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Institution: |
CIMEC-CONICET-UNL |
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Type of Institution: |
Research Center |
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ORCID number: |
https://orcid.org/0000-0002-8242-7993
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Google Scholar: |
https://scholar.google.com/citations?user=vkzcYw2H0xoC
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Research Gate: |
https://www.researchgate.net/profile/Luisina-Forza
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Country: |
Argentina
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WEB address: |
https://www.conicet.gov.ar/new_scp/detalle.php?keywords=&id=44398&datos_academicos=yes |
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Working groups of interest |
| - | WG1 - Advances in Porous Materials and Technologies | | - | WG2 - Health | | - | WG3 - Energy | | - | WG4 - Environment |
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Research field (Free keywords) |
Nanostructure materials - Nanoparticle preparation - Material characterization - Magnetic materials - Porous materials - Phononic and photonic crystal |
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Scientific expertise |
Research in Experimental Physics, Nanostructure material preparation and characterization. Research in Materials Science and Condensed Matter Physics. Production line of porous materials as matrices to produce nanocomposites and multiple applications: Fabricate of nanowires, Improve the stability of perovskites for the manufacture of higher efficiency solar cells, Prepare of hybrid, chemical, and biological sensors, Design of double opto-acoustic sensors. Structural characterization using AFM and SEM microscopes and optical and optofluidic methods. Study of magnetism and ferromagnetic materials, manufacture of porous alumina nanocomposites and ferromagnetic nanowires to sense local deformations. Magnetic anisotropy analysis by FMR, VSM, SQUID. Currenty added the use of computational methods to study the behaviour of opto-acoustic porous systems. |
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Capabilities |
Extensive experience in the design, preparation and characterization of porous materials. Design of experimental setups. Study and characterization of the optical and magnetic materials properties. Knowledge of optofluidic and interferometric techniques for the analysis of porous materials. Currently incorporating computational simulation and calculation techniques, and tools to enhance the design of materials and their applications. In conclusion, I hope to get the opportunity to join the project, considering my academics and research performances so far, my desire to enrich mine and other´s knowledge in this subject, I am convinced that I could be a valuable addition to the project. |
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Relevant publications
(3 max.) |
| (1) Design and optimization of an opto-acoustic sensor based on porous silicon phoxonic crystals. Sensors and Actuators A: Physical, 2021. DOI: 10.1016/j.sna.2021.112915. |
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| (2) Sensing anisotropic stresses with ferromagnetic nanowires. Applied Physics Letters, 2020. DOI: 10.1063/1.5132539. |
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| (3) Normal incidence birefringence in nanoporous alumina. Optical Materials, 2021. DOI: 10.1016/j.optmat. |
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Projects
(2 max.) |
| Multiparametric sensors with Opto-Acoustic porous materials. Expanding knowledge in the area of phononic and photonic materials. |
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