Obtuvo la Licenciatura en Física, la Maestría y el Doctorado en Ciencia e Ingeniería de Materiales en la UNAM. Es Profesor Titular C en el Instituto Politécnico Nacional en la ESIME-Culhuacan, donde formó y coordina el Grupo de Investigación en Nanociencias. Pertenece al Sistema Nacional de Investigadores (SNI)-Nivel 3, ha dirigido 16 tesis doctorales, una estancia sabática, una posdoctoral y tres estancias de investigación en el programa de retención del CONACyT, 29 tesis de maestría y 11 de licenciatura, tres de las cuales han obtenido el premio a la mejor tesis de maestría y de doctorado en el IPN y un premio a la mejor tesis doctoral por parte de la UNAM. Ha publicado 121 artículos en revistas internacionales indizadas en el Journal Citation Reports con un alto factor de impacto, así como 37 artículos in extenso como memorias de congresos. Sus trabajos de investigación se han presentado en más de 250 congresos nacionales e internacionales de reconocida calidad académica. Se ha desempeñado como revisor en revistas internacionales como Applied Surface Science, Nanoscale, Physica E, Physica B, Physica Status Solidi (b) así como el Journal of Energy Storage por citar algunas. Adicionalmente ha sido Responsable Técnico de proyectos financiados por el CONACyT, el ICyTDF y el IPN, además ha coordinado varios proyectos multidisciplinarios en el IPN. Fue Presidente de la División de Estado Sólido de la Sociedad Mexicana de Física. Pertenece a la Academia Mexicana de Ciencias. En su trayectoria docente en el IPN, participó en la creación de la carrera de Ingeniería en Computación, así como la Maestría en Ciencias de Ingeniería en Sistemas Energéticoas y fue Coordinador del Doctorado en Comunicaciones y Electrónica a este último se le otorgó la categoría de programa de Competencia Internacional como resultad ode la evaluación en el Programa Nacional de Posgrados de Calidad (PNPC) del CONACyT. Una de sus líneas de investigación son las propiedades electrónicas, ópticas y vibracionales de semiconductores nanoestructurados con aplicaciones en comunicaciones y electrónica, así como en el almacenamiento y conversión de energía.
González, Israel; Pilo, Jorge; Trejo, Alejandro; Miranda, Álvaro; Salazar, Fernando; Nava, Rocío; Cruz-Irisson, Miguel
Sodium effects on the electronic and structural properties of porous silicon for energy storage Artículo de revista
En: International Journal of Energy Research, vol. 46, no 7, pp. 8760-8780, 2022.
Resumen | Enlaces | BibTeX | Etiquetas: DFT, Na-batteries, NEB, porous silicon
@article{https://doi.org/10.1002/er.7754,
title = {Sodium effects on the electronic and structural properties of porous silicon for energy storage},
author = {Israel Gonz\'{a}lez and Jorge Pilo and Alejandro Trejo and \'{A}lvaro Miranda and Fernando Salazar and Roc\'{i}o Nava and Miguel Cruz-Irisson},
url = {https://onlinelibrary.wiley.com/doi/abs/10.1002/er.7754},
doi = {https://doi.org/10.1002/er.7754},
year = {2022},
date = {2022-01-01},
journal = {International Journal of Energy Research},
volume = {46},
number = {7},
pages = {8760-8780},
abstract = {Summary Porous silicon is a promising anode material in Na-ion batteries, however, there are still no theoretical studies describing the Na storage mechanism within this material. In this work, we present a density functional theory study on the effects of interstitial and substitutional Na atoms on the electronic and structural properties of hydrogen-passivated porous silicon (pSiH). The results show that the substitutional Na reduces the band gap, while the interstitial Na induces metallic properties on the pSiH. The diffusion analysis by the nudged elastic band scheme, reveals that the interstitial Na atoms migrate from the silicon lattice to the pore surface, while the pSiH energy barrier decreases by 20.42% relative to the bulk silicon energy barrier value. Finally, the hydrogenated surface proves to be beneficial for both Na adsorption and diffusion. These results could be important for understanding the storage and diffusion mechanism of Na on pSiH .},
keywords = {DFT, Na-batteries, NEB, porous silicon},
pubstate = {published},
tppubtype = {article}
}
González, Israel; Santiago, Francisco De; Arellano, Lucía G.; Miranda, Álvaro; Trejo, Alejandro; Salazar, Fernando; Cruz-Irisson, Miguel
Theoretical modelling of porous silicon decorated with metal atoms for hydrogen storage Artículo de revista
En: International Journal of Hydrogen Energy, vol. 45, no 49, pp. 26321-26333, 2020, ISSN: 0360-3199, (Progress in Hydrogen Production and Utilization).
Resumen | Enlaces | BibTeX | Etiquetas: Beryllium, DFT, Hydrogen storage, Lithium, Palladium, porous silicon
@article{GONZALEZ202026321,
title = {Theoretical modelling of porous silicon decorated with metal atoms for hydrogen storage},
author = {Israel Gonz\'{a}lez and Francisco De Santiago and Luc\'{i}a G. Arellano and \'{A}lvaro Miranda and Alejandro Trejo and Fernando Salazar and Miguel Cruz-Irisson},
url = {https://www.sciencedirect.com/science/article/pii/S0360319920318784},
doi = {https://doi.org/10.1016/j.ijhydene.2020.05.097},
issn = {0360-3199},
year = {2020},
date = {2020-01-01},
journal = {International Journal of Hydrogen Energy},
volume = {45},
number = {49},
pages = {26321-26333},
abstract = {There is experimental evidence suggesting that metal adatoms enhance the physisorption of hydrogen molecules in porous silicon. However, theoretical reports about the physical properties for this material to be suitable for hydrogen storage are scarce. Thus, in this work we employ Density Functional Theory to study the effects of decoration with metals on the hydrogen-adsorption properties on hydrogen-passivated porous silicon. The results indicate that lithium and palladium decorating atoms are strongly bonded to the porous silicon\textemdashpreventing the adverse effects of clusterization\textemdashwhile beryllium is not. Lithium and palladium exhibit physisorption capacity up to 5 and 4 hydrogen molecules per adatom, respectively. In contrast, adsorption of hydrogen molecules in beryllium is too weak as the adatom is not chemisorbed on the surface of the pore. The hydrogen passivation of the pore surface proves to be beneficial for a strong chemisorption of the decorating atoms.},
note = {Progress in Hydrogen Production and Utilization},
keywords = {Beryllium, DFT, Hydrogen storage, Lithium, Palladium, porous silicon},
pubstate = {published},
tppubtype = {article}
}
Santiago, Francisco; Santana, José Eduardo; Miranda, Álvaro; Trejo, Alejandro; Vázquez-Medina, Rubén; Pérez, Luis Antonio; Cruz-Irisson, Miguel
Quasi-one-dimensional silicon nanostructures for gas molecule adsorption: a DFT investigation Artículo de revista
En: Applied Surface Science, vol. 475, pp. 278-284, 2019, ISSN: 0169-4332.
Resumen | Enlaces | BibTeX | Etiquetas: Chemical sensors, Density Functional Theory, Molecule adsorption, porous silicon, Sensing, Silicon nanowires
@article{DESANTIAGO2019278,
title = {Quasi-one-dimensional silicon nanostructures for gas molecule adsorption: a DFT investigation},
author = {Francisco Santiago and Jos\'{e} Eduardo Santana and \'{A}lvaro Miranda and Alejandro Trejo and Rub\'{e}n V\'{a}zquez-Medina and Luis Antonio P\'{e}rez and Miguel Cruz-Irisson},
url = {https://www.sciencedirect.com/science/article/pii/S0169433218336109},
doi = {https://doi.org/10.1016/j.apsusc.2018.12.258},
issn = {0169-4332},
year = {2019},
date = {2019-01-01},
journal = {Applied Surface Science},
volume = {475},
pages = {278-284},
abstract = {Porous structures offer an enormous surface suitable for gas sensing, however, the effects of their quantum quasi-confinement on their molecular sensing capacities has been seldom studied. In this work the gas-sensing capability of silicon nanopores is investigated by comparing it to silicon nanowires using first principles calculations. In particular, the adsorption of toxic gas molecules CO, NO, SO2 and NO2 on both silicon nanopores and nanowires with the same cross sections was studied. Results show that sensing-related properties of silicon nanopores and nanowires are very similar, suggesting that surface effects are predominant over the confinement. However, there are certain cases where there are remarked differences between the nanowire and porous cases, for instance, CO-adsorbed nanoporous silicon shows a metallic band structure unlike its nanowire counterpart, which remains semiconducting, suggesting that quantum quasi-confinement may be playing an important role in this behaviour. These results are significant in the study of the quantum phenomena behind the adsorption of gas molecules on nanostructure’s surfaces, with possible applications in chemical detectors or catalysts.},
keywords = {Chemical sensors, Density Functional Theory, Molecule adsorption, porous silicon, Sensing, Silicon nanowires},
pubstate = {published},
tppubtype = {article}
}
© 2022 Grupo de Investigación en Nanociencias de ESIME Culhuacan | All Rights Reserved. | Hecho por Vleeko Agencia de Marketing Digital CDMX
¡Escríbenos!