Your search keyword '"Rodriguez-Nieva, J. F."' showing total 10 results

1. Thermionic Emission and Negative dI/dV in Photoactive Graphene Heterostructures

Author

Rodriguez-Nieva, J. F., Dresselhaus, M. S., and Levitov, L. S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Transport in photoactive graphene heterostructures, originating from the dynamics of photogenerated hot carriers, is governed by the processes of thermionic emission, electron-lattice thermal imbalance and cooling. These processes give rise to interesting photoresponse effects, in particular negative differential resistance (NDR) arising in the hot-carrier regime. The NDR effect stems from a strong dependence of electron-lattice cooling on the carrier density, which results in the carrier temperature dropping precipitously upon increasing bias. The ON-OFF switching between the NDR regime and the conventional cold emission regime, as well as the gate-controlled closed-circuit current that is present at zero bias voltage, can serve as signatures of hot-carrier dominated transport., Comment: 8 pgs, 4 fgs

Published

2015

2. Disorder-induced double resonant Raman process in graphene

Author

Rodriguez-Nieva, J. F., Barros, E. B., Saito, R., and Dresselhaus, M. S.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

An analytical study is presented of the double resonant Raman scattering process in graphene, responsible for the D and D$^{\prime}$ features in the Raman spectra. This work yields analytical expressions for the D and D$^{\prime}$ integrated Raman intensities that explicitly show the dependencies on laser energy, defect concentration, and electronic lifetime. Good agreement is obtained between the analytical results and experimental measurements on samples with increasing defect concentrations and at various laser excitation energies. The use of Raman spectroscopy to identify the nature of defects is discussed. Comparison between the models for the edge-induced and the disorder-induced D band intensity suggests that edges or grain boundaries can be distinguished from disorder by the different dependence of their Raman intensity on laser excitation energy. Similarly, the type of disorder can potentially be identified not only by the intensity ratio $I_{\mathrm{D}}/I_{\mathrm{D}^{\prime}}$, but also by its laser energy dependence. Also discussed is a quantitative analysis of quantum interference effects of the graphene wavefunctions, which determine the most important phonon wavevectors and scattering processes responsible for the D and D$^{\prime}$ bands., Comment: 10 pages, 4 figures

Published

2014

3. Sputtering from a Porous Material by Penetrating Ions

Author

Rodriguez-Nieva, J. F, Bringa, E. M, Cassidy, T. A, Johnson, R. E, Caro, A, Fama, M, Loeffler, M, Baragiola, R. A, and Farkas, D

Subjects

Space Sciences (General)

Abstract

Porous materials are ubiquitous in the universe and weathering of porous surfaces plays an important role in the evolution of planetary and interstellar materials. Sputtering of porous solids in particular can influence atmosphere formation, surface reflectivity, and the production of the ambient gas around materials in space, Several previous studies and models have shown a large reduction in the sputtering of a porous solid compared to the sputtering of the non-porous solid. Using molecular dynamics simulations we study the sputtering of a nanoporous solid with 55% of the solid density. We calculate the electronic sputtering induced by a fast, penetrating ion, using a thermal spike representation of the deposited energy. We find that sputtering for this porous solid is, surprisingly, the same as that for a full-density solid, even though the sticking coefficient is high.

Published

2012

4. Resonant tunneling and intrinsic bistability in twisted graphene structures

Author

Rodriguez-Nieva, J. F., primary, Dresselhaus, M. S., additional, and Levitov, L. S., additional

Published

2016

5. Disorder-induced double resonant Raman process in graphene

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Dresselhaus, Mildred, Rodriguez-Nieva, J. F., Barros, Eduardo B., Saito, R., Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Department of Physics, Dresselhaus, Mildred, Rodriguez-Nieva, J. F., Barros, Eduardo B., and Saito, R.

Abstract

An analytical study is presented of the double resonant Raman scattering process in graphene, responsible for the D and D′ features in the Raman spectra. This work yields analytical expressions for the D and D′ integrated Raman intensities that explicitly show the dependencies on laser energy, defect concentration, and electronic lifetime. Good agreement is obtained between the analytical results and experimental measurements on samples with increasing defect concentrations and at various laser excitation energies. The use of Raman spectroscopy to identify the nature of defects is discussed. Comparison between the models for the edge-induced and the disorder-induced D-band intensity suggests that edges or grain boundaries can be distinguished from disorder by the different dependence of their Raman intensity on laser excitation energy. Similarly, the type of disorder can potentially be identified not only by the intensity ratio [ [I subscript D] over [I subscript D′]], but also by its laser energy dependence. Also discussed is a quantitative analysis of quantum interference effects of the graphene wave functions, which determine the most important phonon wave vectors and scattering processes responsible for the D and D′ bands., National Science Foundation (U.S.) (Grant DMR1004147), Conselho Nacional de Pesquisas (Brazil) (Grant 245640/2012-6), Fundação Cearense de Apoio ao Desenvolvimento Científico e Tecnológico

Published

2014

6. Disorder-induced double resonant Raman process in graphene

Author

Rodriguez-Nieva, J. F., primary, Barros, E. B., additional, Saito, R., additional, and Dresselhaus, M. S., additional

Published

2014

7. Sputtering from a porous material by penetrating ions

Author

Materials Science and Engineering (MSE), Rodriguez-Nieva, J. F., Bringa, Eduardo M., Cassidy, T. A., Johnson, R. E., Caro, Alfredo, Fama, M., Loeffler, M. J., Baragiola, R. A., Farkas, Diana, Materials Science and Engineering (MSE), Rodriguez-Nieva, J. F., Bringa, Eduardo M., Cassidy, T. A., Johnson, R. E., Caro, Alfredo, Fama, M., Loeffler, M. J., Baragiola, R. A., and Farkas, Diana

Abstract

Porous materials are ubiquitous in the universe and weathering of porous surfaces plays an important role in the evolution of planetary and interstellar materials. Sputtering of porous solids in particular can influence atmosphere formation, surface reflectivity, and the production of the ambient gas around materials in space. Several previous studies and models have shown a large reduction in the sputtering of a porous solid compared to the sputtering of the non-porous solid. Using molecular dynamics simulations we study the sputtering of a nanoporous solid with 55% of the solid density. We calculate the electronic sputtering induced by a fast, penetrating ion, using a thermal spike representation of the deposited energy. We find that sputtering for this porous solid is, surprisingly, the same as that for a full-density solid, even though the sticking coefficient is high.

Published

2011

8. Effect of13C isotope doping on the optical phonon modes in graphene: Localization and Raman spectroscopy

Author

Rodriguez-Nieva, J. F., primary, Saito, R., additional, Costa, S. D., additional, and Dresselhaus, M. S., additional

Published

2012

9. SPUTTERING FROM A POROUS MATERIAL BY PENETRATING IONS

Author

Rodriguez-Nieva, J. F., primary, Bringa, E. M., additional, Cassidy, T. A., additional, Johnson, R. E., additional, Caro, A., additional, Fama, M., additional, Loeffler, M. J., additional, Baragiola, R. A., additional, and Farkas, D., additional

Published

2011

10. Effect of 13C isotope doping on the optical phonon modes in graphene: Localization and Raman spectroscopy.

Author

Rodriguez-Nieva, J. F., Saito, R., Costa, S. D., and Dresselhaus, M. S.

Subjects

*RAMAN spectroscopy, *SPECTRUM analysis, *NUMERICAL analysis, *EQUATIONS, *PERTURBATION theory

Abstract

The effect of 13C isotope impurities on the phonon properties of graphene is discussed theoretically. We calculated the values of the phonon lifetimes due to isotope impurity scattering for all values of densities, isotopic masses, and for all wave vectors using second-order perturbation theory. We found that for natural concentrations of I3C, the contribution of isotopic scattering to the phonon lifetime of the optical modes is negligible when compared to the electron-phonon interaction. Nevertheless, for atomic concentrations of 13C as high as ≈ = 0.5 both contributions become comparable. Our results are compared with recent experimental results and we find good agreement both in the 13C atomic density dependence of the lifetime as well as in the calculated spectral width of the G-band. Due to phonon scattering by 13C isotopes, some graphene phonon wave functions become localized in real space. Numerical calculations show that phonon localized states exist in the high-energy optical phonon modes and in regions of flat phonon dispersion. In particular, for the case of in-plane optical phonon modes, a typical localization length is on the order of 3 nm for ,3C atomic concentrations of &rgr; ≈ 0.5. Optical excitation of phonon modes may provide a way to experimentally observe localization effects for phonons in graphene. [ABSTRACT FROM AUTHOR]

Published

2012