Your search keyword '"Aizpurua, J."' showing total 6 results

1. Quantum mechanical effects in plasmonic structures with subnanometre gaps

Author

Zhu, W, Esteban, R, Borisov, AG, Baumberg, JJ, Nordlander, P, Lezec, HJ, Aizpurua, J, Crozier, KB, Zhu, W, Esteban, R, Borisov, AG, Baumberg, JJ, Nordlander, P, Lezec, HJ, Aizpurua, J, and Crozier, KB

Abstract

Metallic structures with nanogap features have proven highly effective as building blocks for plasmonic systems, as they can provide a wide tuning range of operating frequencies and large near-field enhancements. Recent work has shown that quantum mechanical effects such as electron tunnelling and nonlocal screening become important as the gap distances approach the subnanometre length-scale. Such quantum effects challenge the classical picture of nanogap plasmons and have stimulated a number of theoretical and experimental studies. This review outlines the findings of many groups into quantum mechanical effects in nanogap plasmons, and discusses outstanding challenges and future directions.

Published

2016

2. Chemical mapping of a single molecule by plasmon-enhanced Raman scattering

Author

Zhang, R., Zhang, Y., Dong, Z. C., Jiang, S., Zhang, C., Chen, L. G., Zhang, L., Liao, Y., Aizpurua, J., Luo, Yi, Yang, J. L., Hou, J. G., Zhang, R., Zhang, Y., Dong, Z. C., Jiang, S., Zhang, C., Chen, L. G., Zhang, L., Liao, Y., Aizpurua, J., Luo, Yi, Yang, J. L., and Hou, J. G.

Abstract

Visualizing individual molecules with chemical recognition is a longstanding target in catalysis, molecular nanotechnology and biotechnology. Molecular vibrations provide a valuable 'finger-print' for such identification. Vibrational spectroscopy based on tip-enhanced Raman scattering allows us to access the spectral signals of molecular species very efficiently via the strong localized plasmonic fields produced at the tip apex(1-11). However, the best spatial resolution of the tip-enhanced Raman scattering imaging is still limited to 3-15 nanometres(5,12-16), which is not adequate for resolving a single molecule chemically. Here we demonstrate Raman spectral imaging with spatial resolution below one nanometre, resolving the inner structure and surface configuration of a single molecule. This is achieved by spectrally matching the resonance of the nanocavity plasmon to the molecular vibronic transitions, particularly the downward transition responsible for the emission of Raman photons. This matching is made possible by the extremely precise tuning capability provided by scanning tunnelling microscopy. Experimental evidence suggests that the highly confined and broadband nature of the nanocavity plasmon field in the tunnelling gap is essential for ultrahigh-resolution imaging through the generation of an efficient double-resonance enhancement for both Raman excitation and Raman emission. Our technique not only allows for chemical imaging at the single-molecule level, but also offers a new way to study the optical processes and photochemistry of a single molecule., QC 20130710

Published

2013

3. Detection of deep-subwavelength dielectric layers at Terahertz frequencies using semiconductor plasmonic rsonators

Author

Berrier, A., Albella, P., Ameen Poyli, R., Ulbricht, R., Bonn, M., Aizpurua, J., Gomez Rivas, J., Berrier, A., Albella, P., Ameen Poyli, R., Ulbricht, R., Bonn, M., Aizpurua, J., and Gomez Rivas, J.

Abstract

Plasmonic bowtie antennas made of doped silicon can operate as plasmonic resonators at terahertz (THz) frequencies and provide large field enhancement close to their gap. We demonstrate both experimentally and theoretically that the field confinement close to the surface of the antenna enables the detection of ultrathin (100 nm) inorganic films, about 3750 times thinner than the free space wavelength. Based on model calculations, we conclude that the detection sensitivity and its variation with the thickness of the deposited layer are related to both the decay of the local THz field profile around the antenna and the local field enhancement in the gap of the bowtie antenna. This large field enhancement has the potential to improve the detection limits of plasmon-based biological and chemical sensors.

Published

2012

4. Detection of deep-subwavelength dielectric layers at Terahertz frequencies using semiconductor plasmonic rsonators

Author

Berrier, A., Albella, P., Ameen Poyli, R., Ulbricht, R., Bonn, M., Aizpurua, J., Gomez Rivas, J., Berrier, A., Albella, P., Ameen Poyli, R., Ulbricht, R., Bonn, M., Aizpurua, J., and Gomez Rivas, J.

Abstract

Plasmonic bowtie antennas made of doped silicon can operate as plasmonic resonators at terahertz (THz) frequencies and provide large field enhancement close to their gap. We demonstrate both experimentally and theoretically that the field confinement close to the surface of the antenna enables the detection of ultrathin (100 nm) inorganic films, about 3750 times thinner than the free space wavelength. Based on model calculations, we conclude that the detection sensitivity and its variation with the thickness of the deposited layer are related to both the decay of the local THz field profile around the antenna and the local field enhancement in the gap of the bowtie antenna. This large field enhancement has the potential to improve the detection limits of plasmon-based biological and chemical sensors.

Published

2012

5. Strong magnetic response of submicron Silicon particles in the infrared

Author

García-Etxarri, A., Gómez-Medina, R., Froufe-Pérez, Luis S., López, C., Chantada, Laura, Scheffold, Frank, Aizpurua, J., Nieto-Vesperinas, M., Sáenz, Juan José, García-Etxarri, A., Gómez-Medina, R., Froufe-Pérez, Luis S., López, C., Chantada, Laura, Scheffold, Frank, Aizpurua, J., Nieto-Vesperinas, M., and Sáenz, Juan José

Abstract

High-permittivity dielectric particles with resonant magnetic properties are being explored as constitutive elements of new metamaterials and devices. Magnetic properties of low-loss dielectric nanoparticles in the visible or infrared are not expected due to intrinsic low refractive index of optical media in these regimes. Here we analyze the dipolar electric and magnetic response of lossless dielectric spheres made of moderate permittivity materials. For low material refractive index (. 3) there are no sharp resonances due to strong overlapping between different multipole contributions. However, we find that Silicon particles with index of refraction ∼ 3.5 and radius ∼ 200nm present strong electric and magnetic dipolar resonances in telecom and near-infrared frequencies, (i.e. at wavelengths ≈ 1.2−2mm) without spectral overlap with quadrupolar and higher order resonances. The light scattered by these Si particles can then be perfectly described by dipolar electric and magnetic fields.

Published

2011

6. Strong magnetic response of submicron Silicon particles in the infrared

Author

García-Etxarri, A., Gómez-Medina, R., Froufe-Pérez, Luis S., López, C., Chantada, Laura, Scheffold, Frank, Aizpurua, J., Nieto-Vesperinas, M., Sáenz, Juan José, García-Etxarri, A., Gómez-Medina, R., Froufe-Pérez, Luis S., López, C., Chantada, Laura, Scheffold, Frank, Aizpurua, J., Nieto-Vesperinas, M., and Sáenz, Juan José

Abstract

High-permittivity dielectric particles with resonant magnetic properties are being explored as constitutive elements of new metamaterials and devices. Magnetic properties of low-loss dielectric nanoparticles in the visible or infrared are not expected due to intrinsic low refractive index of optical media in these regimes. Here we analyze the dipolar electric and magnetic response of lossless dielectric spheres made of moderate permittivity materials. For low material refractive index (. 3) there are no sharp resonances due to strong overlapping between different multipole contributions. However, we find that Silicon particles with index of refraction ∼ 3.5 and radius ∼ 200nm present strong electric and magnetic dipolar resonances in telecom and near-infrared frequencies, (i.e. at wavelengths ≈ 1.2−2mm) without spectral overlap with quadrupolar and higher order resonances. The light scattered by these Si particles can then be perfectly described by dipolar electric and magnetic fields.