Your search keyword '"Hernández-García, Carlos"' showing total 15 results

1. High-harmonic spectroscopy of solids driven by structured light

Author

García-Cabrera Ana, Boyero-García Roberto, Zurrón-Cifuentes Óscar, Serrano Javier, Román Julio San, Hernández-García, Carlos, and Plaja Luis

Subjects

Physics, QC1-999

Abstract

Understanding high-order harmonic generation (HHG) from solid targets holds the key of potential technological innovations in the field of high-frequency coherent sources. Solids present optical nonlinearities at lower driving intensities, and harmonics can be efficiently emitted due to the increased electron density in comparison with the atomic and molecular counterparts. In addition, crystalline solids introduce a new complexity, as symmetries play a role in the anisotropic character of the optical response. An extraordinary playground is, therefore, the scenario in which solids are driven by vector beams, since crystal symmetries can be directly coupled with the topology of the driving laser beam. In this contribution we analyze the topological properties of the HHG radiation emitted by a single-layer graphene sheet driven by a vector beam. We show that the harmonic field is a complex combination of vortices, whose geometrical properties hold information about the details of the non-linear response of the crystal. We demonstrate, therefore, that the analysis of the topological structure of the harmonic field can be used as a spectroscopic measurement technique, paving the way of topological spectroscopy as a new strategy for the characterization of the optical response of macroscopic targets.

Published

2023

2. Novel ultrafast structured EUV/x-ray sources from nonlinear optics

Author

Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

Coherent extreme-ultraviolet (EUV)/x-ray laser sources, structured in their temporal/spectral, spatial and angular momentum properties are emerging as unique tools to probe the nanoworld. One of the key ingredients for the emergence of such sources is the extraordinary coherence in the up-conversion of infrared laser sources through the highly nonlinear process of high-order harmonic generation. In this contribution we will review the advances during the last decade that led to the generation of structured EUV/xray sources, such as circularly polarized attosecond pulses, harmonic vortices with time-varying orbital angular momentum, ultrafast vector and vector/vortex beams, tunable high-order harmonic combs or attosecond pulse trains with time-dependent polarization states. The use of such sources is being already applied to the investigation of chiral matter or magnetic materials. In the latter case, structured ultrafast sources are very promising to achieve a complete understanding of the electronic and spin interactions that govern sub-femtosecond magnetization dynamics.

Published

2022

3. Multi-beam vortex generation induced by the non-linear optical anisotropy of graphene

Author

Plaja Luis, García-Cabrera Ana, Boyero-García Roberto, Zurrón Óscar, San Román Julio, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

We analyse the high harmonic emission from single-layer graphene driven by infrared vector beams. We demonstrate that graphene’s anisotropy offers a privileged scenario to explore non-trivial light spin-orbit couplings, which substantially extends the possibilities for the generation of high-harmonic structured beams currently studied in atomic and molecular targets. In our case, graphene’s crystal symmetry introduces a spin-dependent diffraction pattern that, coupled with the fundamental conservation of the driver’s topological phase, leads to the splitting of the harmonic field in a multi-beam structure, composed of spatially diverging vortices. Our work demonstrates that anisotropic targets are extraordinary tools to sculpt complex structured short-wavelength beams.

Published

2022

4. Fourier-limited attosecond pulse generation with magnetically pumped high-order harmonic generation

Author

Martín-Hernández Rodrigo, Plaja Luis, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

After more than two decades of attosecond physics, the generation and control of the shortest laser pulses available remains as a complex task. One of the main limitations of reducing the temporal duration of attosecond pulses emitted from high-order harmonic generation (HHG) is the attochirp. In this contribution, we demonstrate that HHG assisted by strong fast oscillating magnetic fields enables the generation of Fourierlimited attosecond pulses in the water window. In short, the magnetic field generates a nanowire-like structure, which transversally confines the electronic wavefunction in the HHG process. We demonstrate that the resulting HHG spectrum extends well beyond the semiclassical cutoff frequency, and most interestingly, it is emitted in the form of few-cycle, Fourier-limited, attosecond pulses.

Published

2022

5. Switching the Twist in X Rays with Magnets

Author

Liao, Chen-Ting, Hernández García, Carlos, and Murnane, Margaret M.

Subjects

010309 optics, Physics, Condensed matter physics, Magnet, 0103 physical sciences, Magnetism, 2202.08 Magnetismo, Twist, 010306 general physics, 01 natural sciences

Published

2021

6. Spectral signature of back reaction in correlated electron dynamics in intense electromagnetic fields

Author

de las Heras, Alba, Hernández-García, Carlos, and Plaja, Luis

Subjects

Electromagnetic field, Field (physics), Strong-field-induced spectra, Electron, 01 natural sciences, Strong field excitation, Ultrashort pulses, 010305 fluids & plasmas, symbols.namesake, Ionization, Strong electromagnetic field effects, 0103 physical sciences, Physics::Atomic and Molecular Clusters, Electron correlation calculations for atoms & ions, High harmonic generation, Physics::Atomic Physics, 010306 general physics, Physics, High-order harmonic generation, Ultrafast phenomena, Multiphoton or tunneling ionization & excitation, Excited state, Rydberg formula, symbols, Atomic physics, Excitation

Abstract

Datos de investigación en: http://hdl.handle.net/10366/148373, Few-electron atoms interacting with electromagnetic fields provide for privileged scenarios for disentangling elemental correlation mechanisms. We demonstrate that high-order harmonic generation (HHG) from neutral helium presents a distinctive trace of correlation back reaction in the electron dynamics prior to ionization. We identify a mechanism in which the field interacts with one of the electrons, while the second is excited to a Rydberg level through the Coulomb interaction. As back response to this correlated excitation, the first electron is knocked down to a lower level, from which it ionizes to generate high-order harmonics. Unlike other multielectron phenomena, where the electron-field interaction is modified by cross correlations with the rest of the interacting electrons, back reaction is a mechanism of autocorrelation. Our numerical simulations reveal back reaction as a relevant aspect in HHG from correlated two-electron systems, and paves the way to disentangle valence electron-electron correlation dynamics using high-harmonic spectroscopy., We acknowledge fruitful discussions with Tenio Popmintchev. We also acknowledge support from Junta de Castilla y León FEDER funds (Project No. SA287P18) and Ministerio de Ciencia e Innovación (FIS2016-75652-P and PID2019-106910GB-I00). C.H.-G. acknowledges Ministerio de Ciencia, Innovación, y Universidades for a Ramón y Cajal contract (RYC-2017-22745), co-funded by the European Social Fund. This project has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (Grant Agreement No. 851201).

Published

2020

7. Coherent attosecond light sources based on high-order harmonic generation: influence of the propagation effects

Author

Hernández García, Carlos and Plaja Rustein, Luis

Subjects

Physics, Academic dissertations, Investigación::22 Física::2209 Óptica [Materias], Universidad de Salamanca (España), Tesis y disertaciones académicas, Investigación::22 Física [Materias], Láseres, Física aplicada, 2209 Óptica, 22 Física, High order, Tesis Doctoral, Humanities, Óptica

Abstract

[ES]Durante las últimas dos décadas, el avance en el campo de los láseres ultraintensos y ultracortos ha mejorado nuestra comprensión de la materia sometida a campos láser intensos. A diferencia de otros campos no perturbativos de la física, la disponibilidad de la tecnología de láseres intensos en laboratorios de tamaño medio a nivel mundial ha proporcionado una fructífera interacción entre la teoría y los experimentos. Esta tesis es un ejemplo de esta interacción.La radiación electromagnética intensa induce una fuerte respuesta no lineal en la materia. Los electrones atómicos adquieren energía del campo láser, que puede ser posteriormente liberada en forma de radiación coherente de alta frecuencia, en un proceso conocido como generación de armónicos de orden elevado (HHG, procedente de sus siglas en inglés). La ausencia de láseres convencionales a estas frecuencias elevadas ha impulsado el interés tecnológico en el desarrollo de HHG como herramienta para conseguir fuentes coherente de luz de longitud de onda corta. Hasta hace muy poco, la tecnología de láseres ultraintensos se limitaba a longitudes de onda del infrarrojo cercano (alrededor de 800 nm) y la conversión en armónicos de orden elevado se limitaba a la región del ultravioleta lejano (XUV). Actualmente, con la mejoría de las técnicas de inversión paramétrica, este límite se encuentra en los rayos X blandos. Sin embargo, desde el inicio se reconocieron las aplicaciones potenciales del proceso HHG, más allá de las naturales de una radiación coherente de alta frecuencia. El espectro de HHG consiste en un peine de armónicos que se extienden hasta la denominada frecuencia de corte. En la región espectral cercana a este corte, los armónicos tienen intensidades similares y, lo que es más interesante aún, su distribución de fase espectral es suave. Con estas dos premisas, tras filtrar el espectro de baja frecuencia, la radiación resultante se corresponde a un tren de pulsos ultracortos en la región XUV, con duraciones en torno a unos cuantos centenares de attosegundos (1 attosegundo = 10-18 segundos), espaciadas regularmente cada medio ciclo del láser incidente. Tras su confirmación experimental a comienzos del siglo XXI, éstos son considerados los pulsos de luz coherente más cortos jamás creados. Esta tecnología está dando sus primeros frutos, pues ya se han identificado distintas aplicaciones para discriminar procesos ultrarrápidos (en el régimen de los attosegundos) en la dinámica de sistemas físicos, químicos y biológicos.El objetivo de esta tesis es realizar una contribución novedosa y original en este campo. El núcleo principal de este estudio consiste en el desarrollo de métodos teóricos para simular los experimentos. Esta estrategia contiene una vertiente doble. En primer lugar, la teoría se utiliza para comprender los resultados obtenidos experimentalmente. Para ello hemos desarrollado nuestros propios experimentos, que contrastamos directamente con los resultados teóricos y, además, hemos colaborado con dos grupos experimentales a nivel internacional con el objetivo de simular sus experimentos. En segundo lugar, hemos aplicado nuestra teoría para predecir nuevos procesos físicos y, de este modo servir de guía para la realización de nuevos experimentos. El punto de partida de esta tesis se basa en la teoría SFA+, desarrollada previamente en el área de óptica de la Universidad de Salamanca, para el cálculo del proceso de generación de armónicos de orden elevado en un solo átomo, a nivel microscópico. Este método, así como una extensa introducción al proceso HHG, se expone a lo largo del capítulo 1. Nuestro primer objetivo ha sido desarrollar un esquema de propagación de los armónicos de orden elevado que permite la simulación del proceso a escala macroscópica, de manera que la teoría sea comparable a los experimentos. Para ello, hemos implementado una nueva técnica de propagación basada en la aproximación dipolar discreta. Esta técnica, así como los fundamentos para la comprensión de la propagación de armónicos de orden elevado, se desarrollan en el capítulo 2.En el capítulo 3 estudiamos la propagación de armónicos de orden elevado generados por campos láser de longitud de onda en el infrarrojo cercano, focalizados en chorros o celdas de gas de baja densidad. Como primer test, hemos analizado teórica y experimentalmente el cambio en las condiciones de ajuste de fases que resulta de situar el chorro de gas en distintas posiciones a lo largo del eje de propagación. Una vez validado nuestro método teórico experimentalmente, proponemos una alternativa para acortar los pulsos de attosegundo, mediante su detección bajo distintos ángulos desde el eje de propagación. Posteriormente presentamos un estudio de la longitud de coherencia transversal, comparando nuestros resultados teóricos y experimentales. Finalmente, hemos implementado la geometría de una celda de gas semi-infinita en nuestro código de propagación, con el objetivo de comprender los resultados experimentales obtenidos por el grupo de M. Kovacev, en la Universidad de Hannover (Alemania). En el capítulo 4 hemos modificado nuestro método para estudiar la generación armónicos de orden ultra-elevado, producidos utilizando láseres de longitud de onda en el infrarrojo medio (aproximadamente de 4 µm), en colaboración con el grupo teórico de A. Becker y A. Jaron-Becker, del JILA, en la Universidad de Colorado (EEUU). El resultado principal de este trabajo consiste en la demostración de la coherencia temporal de los rayos X con energía de kiloelectronvoltio obtenidos en el grupo experimental de M. Murnane y H. Kapteyn en el JILA, Universidad de Colorado (EEUU), que lideró una colaboración internacional en la que también participaron la Universidad Técnica de Viena (Austria), la Universidad de Cornell (EEUU) y nuestro grupo. Como continuación a este trabajo, y gracias al desarrollo de nuestros métodos teóricos, hemos derivado un camino para obtener pulsos de luz de rayos X en el régimen de los zeptosegundos (1 zeptosegundo=10-21 segundos)., [EN]During the past two decades, progress in the field of ultra-intense and ultra-short lasers has improved our understanding of the subject under intense laser fields. Unlike other nonperturbative fields of physics, the availability of intense laser technology in medium-sized laboratories worldwide has provided a fruitful interaction between theory and experiment. This thesis is an example of this interaction.Intense electromagnetic radiation induces a strong nonlinear response in the subject. The atomic electrons gain energy from the laser field, which can be subsequently released as high-frequency coherent radiation, a process known as generation of high order harmonics (HHG, from its acronym in English). Conventional lasers absence of these higher frequencies has fueled interest in developing technology as a tool for HHG coherent light sources of short wavelength. Until recently, ultra-intense laser technology was limited to wavelengths of near infrared (around 800 nm) and conversion into higher-order harmonics was limited to the far-ultraviolet region (XUV). Currently, with the improvement of the parametric inversion techniques, this limit is in soft X-rays.However, from the beginning recognized the potential applications of HHG process, beyond a natural high frequency coherent radiation. HHG spectrum consists of a comb of harmonics which extend to the so-called cutoff frequency. In the spectral region near this cut harmonics have similar intensities and, even more interestingly, the spectral phase distribution is smooth. With these two assumptions, after filtering the low frequency spectrum, the resulting radiation corresponds to a train of ultrashort pulses in the XUV region, lasting about a few hundred attoseconds (1 attosecond = 10-18 sec), spaced regularly every half cycle of the laser incident. Following early experimental confirmation of the century, they are considered coherent light pulses shorter ever created. This technology is starting to pay off, as already identified different applications for discriminating ultrafast processes (in the attosecond regime) in the dynamics of physical systems, chemical and biological.The aim of this thesis is to make a new and original contribution in this field. The core of this study is the development of theoretical methods to simulate the experiments. This strategy contains a double aspect. First, the theory used to understand the results obtained experimentally. We have developed our own experiments, we contrast directly with the theoretical results and also we have worked with two experimental groups at the international level in order to simulate their experiments. Second, we have applied our theory to predict new physical processes and thus serve as a guide for conducting new experiments.The starting point of this thesis is based on the theory SFA +, previously developed in the area of ​​optics at the University of Salamanca, for calculating the process of generating high order harmonics in a single atom, a microscopic level. This method, as well as an extensive introduction to the HHG process, is exposed along the chapter 1. Our first objective was to develop a propagation scheme of higher order harmonics which allows the simulation of the process on a macroscopic scale, so that the theory is comparable to the experiments. To do this, we implemented a new propagation technique based on the discrete dipole approximation. This technique, as well as the basics for understanding the propagation of high-order harmonics, are developed in chapter 2.In Chapter 3, studied the propagation of a high order harmonic fields generated by laser wavelength in the near infrared, targeted cells jets or low density gas. As a first test, we analyzed theoretically and experimentally the change in conditions of phase adjustment that results from positioning the gas stream at various positions along the axis of propagation. Once experimentally validated our theoretical method, we propose an alternative to shorten attosecond pulses, by detecting different angles from the axis of propagation. We then present a study of the transverse coherence length, comparing our theoretical and experimental results. Finally, we implemented the cell geometry of a semi-infinite gas in our propagation code, in order to understand the experimental results obtained by the group of M. Kovacev, University of Hannover (Germany).In Chapter 4 we have modified our method to study the harmonics generation ultra-high, produced using wavelength lasers in the mid-infrared (approximately 4 microns), in collaboration with the theoretical group A. Becker and A. Jaron-Becker, of JILA, University of Colorado (USA). The main result of this paper is the demonstration of the temporal coherence of X-rays with energy kiloelectronvoltio obtained in the experimental group M. Murnane and H. Kapteyn at JILA, University of Colorado (USA), who led an international collaboration which also included the Technical University of Vienna (Austria), Cornell University (USA) and our group. Further to this work, and thanks to the development of our theoretical methods, we have derived a way to obtain light pulses in the X-ray regime zeptosegundos (1 zeptosegundo = 10 to 21 seconds).

Published

2019

8. Enhancement of second harmonic microscopy images in collagen-based thick samples using radially polarized laser beams

Author

Martínez-Ojeda, Rosa M., Hernández-García, Carlos, and Bueno, Juan M.

Subjects

Physics, business.industry, European research, Polarization control, 02 engineering and technology, 021001 nanoscience & nanotechnology, Polarization (waves), 01 natural sciences, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, 010309 optics, Optics, Vector beam, Biological imaging, 0103 physical sciences, Microscopy, Harmonic, Physics::Accelerator Physics, 2209 Óptica, Electrical and Electronic Engineering, Physical and Theoretical Chemistry, 0210 nano-technology, business, Second harmonic microscopy, Laser beams

Abstract

[EN][The visualization of collagen-based tissues imaged with second harmonic generation (SHG) microscopy strongly depends on the polarization state of the scanning laser beam. This has been often explored using spatially homogeneous states (mainly linear or circular). However, vector beams (i.e. laser beams with spatially non-uniform polarization states) have become a powerful tool in different research field and technological applications. In particular, radially polarized vector beams are known to provide a tight focal spot and lateral resolution enhancement. Here we propose the use of radially polarized beams to improve the quality of SHG microscopy images. The performance of this particular type of vector beam is compared to that obtained with a circularly polarized light beam for different non-stained specimens and depth locations. Results show that independently of the sample’s thickness, the efficiency of SHG processes is increased when using the radially polarized beam, also leading to a higher image quality. Our results open the route for using vector beams to get a better visualization of biological details within the imaged areas, especially at deeper locations., This work was supported by Ministerio de Ciencia e Innovación, Spain, Agencia Estatal de Investigación to J. M. B. (PID2020-113919RB-I00). R. M. O. was granted by a fellowship from Agencia Estatal de Investigación, Spain (BES-2017-081691). C.H-.G. acknowledges support from Ministerio de Ciencia e Innovación, y Universidades, Spain for a Ramón y Cajal contract (RYC-2017-22745), and the European Research Council (ERC) under Grant Agreement No. 851201.

9. Ultrafast magnetic field induced by anisotropy in carbon nanotubes irradiated by intense laser fields

Author

Zurrón-Cifuentes Óscar, Martín-Doménech Sergio, García-Cabrera Ana, Hernández-García Carlos, and Plaja Luis

Subjects

Physics, QC1-999

Abstract

We report an unexpected result of the anisotropy of the nonlinear optical response of carbon nanotubes, inherent to their chirality. Using a model based on the resolution of the semiconductor Bloch equations, we theoretically demonstrate that, upon irradiation with an intense linearly polarized laser pulse along the axial direction, chiral nanotubes exhibit an oscillating azimuthal current that is absent in achiral species. This current induces a magnetic field parallel to the axis of the nanotube that radiates like a loop antenna.

Published

2024

10. High-order harmonic generation from ultrafast matter Talbot effect

Author

Plaja Luis, García-Cabrera Ana, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

High-order harmonic spectroscopy is a robust method for probing electron dynamics under the influence of a driving field, capturing phenomena as brief as attoseconds. It relies on the extreme non-linear process of high-harmonic generation (HHG), where intense laser pulses are directed at a material, causing it to emit high-energy photons in harmonics of the laser frequency. In this contribution we explore the possibility to generate high-order harmonics from low-dimensional crystalline solids driven under grazing incidence. We demonstrate that, in this unconventional geometry, the electron wavefunction is ejected from the solid and, subsequently, redirected to it to generate harmonics. Most appealingly, we show that the crystal’s periodicity imprinted in the electron’s wavefunction introduces a revival dynamics closely connected with the matter temporal Talbot effect. These Talbot oscillations are ultrafast (< femtosecond) and leave a distinct signature in the high-frequency harmonic spectrum, in the form of structures extending beyond the main spectral cutoff.

Published

2024

11. Integrating artificial intelligence into the simulation of structured laser-driven high harmonic generation

Author

Pablos-Marín José Miguel, Schmidt David D., de las Heras Alba, Westlake Nathaniel, Serrano Javier, Lei Yuhao, Kazansky Peter, Adams Daniel, Durfee Charles, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

High harmonic generation (HHG) stands as one of the most complex processes in strong-field physics, as it enables the conversion of laser light from the infrared to the extreme-ultraviolet or even the soft x-rays, enabling the synthesis and control of pulses lasting as short as tens of attoseconds. Accurately simulating this nonlinear and non-perturbative phenomena requires the coupling the dynamics of laser-driven electronic wavepackets, described by the three-dimensional time-dependent Schrödinger equation (3D-TDSE), with macroscopic Maxwell’s equations. Such calculations are extremely demanding due to the duality of microscopic and macroscopic nature of the process, thereby requiring the use of approximations. We develop a HHG method assisted by artificial intelligence that facilitates the simulation of macroscopic HHG within the framework of 3D-TDSE. This approach is particularly suited to simulate HHG driven by structured laser pulses. In particular, we demonstrate a self-interference effect in HHG driven by Hermite-Gauss beams. The theoretical and experimental agreement allows us to validate the AI-based model, and to identify a unique signature of the quantum nature of the HHG process.

Published

2024

12. Conversion of a beam carrying fractionnal angular momentum in High-Harmonics Generation

Author

Guer Matthieu, Luttmann Martin, Vimal Mekha, Hergott Jean-François, Zelaquett Khoury Antonio, Hernández-García Carlos, Pisanty Emilio, and Ruchon Thierry

Subjects

Physics, QC1-999

Abstract

Exotic light fields combining non-trivial spin and angular momentum may not be eigenstates of either the spin or orbital angular momenta operators. For these fields, it is relevant to define a Generalized Angular Momentum operator of which they are eigenvectors. Their associated eigenvalues can take, depending on the case, non-integer values. We report that this new quantity is conserved via non-linear phenomena, such as High Harmonic Generation.

Published

2023

13. Mapping partially polarized light to incoherent superpositions of vector beams and vortex beams with orbital angular momentum

Author

Marco David, del Mar Sánchez-López María, Hernández-García Carlos, and Moreno Ignacio

Subjects

Physics, QC1-999

Abstract

Fully polarized light, cylindrical vector beams, and beams with opposite orbital angular momentum (OAM) and their superpositions are respectively represented as points on the Poincaré sphere (PS), the higher-order Poincaré sphere (HOPS) and the OAM Poincaré sphere (OAMPS). Here, we study the mapping of inner points between these spheres, which we regard as incoherent superpositions of points on the surface of their respective sphere. We obtain points inside the HOPS and OAMPS by mapping incoherent superpositions of points on the PS, i.e., partially polarized states. To map points from the PS to the HOPS, we use a q-plate, while for mapping points from the HOPS to the OAMPS, we use a linear polarizer. Furthermore, we demonstrate a new polarization state generator (PSG) that generates efficiently partially polarized light. It uses a geometric phase (GP) blazed grating to split an unpolarized laser into two orthogonal polarization components. An intensity filter adjusts the relative intensity of the components, which are then recombined with another GP grating and directed to a waveplate, thus achieving every point inside the PS. The proposed PSG offers advantages over other methods in terms of energy efficiency, ease of alignment, and not requiring spatial or long-time integrations.

Published

2023

14. Machine-learning applied to the simulation of high harmonic generation driven by structured laser beams

Author

Serrano Javier, Pablos-Marín José Miguel, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

High harmonic generation (HHG) is one of the richest processes in strong-field physics. It allows to up-convert laser light from the infrared domain into the extreme-ultraviolet or even soft x-rays, that can be synthesized into laser pulses as short as tens of attoseconds. The exact simulation of such highly non-linear and non-perturbative process requires to couple the laser-driven wavepacket dynamics given by the three-dimensional time-dependent Schrödinger equation (3D-TDSE) with the Maxwell equations to account for macroscopic propagation. Such calculations are extremely demanding, well beyond the state-of-the-art computational capabilities, and approximations, such as the strong field approximation, need to be used. In this work we show that the use of machine learning, in particular deep neural networks, allows to simulate macroscopic HHG within the 3D-TDSE, revealing hidden signatures in the attosecond pulse emission that are neglected in the standard approximations. Our HHG method assisted by artificial intelligence is particularly suited to simulate the generation of soft x-ray structured attosecond pulses.

Published

2023

15. Ultra-high phase-locked harmonic generation from magnetic transversal confinement of electrons

Author

Plaja Luis, Martín-Hernández Rodrigo, Hu Hongtao, Baltuska Andrius, and Hernández-García Carlos

Subjects

Physics, QC1-999

Abstract

The technological refinements on high-power laser systems of Petawatt class unveil scenarios for light-matter interaction beyond the laser-plasma perspective. In this contribution we explore the possibility of assisting high-harmonic generation (HHG) with the strong magnetic field associated with one of those intense sources. Recently, there has been an interest in developing schemes to employ intense laser beams to define spatial volumes in which strong magnetic fields are found isolated from the electric field. In this conditions, the magnetic field can be used to assist the harmonic generation from atoms from standard drivers. We demonstrate that, using the proper interaction geometry, the magnetic field confines the transversal dynamics of the con-tinuum electrons allowing, on one side, to enhance the efficiency of the electron rescattering that produces the harmonic radiation and, on the other side, to excite the electron transverse dynamics and to convert this energy into phase-locked harmonic photons of few hundreds of eV.

Published

2023