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11 results on '"Cistaro, Giovanni"'

1. Topological phase transitions via attosecond x-ray absorption spectroscopy

Author

Mosquera, Juan F. P., Cistaro, Giovanni, Malakhov, Mikhail, Pisanty, Emilio, Dauphin, Alexandre, Plaja, Luis, Chacón, Alexis, Lewenstein, Maciej, and Picón, Antonio

Subjects
Physics - Optics, Quantum Physics
Abstract

We present a numerical experiment that demonstrates the possibility to capture topological phase transitions via an x-ray absorption spectroscopy scheme. We consider a Chern insulator whose topological phase is tuned via a second-order hopping. We perform time-dynamics simulations of the out-of-equilibrium laser-driven electron motion that enables us to model a realistic attosecond spectroscopy scheme. In particular, we use an ultrafast scheme with a circularly polarized IR pump pulse and an attosecond x-ray probe pulse. A laser-induced dichroism-type spectrum shows a clear signature of the topological phase transition. We are able to connect these signatures with the Berry structure of the system. This work extend the applications of attosecond absorption spectroscopy to systems presenting a non-trivial topological phase.

Published
2024

2. Exciton migration in two-dimensional materials

Author

Malakhov, Mikhail, Cistaro, Giovanni, Martín, Fernando, and Picón, Antonio

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

Excitons play an essential role in the optical response of two-dimensional materials. These are bound states showing up in the band gaps of many-body systems and are conceived as quasiparticles formed by an electron and a hole. By performing real-time simulations in hBN, we show that an ultrashort (few-fs) UV pulse can produce a coherent superposition of excitonic states that induces an oscillatory motion of electrons and holes between different valleys in reciprocal space, leading to a sizeable exciton migration in real space. We also show that an ultrafast spectroscopy scheme based on the absorption of an attosecond pulse in combination with the UV pulse can be used to read out the laser-induced coherences, hence to extract the characteristic time for exciton migration. This work opens the door towards ultrafast electronics and valleytronics adding time as a control knob and exploiting electron coherence at the early times of excitation.

Published
2023
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3. Formation, stability, and highly nonlinear optical response of excitons to intense light fields interacting with two-dimensional materials

Author

Molinero, Eduardo B., Amorim, Bruno, Malakhov, Mikhail, Cistaro, Giovanni, Jiménez-Galán, Álvaro, Ivanov, Misha, Picón, Antonio, San-José, Pablo, and Silva, Rui E. F.

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

Excitons play a key role in the linear optical response of 2D materials. However, their significance in the highly nonlinear optical response to intense mid-infrared light has often been overlooked. Using hBN as a prototypical example, we theoretically demonstrate that excitons play a major role in this process. Specifically, we illustrate their formation and stability in intense low-frequency fields, where field strengths surpass the Coulomb field binding the electron-hole pair in the exciton. Additionally, we establish a parallelism between these results and the already-known physics of Rydberg states using an atomic model. Finally, we propose an experimental setup to test the effect of excitons in the nonlinear optical response, Comment: 7 pages, 5 figures

Published
2023
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5. A theoretical approach for electron dynamics and ultrafast spectroscopy

Author

Cistaro, Giovanni, Malakhov, Mikhail, Esteve-Paredes, Juan José, Uría-Álvarez, Alejandro José, Silva, Rui E. F., Martín, Fernando, Palacios, Juan José, and Picón, Antonio

Subjects
Physics - Optics, Physics - Atomic Physics
Abstract

In this manuscript we present a theoretical framework and its numerical implementation to simulate the out-of-equilibrium electron dynamics induced by the interaction of ultrashort laser pulses in condensed-matter systems. Our approach is based on evolving in real-time the density matrix of the system in reciprocal space. It considers excitonic and non-perturbative light-matter interactions. We show some relevant examples that illustrate the efficiency and flexibility of the approach to describe realistic ultrafast spectroscopy experiments. Our approach is suitable for modeling the promising and emerging ultrafast studies at the attosecond time scale that aim at capturing the electron dynamics and the dynamical electron-electron correlations via X-ray absorption spectroscopy.

Published
2022
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7. Attosecond spectroscopy in the x-ray regime in complex systems

Author

Cistaro, Giovanni Consalvo, Picón Álvarez, Antonio, Martín García, Fernando, and UAM. Departamento de Química

Subjects
Mecánica de partículas, Grafenos--Propiedades eléctricas, Electrones--Propiedades eléctricas, Química
Abstract

Tesis Doctoral inédita leída en la Universidad Autónoma de Madrid, Facultad de Ciencias, Departamento de Química. Fecha de Lectura: 26-10-2022, El movimiento ultrarrápido de los electrones es una fuerza impulsora de las reacciones químicas y la posibilidad de controlarlo lo convierte en una vía de estudio muy deseable. Esta tesis utiliza la mecánica cuántica de sistemas extendidos para simular experimentos de pump-probe como ATAS en los que los electrones pueden ser promovidos desde bandas internas y luego son libres de moverse a través de bandas que son responsables de las propiedades físicas de los materiales. La herramienta principal que se utilizará es la resolución de la ecuación de Von Neumann para la matriz de densidad en la representación del momento del cristal, por lo que habrá la posibilidad de realizar un seguimiento del movimiento de los electrones en tiempo real. Los temas principales de esta tesis son los solidos hexagonales en 2D, grafeno y hBN, así como su extensión en 3D, grafito. Las simulaciones permitirán promover electrones desde los niveles del núcleo (K edge) hacia bandas cercanas a la energía de Fermi, y todos los espectros que se observarán se muestran sensibles a las principales propiedades de los materiales; en caso de inyección de electrones desde la banda de valencia, además, el ATAS observado realiza un seguimiento de la interferencia que sienten los electrones. Además, se investigarán muchos métodos computacionales relacionados con la computación de alto rendimiento para la resolución de las ecuaciones de Von Neumann, para agilizar las simulaciones, ya que son muy exigentes desde el punto de vista numérico. Las metodologías utilizadas y los resultados obtenidos abren el camino para una comprensión más profunda de la física de los materiales, desde la coherencia electrónica hasta el control de sus estados cuánticos, The ultrafast motion of electrons is a driving force for chemical reactions and the possibility to have control of it makes it a highly desirable avenue for study. This thesis uses the quantum mechanics of extended systems to simulate pump-probe experiments like ATAS in which the electrons can be promoted from inner shells and then are free to move through bands that are responsible for the physical properties of materials. The main tool that will be used is the resolution of the Von Neumann equation for the density matrix in crystal momentum representation, and so there will be the possibility to keep track of the real-time movement of electrons. The main subjects of this thesis are hexagonal lattices in 2D, graphene and hBN, as well as their extension in 3D, graphite. The simulations will allow to promote electrons from the core levels (K edge) to bands that are close to the Fermi energy, and all the spectra that will be observed are shown to be sensitive to the main properties of the materials; in case of injection of electrons from the valence band, also, the ATAS observed keep track of the interference felt by the electrons. Also, many computational methods related to high-performance computing will be investigated for the resolution of the Von Neumann equations, to speed up the simulations, as they are very demanding from the numerical point of view. The methodologies used and the results obtained pave the way for a deeper understanding of the physics of materials, from the electron coherence to the control of their quantum states

Published
2022

10. Subcycle dynamics of excitons under strong laser fields.

Author

Molinero, Eduardo B., Amorim, Bruno, Malakhov, Mikhail, Cistaro, Giovanni, Jiménez-Galán, Álvaro, Picón, Antonio, San-José, Pablo, Ivanov, Misha, and Silva, Rui E. F.

Subjects
*EXCITON theory, *RYDBERG states, *LASERS, *DIELECTRIC materials, *ATTOSECOND pulses
Abstract

Excitons play a key role in the linear optical response of two-dimensional (2D) materials. However, their role in the nonlinear response to intense, nonresonant, low-frequency light is often overlooked as strong fields are expected to tear the electron-hole pair apart. Using high-harmonic generation as a spectroscopic tool, we theoretically study their formation and role in the nonlinear optical response. We show that the excitonic contribution is prominent and that excitons remain stable even when the driving laser field surpasses the strength of the Coulomb field binding the electron-hole pair. We demonstrate a parallel between the behavior of strongly laser-driven excitons in 2D solids and strongly driven Rydberg states in atoms, including the mechanisms of their formation and stability. Last, we show how the excitonic contribution can be singled out by encapsulating the 2D material in a dielectric, tuning the excitonic energy and its contribution to the high-harmonic spectrum. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Topological phase transitions via attosecond x-ray absorption spectroscopy.

Author

Mosquera JFP, Cistaro G, Malakhov M, Pisanty E, Dauphin A, Plaja L, Chacón A, Lewenstein M, and Picón A

Abstract

We present a numerical experiment that demonstrates the possibility to capture topological phase transitions via an x-ray absorption spectroscopy scheme. We consider a Chern insulator whose topological phase is tuned via a second-order hopping. We perform time-dynamics simulations of the out-of-equilibrium laser-driven electron motion that enables us to model a realistic attosecond spectroscopy scheme. In particular, we use an ultrafast scheme with a circularly polarized IR pump pulse and an attosecond x-ray probe pulse. A laser-induced dichroism-type spectrum shows a clear signature of the topological phase transition. We are able to connect these signatures with the Berry structure of the system. This work extend the applications of attosecond absorption spectroscopy to systems presenting a non-trivial topological phase., (Creative Commons Attribution license.)

Published
2024
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