Your search keyword '"E. López-Elvira"' showing total 8 results

1. Low T direct plasma assisted growth of graphene on sapphire and its integration in graphene/MoS2 heterostructure-based photodetectors

Author

R. Muñoz, E. López-Elvira, C. Munuera, F. Carrascoso, Y. Xie, O. Çakıroğlu, T. Pucher, S. Puebla, A. Castellanos-Gomez, and M. García-Hernández

Subjects

Materials of engineering and construction. Mechanics of materials, TA401-492, Chemistry, QD1-999

Abstract

Abstract We report on outstanding photo-responsivity, R > 103 A/W, fast response (~0.1 s), and broadband sensitivity ranging from the UV to the NIR in two terminal graphene/MoS2 photodetectors. Our devices are based on the deterministic transfer of MoS2 on top of directly grown graphene on sapphire, and their performance outperforms previous similar photodetectors using large-scale grown graphene. Here we devise a protocol for the direct growth of transparent (transmittance, Tr > 90%), highly conductive (sheet resistance, R □

Published

2023

2. Hydrogen-Induced Reduction Improves the Photoelectrocatalytic Performance of Titania.

Author

Sánchez-Sánchez C, Muñoz R, Alfonso-González E, Barawi M, Martínez JI, López-Elvira E, Sánchez-Santolino G, Shibata N, Ikuhara Y, Ellis GJ, García-Hernández M, López MF, de la Peña O'Shea VA, and Martín-Gago JA

Abstract

One of the main challenges to expand the use of titanium dioxide (titania) as a photocatalyst is related to its large band gap energy and the lack of an atomic scale description of the reduction mechanisms that may tailor the photocatalytic properties. We show that rutile TiO 2 single crystals annealed in the presence of atomic hydrogen experience a strong reduction and structural rearrangement, yielding a material that exhibits enhanced light absorption, which extends from the ultraviolet to the near-infrared (NIR) spectral range, and improved photoelectrocatalytic performance. We demonstrate that both magnitudes behave oppositely: heavy/mild plasma reduction treatments lead to large/negligible spectral absorption changes and poor/enhanced (×10) photoelectrocatalytic performance, as judged from the higher photocurrent. To correlate the photoelectrochemical performance with the atomic and chemical structures of the hydrogen-reduced materials, we have modeled the process with in situ scanning tunneling microscopy measurements, which allow us to determine the initial stages of oxygen desorption and the desorption/diffusion of Ti atoms from the surface. This multiscale study opens a door toward improved materials for diverse applications such as more efficient rutile TiO 2 -based photoelectrocatalysts, green photothermal absorbers for solar energy applications, or NIR-sensing materials., Competing Interests: The authors declare no competing financial interest., (© 2024 The Authors. Published by American Chemical Society.)

Published

2024

3. Acrylates Polymerization on Covalent Plasma-Assisted Functionalized Graphene: A Route to Synthesize Hybrid Functional Materials.

Author

Muñoz R, León-Boigues L, López-Elvira E, Munuera C, Vázquez L, Mompeán F, Martín-Gago JÁ, Palacio I, and García-Hernández M

Abstract

The modification of the surface properties of graphene with polymers provides a method for expanding its scope into new applications as a hybrid material. Unfortunately, the chemical inertness of graphene hinders the covalent functionalization required to build them up. Developing new strategies to enhance the graphene chemical activity for efficient and stable functionalization, while preserving its electronic properties, is a major challenge. We here devise a covalent functionalization method that is clean, reproducible, scalable, and technologically relevant for the synthesis of a large-scale, substrate-supported graphene-polymer hybrid material. In a first step, hydrogen-assisted plasma activation of p -aminophenol ( p -AP) linker molecules produces their stable and covalent attachment to large-area graphene. Second, an in situ radical polymerization reaction of 2-hydroxyethyl acrylate (HEA) is carried out on the functionalized surface, leading to a graphene-polymer hybrid functional material. The functionalization with a hydrophilic and soft polymer modifies the hydrophobicity of graphene and might enhance its biocompatibility. We have characterized these hybrid materials by atomic force microscopy (AFM), X-Ray photoelectron spectroscopy (XPS) and Raman spectroscopy and studied their electrical response, confirming that the graphene/ p -AP/PHEA architecture is anchored covalently by the sp 3 hybridization and controlled polymerization reaction on graphene, retaining its suitable electronic properties. Among all the possibilities, we assess the proof of concept of this graphene-based hybrid platform as a humidity sensor. An enhanced sensitivity is obtained in comparison with pristine graphene and related materials. This functional nanoarchitecture and the two-step strategy open up future potential applications in sensors, biomaterials, or biotechnology fields.

Published

2023

4. Direct synthesis of graphene on silicon oxide by low temperature plasma enhanced chemical vapor deposition.

Author

Muñoz R, Martínez L, López-Elvira E, Munuera C, Huttel Y, and García-Hernández M

Abstract

Direct graphene growth on silicon with a native oxide using plasma enhanced chemical vapour deposition at low temperatures [550 °C-650 °C] is demonstrated for the first time. It is shown that the fine-tuning of a two-step synthesis with gas mixtures C2H2/H2 yields monolayer and few layer graphene films with a controllable domain size from 50 nm to more than 300 nm and the sheet resistance ranging from 8 kΩ sq-1 to less than 1.8 kΩ sq-1. Differences are understood in terms of the interaction of the plasma species - chiefly atomic H - with the deposited graphene and the native oxide layer. The proposed low temperature direct synthesis on an insulating substrate does not require any transfer processes and improves the compatibility with the current industrial processes.

Published

2018

5. Chemistry below graphene: decoupling epitaxial graphene from metals by potential-controlled electrochemical oxidation.

Author

Palacio I, Otero-Irurueta G, Alonso C, Martínez JI, López-Elvira E, Muñoz-Ochando I, Salavagione HJ, López MF, García-Hernández M, Méndez J, Ellis GJ, and Martín-Gago JA

Abstract

While high-quality defect-free epitaxial graphene can be efficiently grown on metal substrates, strong interaction with the supporting metal quenches its outstanding properties. Thus, protocols to transfer graphene to insulating substrates are obligatory, and these often severely impair graphene properties by the introduction of structural or chemical defects. Here we describe a simple and easily scalable general methodology to structurally and electronically decouple epitaxial graphene from Pt(111) and Ir(111) metal surfaces. A multi-technique characterization combined with ab-initio calculations was employed to fully explain the different steps involved in the process. It was shown that, after a controlled electrochemical oxidation process, a single-atom thick metal-hydroxide layer intercalates below graphene, decoupling it from the metal substrate. This decoupling process occurs without disrupting the morphology and electronic properties of graphene. The results suggest that suitably optimized electrochemical treatments may provide effective alternatives to current transfer protocols for graphene and other 2D materials on diverse metal surfaces.

Published

2018

6. Optical contrast and refractive index of natural van der Waals heterostructure nanosheets of franckeite.

Author

Gant P, Ghasemi F, Maeso D, Munuera C, López-Elvira E, Frisenda R, De Lara DP, Rubio-Bollinger G, Garcia-Hernandez M, and Castellanos-Gomez A

Abstract

We study mechanically exfoliated nanosheets of franckeite by quantitative optical microscopy. The analysis of transmission-mode and epi-illumination-mode optical microscopy images provides a rapid method to estimate the thickness of the exfoliated flakes at first glance. A quantitative analysis of the optical contrast spectra by means of micro-reflectance allows one to determine the refractive index of franckeite over a broad range of the visible spectrum through a fit of the acquired spectra to a model based on the Fresnel law.

Published

2017

7. Hybrid titania-aminosilane platforms evaluated with human mesenchymal stem cells.

Author

Manso-Silván M, Rodríguez-Navas C, Arroyo-Hernández M, López-Elvira E, Gago R, Vázquez L, Agulló-Rueda F, Climent A, Martínez-Duart JM, and García-Ruiz JP

Subjects

Biocompatible Materials chemistry, Cells, Cultured, Humans, Hydrogen-Ion Concentration, Imines chemistry, Materials Testing, Mesenchymal Stem Cells cytology, Silanes chemistry, Titanium chemistry, Biocompatible Materials metabolism, Mesenchymal Stem Cells physiology, Silanes metabolism, Titanium metabolism

Abstract

The properties of hybrid aminopropyltriethoxysilane-tetraisopropylorthotitanate (APTS-TIPT) platforms prepared by a sol-gel route have been explored, and their biocompatibility was assayed after culture of human mesenchymal stem cells (hMSCs). The organic content of this material was observed to be preferably surface-oriented as indicated by microanalytical techniques. Furthermore, the surface showed characteristic amino-silane bands when explored by Raman spectroscopy as well as indications of silane and titanate condensation. Surface activity of the amino groups was probed by ultraviolet-visible spectroscopy imine derivatization and chemical force spectroscopy, showing a pH-dependent surface charge-induced potential. hMSCs cultured onto these surfaces showed relevant differences with respect to their behavior on gelatin-coated glass plates. Even if with a lower proliferative rate than controls, the cells develop long cytosolic prolongations in osteogenic differentiation medium, thus, supporting the idea of an APTS-TIPT stimulated process.

Published

2007

8. One step processing of aminofunctionalized gate oxides.

Author

Arroyo-Hernández M, Manso-Silvan M, López-Elvira E, Muñoz A, Climent A, and Duart JM

Subjects

Propylamines, Silanes, Silicon Dioxide, Spectroscopy, Fourier Transform Infrared, Biosensing Techniques instrumentation, Transistors, Electronic

Abstract

A plasma discharge process has been developed that allows the growth of biosensor gate oxides with adapted surface properties for the direct application of biomolecular immobilization cascades. The process involves an accurate selection of processing conditions, mainly, low temperature evaporation of (3-aminopropyl)triethoxysilane (APTS) and dynamic power and flow conditions. Room temperature evaporation of APTS was achieved by designing a vessel with an internal capillary network. The initial high power (100 W) plasma conditions were replaced by milder molecular fragmentation (50 W, 25 W) in a pure Ar discharge. Under these conditions the thin SiO(2) layers presented graded properties with a denser layer at the Si (100) interface and a hybrid organic-inorganic structure at the surface. The chemistry of the films was analysed by Fourier transformed infrared spectroscopy (FTIR) and Rutherford backscattering spectroscopy combined with elastic recoil detection analysis (RBS, ERDA), which confirmed the presence of the SiO(2) and organic phases. Contact angle measurements indicate the higher contribution of the basic polar component to the surface free energy. Furthermore, the higher affinity of the surface towards biomolecular immobilization was confirmed by fluorescence microscopy. Finally, penetration of nitrobenzaldehyde was obtained by application of a molecular permeation method evaluated by UV-vis spectroscopy onto fused silica substrates.

Published

2007