CORRELACIONES CUANTICAS E INTERFERENCIA DE FOTONES INTERACTUANTES EN ESTRUCTURAS MATERIA-LUZ BIDIMENSIONALES
PID2020-113415RB-C22
•
Nombre agencia financiadora Agencia Estatal de Investigación
Acrónimo agencia financiadora AEI
Programa Programa Estatal de I+D+i Orientada a los Retos de la Sociedad
Subprograma Programa Estatal de I+D+i Orientada a los Retos de la Sociedad
Convocatoria Proyectos I+D
Año convocatoria 2020
Unidad de gestión Plan Estatal de Investigación Científica y Técnica y de Innovación 2017-2020
Centro beneficiario UNIVERSIDAD AUTONOMA DE MADRID
Identificador persistente http://dx.doi.org/10.13039/501100011033
Publicaciones
Found(s) 2 result(s)
Found(s) 1 page(s)
Found(s) 1 page(s)
Rydberg excitons and polaritons in monolayer transition metal dichalcogenides in a magnetic field
e-cienciaDatos, Repositorio de Datos del Consorcio Madroño
- de la Fuente Pico, David
- Levinsen, Jesper
- Laird, Emma
- Parish, Meera
- Marchetti, Francesca Maria
<p>This dataset was developed as part of the projects: <p>
<ul>
<li>Engineering quantum photon states in two-dimensional materials (2DEnLight). Summary:The 'quantum age' of the 21st century has the potential to revolutionize science, industry, and everyday life. However, its full impact, far beyond today's digital landscape, is still unfolding. Among the most exciting fields is quantum light and light-matter interactions, particularly non-classical light sources emitting photons with controllable quantum correlations. These are key for quantum communication and information processing. The 2DEnLight project focuses on generating light at the single-photon limit and manipulating its intrinsic properties. Our proposal aims to engineer coupled emitter-light systems to produce non-classical photon streams and demonstrate tunable quantum correlations at both the few- and many-body levels.</li>
<li>Quantum Relativistic Laboratory (QRAB):QRAB brings together topics of quantum optics and many-body physics—which it fits in a subproject labelled QUANTUM—together with wavepacket propagation in two-dimensional (2D) materials, with a focus on changes of reference frames made experimentally available thanks to Surface Acoustic Waves (SAW)—which it fits in the subproject labelled RELATIVITY. The theoretical exploitation of these themes, both on their own and in their combination, is to be brought to experimental implementations in a third subproject labelled LABORATORY.</li>
</ul>
<p>The dataset is structured in folders named "Figure_i" with 2,...,13. They correspond to the figures in the PRB paper "Rydberg excitons and polaritons in monolayer transition metal dichalcogenides in a magnetic field". Each folder contains the data in format .txt for the corresponding figure in the paper, along with the Python code to generate it.</p>
<ul>
<li>Engineering quantum photon states in two-dimensional materials (2DEnLight). Summary:The 'quantum age' of the 21st century has the potential to revolutionize science, industry, and everyday life. However, its full impact, far beyond today's digital landscape, is still unfolding. Among the most exciting fields is quantum light and light-matter interactions, particularly non-classical light sources emitting photons with controllable quantum correlations. These are key for quantum communication and information processing. The 2DEnLight project focuses on generating light at the single-photon limit and manipulating its intrinsic properties. Our proposal aims to engineer coupled emitter-light systems to produce non-classical photon streams and demonstrate tunable quantum correlations at both the few- and many-body levels.</li>
<li>Quantum Relativistic Laboratory (QRAB):QRAB brings together topics of quantum optics and many-body physics—which it fits in a subproject labelled QUANTUM—together with wavepacket propagation in two-dimensional (2D) materials, with a focus on changes of reference frames made experimentally available thanks to Surface Acoustic Waves (SAW)—which it fits in the subproject labelled RELATIVITY. The theoretical exploitation of these themes, both on their own and in their combination, is to be brought to experimental implementations in a third subproject labelled LABORATORY.</li>
</ul>
<p>The dataset is structured in folders named "Figure_i" with 2,...,13. They correspond to the figures in the PRB paper "Rydberg excitons and polaritons in monolayer transition metal dichalcogenides in a magnetic field". Each folder contains the data in format .txt for the corresponding figure in the paper, along with the Python code to generate it.</p>
Multiple polaron quasiparticles with dipolar fermions in a bilayer geometry (dataset)
e-cienciaDatos, Repositorio de Datos del Consorcio Madroño
- Tiene, Antonio
- Tamargo Bracho, Andrés
- Parish, Meera M.
- Levinsen, Jesper
- Marchetti, Francesca Maria
<p>This dataset contains the folders including gnuplot scripts and datafile to reproduce all the pictures in the published paper.</p>
<ul>
<li>2DEnLight</li>
<p align="justify">The ‘quantum age’ of the 21st century has proven to have a tremendous power to revolutionize not only our science but also many sectors of our economy, industry and everyday-life. Its full potential to shape the future of our society and to take us into a new era far beyond the capabilities of today’s familiar digital landscape is yet to be realized. Among many existing candidates for developing and testing fundamental as well as technically innovative ideas in the quantum realm, the quantum aspects of light and light-matter interactions are one of the most fascinating and rapidly emerging research fields. In particular, the non-classical light sources emitting photons with controllable quantum correlations are at the heart of most applications in quantum communication and information processing. The 2DEnLight project focusses on the controllable production of light at its fundamental single-photon limit as well as manipulation of its intrinsic properties. Our proposal includes the possibility of engineering and manipulating coupled emitter-light systems capable of generating non-classical photon streams and demonstrating tunable quantum correlations both at the few- and many-body level.</p>
<li> NanoQuCo</li>
<p align="justify">With NanoQuCo we will design quantum computers based on quantum nanophotonics to overcome the size and speed limitations of current
limitations of current platforms, and realize new quantum computing algorithms with near-term applications. </p>
</ul>
<ul>
<li>2DEnLight</li>
<p align="justify">The ‘quantum age’ of the 21st century has proven to have a tremendous power to revolutionize not only our science but also many sectors of our economy, industry and everyday-life. Its full potential to shape the future of our society and to take us into a new era far beyond the capabilities of today’s familiar digital landscape is yet to be realized. Among many existing candidates for developing and testing fundamental as well as technically innovative ideas in the quantum realm, the quantum aspects of light and light-matter interactions are one of the most fascinating and rapidly emerging research fields. In particular, the non-classical light sources emitting photons with controllable quantum correlations are at the heart of most applications in quantum communication and information processing. The 2DEnLight project focusses on the controllable production of light at its fundamental single-photon limit as well as manipulation of its intrinsic properties. Our proposal includes the possibility of engineering and manipulating coupled emitter-light systems capable of generating non-classical photon streams and demonstrating tunable quantum correlations both at the few- and many-body level.</p>
<li> NanoQuCo</li>
<p align="justify">With NanoQuCo we will design quantum computers based on quantum nanophotonics to overcome the size and speed limitations of current
limitations of current platforms, and realize new quantum computing algorithms with near-term applications. </p>
</ul>