens the possibility of creating and controlling physical properties in systems driven out of equilibrium. In this work, we demonstrate that the Hubbard $U$, the on-site Coulomb repulsion in strongly correlated materials, can be modified on femtosecond time scales by a strong nonresonant laser excitation in the prototypical charge transfer insulator NiO. Using our recently developed time-dependent density functional theory plus self-consistent $U$ (TDDFT+U) method, we demonstrate the importance of a dynamically modulated $U$ in the description of the high-harmonic generation of NiO. Our study opens the door to novel ways of modifying effective interactions in strongly correlated materials via laser driving, which may lead to new control paradigms for field-induced phase transitions and perhaps laser-induced Mott insulation in charge-transfer materials.

Published
2017
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