Your search keyword '"Carrascoso F"' showing total 3 results

1. Improved strain engineering of 2D materials by adamantane plasma polymer encapsulation

Author

Carrascoso, F., Li, H., Obrero-Pérez, J.M., Aparicio, Francisco J., Borrás, Ana, Island, J,O., Barranco, Ángel, Castellanos-Gömez, A., Carrascoso, F., Li, H., Obrero-Pérez, J.M., Aparicio, Francisco J., Borrás, Ana, Island, J,O., Barranco, Ángel, and Castellanos-Gömez, A.

Abstract

Two-dimensional materials present exceptional crystal elasticity and provide an ideal platform to tune electrical and optical properties through the application of strain. Here we extend recent research on strain engineering in monolayer molybdenum disulfide using an adamantane plasma polymer pinning layer to achieve unprecedented crystal strains of 2.8%. Using micro-reflectance spectroscopy, we report maximum strain gauge factors of −99.5 meV/% and −63.5 meV/% for the A and B exciton of monolayer MoS, respectively, with a 50 nm adamantane capping layer. These results are corroborated with photoluminescence and Raman measurements on the same samples. Taken together, our results indicate that adamantane polymer is an exceptional capping layer to transfer substrate-induced strain to a 2D layer and achieve higher levels of crystal strain.

Published

2023

2. Author Correction: Enhanced stability in CH 3 NH 3 PbI 3 hybrid perovskite from mechano-chemical synthesis: structural, microstructural and optoelectronic characterization.

Author

López CA, Abia C, Rodrigues JE, Serrano-Sánchez F, Nemes NM, Martínez JL, Fernandez-Díaz MT, Biškup N, Alvarez-Galván C, Carrascoso F, Castellanos-Gomez A, and Alonso JA

Published

2022

3. Enhanced stability in CH 3 NH 3 PbI 3 hybrid perovskite from mechano-chemical synthesis: structural, microstructural and optoelectronic characterization.

Author

López CA, Abia C, Rodrigues JE, Serrano-Sánchez F, Nemes NM, Martínez JL, Fernandez-Díaz MT, Biškup N, Alvarez-Galván C, Carrascoso F, Castellanos-Gomez A, and Alonso JA

Abstract

Among the hybrid organic-inorganic perovskites MAPbX 3 (MA: methyl-ammonium CH 3 -NH 3 + , X = halogen), the triiodide specimen (MAPbI 3 ) is still the material of choice for solar energy applications. Although it is able to absorb light above its 1.6 eV bandgap, its poor stability in humid air atmosphere has been a major drawback for its use in solar cells. However, we discovered that this perovskite can be prepared by ball milling in a straightforward way, yielding specimens with a superior stability. This fact allowed us to take atomic-resolution STEM images for the first time, with sufficient quality to unveil microscopic aspects of this material. We demonstrated full Iodine content, which might be related to the enhanced stability, in a more compact PbI 6 framework with reduced unit-cell volume. A structural investigation from neutron powder diffraction (NPD) data of an undeuterated specimen was essential to determine the configuration of the organic MA unit in the 100-298 K temperature range. A phase transition is identified, from the tetragonal structure observed at RT (space group I4/mcm) to an orthorhombic (space group Pnma) phase where the methyl-ammonium organic units are fully localized. Our NPD data reveal that the MA changes are gradual and start before reaching the phase transition. Optoelectronic measurements yield a photocurrent peak at an illumination wavelength of 820 nm, which is redshifted by 30 nm with respect to previously reported measurements on MAPbI 3 perovskites synthesized by crystallization from organic solvents.

Published

2020