Your search keyword '"López-Polín, G."' showing total 13 results

1. Improved graphene blisters by ultrahigh pressure sealing

Author

Manzanares-Negro, Y., Ares, P., Jaafar, M., López-Polín, G., Gómez-Navarro, C., and Gómez-Herrero, J.

Subjects

Condensed Matter - Materials Science

Abstract

Graphene is a very attractive material for nanomechanical devices and membrane applications. Graphene blisters based on silicon oxide micro-cavities are a simple but relevant example of nanoactuators. A drawback of this experimental set up is that gas leakage through the graphene-SiO2 interface contributes significantly to the total leak rate. Here we study the diffusion of air from pressurized graphene drumheads on SiO2 micro-cavities and propose a straightforward method to improve the already strong adhesion between graphene and the underlying SiO2 substrate, resulting in reduced leak rates. This is carried out by applying controlled and localized ultrahigh pressure (> 10 GPa) with an Atomic Force Microscopy diamond tip. With this procedure, we are able to significantly approach the graphene layer to the SiO2 surface around the drumheads, thus enhancing the interaction between them allowing us to better seal the graphene-SiO2 interface, which is reflected in up to ~ 4 times lower leakage rates. Our work opens an easy way to improve the performance of graphene as a gas membrane on a technological relevant substrate such as SiO2., Comment: pages 19, 4 figures + supplementary information

Published

2018

2. The influence of strain on the elastic constants of graphene

Author

López-Polín G., Jaafar M., Guinea F., Roldán R., Gómez-Navarro C., Gómez-Herrero J. and We acknowledge M. Katsnelson, A. Fasolino, R. Perez and P. San José for fruitful discussions, and R. P. Pelaez for technical support. Financial support was received from P2013/MIT-3007, MAT2016-77608-C3-3-P, MAD2D-CM, S2013/MIT-3007, CSD2010-0024, FIS2014-58445-JIN and the ERC Advanced Grant , #290846 . Appendix A

Published

2017

3. The influence of strain on the elastic constants of graphene

Author

López-Polín G., Jaafar M., Guinea, Francisco, Roldán R., Gómez-Navarro C., Gómez-Herrero J., López-Polín G., Jaafar M., Guinea, Francisco, Roldán R., Gómez-Navarro C., and Gómez-Herrero J.

Published

2017

4. The influence of strain on the elastic constants of graphene

Author

Ministerio de Ciencia e Innovación (España), Comunidad de Madrid, European Research Council, Ministerio de Economía y Competitividad (España), López-Polín, G., Jaafar, Miriam, Guinea, F., Roldán, R., Gómez-Navarro, C., Gómez-Herrero, J., Ministerio de Ciencia e Innovación (España), Comunidad de Madrid, European Research Council, Ministerio de Economía y Competitividad (España), López-Polín, G., Jaafar, Miriam, Guinea, F., Roldán, R., Gómez-Navarro, C., and Gómez-Herrero, J.

Abstract

Recent advances in the understanding of graphene elasticity have shown that suspended graphene does not behave as a conventional thin plate but has a more complex behavior where flexural modes play a significant role. Among other effects, out-of-plane thermal fluctuations modify the in-plane elastic properties. Here we report indentation experiments on graphene subjected to strain. This strain is achieved by applying pressure difference across suspended graphene drumheads. Our indentation curves show an increased mechanical response at strains larger than 0.3%. Finite element simulations of the indentation curves on pressurized membranes show that this observation can be ascribed to a twofold increase of the in-plane elastic modulus and the Poisson ratio. Based in the thermodynamic theory of elastic membranes, this increase is attributed to the suppression of out-of-plane fluctuations by strain. This result reinforces the idea that suspended graphene behaves as a fluctuating membrane and points out that a careful analysis should be done when analyzing indentation curves on atomic thick materials.

Published

2017

5. The influence of strain on the elastic constants of graphene

Author

López-Polín, G., primary, Jaafar, M., additional, Guinea, F., additional, Roldán, R., additional, Gómez-Navarro, C., additional, and Gómez-Herrero, J., additional

Published

2017

6. Atomic Force Microscopy In High Vacuum: Experiments On Graphitic Surfaces

Author

Jaafar, Miriam, López Polín, G., Martínez Martín, D., Gómez-Navarro, Cristina, and Gómez-Herrero, J.

Abstract

Trabajo presentado en la conferencia Fuerzas y Túnel (FyT2014), celebrada en San Sebastián del 27 al 29 de agosto de 2014., Atomic Force Microscopy (AFM) working in high vacuum (HV) conditions is a valuable technique due to its sensitivity and versatility. In this work we present different experiments in carbon-based materials. We use the HV-AFM to perform different experiments on graphitic surfaces like graphene and graphene oxide (GO). Graphene can be described as one-atom thick layer of graphite. For many applications, the interaction of graphene and GO with the supporting substrate and with adjacent layers plays a relevant role in properties such as adhesion, charge transfer [1], doping level etc. Furthermore, it is important to take into account the presence of atmospheric contaminants for a correct interpretation of experimental data [2]. Finally, we have studied the influence of a pressure difference onto the mechanical properties of suspended graphene membranes [3]. We have studied the diffusion through these membranes as a function of the kinetic diameter of the gas molecules [4] (Figure 1).

Published

2014

7. Exfoliated graphite flakes as soft-electrodes for precisely contacting nanoobjects

Author

Ares, P, primary, López-Polín, G, additional, Hermosa, C, additional, Zamora, F, additional, Gómez-Herrero, J, additional, and Gómez-Navarro, C, additional

Published

2015

8. Step like surface potential on few layered graphene oxide

Author

Jaafar, M., primary, López-Polín, G., additional, Gómez-Navarro, C., additional, and Gómez-Herrero, J., additional

Published

2012

9. Broad Adaptability of Coronavirus Adhesion Revealed from the Complementary Surface Affinity of Membrane and Spikes.

Author

García-Arribas AB, Ibáñez-Freire P, Carlero D, Palacios-Alonso P, Cantero-Reviejo M, Ares P, López-Polín G, Yan H, Wang Y, Sarkar S, Chhowalla M, Oksanen HM, Martín-Benito J, de Pablo PJ, and Delgado-Buscalioni R

Abstract

Coronavirus stands for a large family of viruses characterized by protruding spikes surrounding a lipidic membrane adorned with proteins. The present study explores the adhesion of transmissible gastroenteritis coronavirus (TGEV) particles on a variety of reference solid surfaces that emulate typical virus-surface interactions. Atomic force microscopy informs about trapping effectivity and the shape of the virus envelope on each surface, revealing that the deformation of TGEV particles spans from 20% to 50% in diameter. Given this large deformation range, experimental Langmuir isotherms convey an unexpectedly moderate variation in the adsorption-free energy, indicating a viral adhesion adaptability which goes beyond the membrane. The combination of an extended Helfrich theory and coarse-grained simulations reveals that, in fact, the envelope and the spikes present complementary adsorption affinities. While strong membrane-surface interaction lead to highly deformed TGEV particles, surfaces with strong spike attraction yield smaller deformations with similar or even larger adsorption-free energies., (© 2024 The Author(s). Advanced Science published by Wiley‐VCH GmbH.)

Published

2024

10. Fatigue Response of MoS 2 with Controlled Introduction of Atomic Vacancies.

Author

Manzanares-Negro Y, Zambudio A, López-Polín G, Sarkar S, Chhowalla M, Gómez-Herrero J, and Gómez-Navarro C

Abstract

Fatigue-induced failure resulting from repetitive stress-strain cycles is a critical concern in the development of robust and durable nanoelectromechanical devices founded on 2D semiconductors. Defects, such as vacancies and grain boundaries, inherent in scalable materials can act as stress concentrators and accelerate fatigue fracture. Here, we investigate MoS 2 with controlled atomic vacancies, to elucidate its mechanical reliability and fatigue response as a function of atomic defect density. High-quality MoS 2 demonstrates an exceptional fatigue response, enduring 10 9 cycles at 80% of its breaking strength (13.5 GPa), surpassing the fatigue resistance of steel and approaching that of graphene. The introduction of atomic defect densities akin to those generated during scalable synthesis processes (∼10 12 cm -2 ) reduces the fatigue strength to half the breaking strength. Our findings also point toward a sudden defect reconfiguration prior to global failure as the primary fatigue mechanism, offering valuable insights into structure-property relationships.

Published

2023

11. Confined Crack Propagation in MoS 2 Monolayers by Creating Atomic Vacancies.

Author

Manzanares-Negro Y, López-Polín G, Fujisawa K, Zhang T, Zhang F, Kahn E, Perea-López N, Terrones M, Gómez-Herrero J, and Gómez-Navarro C

Abstract

In two-dimensional crystals, fractures propagate easily, thus restricting their mechanical reliability. This work demonstrates that controlled defect creation constitutes an effective approach to avoid catastrophic failure in MoS 2 monolayers. A systematic study of fracture mechanics in MoS 2 monolayers as a function of the density of atomic vacancies, created by ion irradiation, is reported. Pristine and irradiated materials were studied by atomic force microscopy, high-resolution scanning transmission electron microscopy, and Raman spectroscopy. By inducing ruptures through nanoindentations, we determine the strength and length of the propagated cracks within MoS 2 atom-thick membranes as a function of the density and type of the atomic vacancies. We find that a 0.15% atomic vacancy induces a decrease of 40% in strength with respect to that of pristine samples. In contrast, while tear holes in pristine 2D membranes span several microns, they are restricted to a few nanometers in the presence of atomic and nanometer-sized vacancies, thus increasing the material's fracture toughness.

Published

2021

12. Improved Graphene Blisters by Ultrahigh Pressure Sealing.

Author

Manzanares-Negro Y, Ares P, Jaafar M, López-Polín G, Gómez-Navarro C, and Gómez-Herrero J

Abstract

Graphene is a very attractive material for nanomechanical devices and membrane applications. Graphene blisters based on silicon oxide microcavities are a simple but relevant example of nanoactuators. A drawback of this experimental setup is that gas leakage through the graphene-SiO 2 interface contributes significantly to the total leak rate. Here, we study the diffusion of air from pressurized graphene drumheads on SiO 2 microcavities and propose a straightforward method to improve the already strong adhesion between graphene and the underlying SiO 2 substrate, resulting in reduced leak rates. This is carried out by applying controlled and localized ultrahigh pressure (>10 GPa) with an atomic force microscopy diamond tip. With this procedure, we are able to significantly approach the graphene layer to the SiO 2 surface around the drumheads, thus enhancing the interaction between them, allowing us to better seal the graphene-SiO 2 interface, which is reflected in up to ∼ 4 times lower leakage rates. Our work opens an easy way to improve the performance of graphene as a gas membrane on a technological relevant substrate such as SiO 2 .

Published

2020

13. Confining crack propagation in defective graphene.

Author

López-Polín G, Gómez-Herrero J, and Gómez-Navarro C

Abstract

Crack propagation in graphene is essential to understand mechanical failure in 2D materials. We report a systematic study of crack propagation in graphene as a function of defect content. Nanoindentations and subsequent images of graphene membranes with controlled induced defects show that while tears in pristine graphene span microns length, crack propagation is strongly reduced in the presence of defects. Accordingly, graphene oxide exhibits minor crack propagation. Our work suggests controlled defect creation as an approach to avoid catastrophic failure in graphene.

Published

2015