69 research outputs found
Photoinduced transient symmetry breaking in plasmonic structures for ultrafast nanophotonics
We study the spatio-temporal evolution of hot electrons generated in plasmonic nanostructures under resonant excitation with fs-laser pulses. A spatially inhomogeneous version of the Three-Temperature Model for hot-electrons dynamics, coupled to semiclassical calculations of third-order optical nonlinearity in gold, enabled us to engineer a transient symmetry breaking of the optical properties at the nanoscale. This effect is exploited to achieve all-optical control of light with unprecedented speed. For instance, a photoinduced broadband dichroism, fully reversible and transiently vanishing in less than 1 picoseconds (overcoming the speed bottleneck caused by slower, electron-phonon and phonon-phonon relaxation processes), has been experimentally demonstrated in plasmonic metasurfaces with nanocross metaatoms. Also, we designed a nonlinear plasmonic metagrating (based on cross-polarized gold nanostrip dimer metaatoms), where the nanoscale symmetry breaking enables ultrafast reconfiguration of diffraction orders via control laser pulses. The photoinduced power imbalance between symmetrical diffraction orders is calculated to exceed 20% under moderate (similar to 2 mJ/cm(2)) laser fluence, and returns to the balanced diffraction in about 2 ps. Our design has been developed for gold nanomaterials, but the concept of ultrafast all-optical symmetry breaking can be exploited beyond plasmonics (e.g. in semiconductor nanostructures), with potential impact on a broad range of applications in nanophotonics
Challenges and prospects of plasmonic metasurfaces for photothermal catalysis
Solar-thermal technologies for converting chemicals using thermochemistry require extreme light concentration. Exploiting plasmonic nanostructures can dramatically increase the reaction rates by providing more efficient solar-to-heat conversion by broadband light absorption. Moreover, hot-carrier and local field enhancement effects can alter the reaction pathways. Such discoveries have boosted the field of photothermal catalysis, which aims at driving industrially-relevant chemical reactions using solar illumination rather than conventional heat sources. Nevertheless, only large arrays of plasmonic nano-units on a substrate, i.e., plasmonic metasurfaces, allow a quasi-unitary and broadband solar light absorption within a limited thickness (hundreds of nanometers) for practical applications. Through moderate light concentration (∼10 Suns), metasurfaces reach the same temperatures as conventional thermochemical reactors, or plasmonic nanoparticle bed reactors reach under ∼100 Suns. Plasmonic metasurfaces, however, have been mostly neglected so far for applications in the field of photothermal catalysis. In this Perspective, we discuss the potentialities of plasmonic metasurfaces in this emerging area of research. We present numerical simulations and experimental case studies illustrating how broadband absorption can be achieved within a limited thickness of these nanostructured materials. The approach highlights the synergy among different enhancement effects related to the ordered array of plasmonic units and the efficient heat transfer promoting faster dynamics than thicker structures (such as powdered catalysts). We foresee that plasmonic metasurfaces can play an important role in developing modular-like structures for the conversion of chemical feedstock into fuels without requiring extreme light concentrations. Customized metasurface-based systems could lead to small-scale and low-cost decentralized reactors instead of large-scale, infrastructure-intensive power plants
Thermoplasmonic Effect of Surface-Enhanced Infrared Absorption in Vertical Nanoantenna Arrays
Thermoplasmonics is a method for increasing temperature remotely using focused visible or infrared laser beams interacting with plasmonic nanopartides. Here, local heating induced by mid-infrared quantum cascade laser illumination of vertical gold-coated nanoanterma arrays embedded into polymer layers is investigated by infrared nanospectroscopy and electromagnetic/thermal simulations. Nanoscale thermal hotspot images are obtained by a phototherrnal scanning probe microscopy technique with laser illumination wavelength tuned at the different plasmonic resonances of the arrays. Spectral analysis indicates that both Joule heating by the metal antennas and surface-enhanced-infrared absorption (SEIRA) by the polymer molecules located in the apical hotspots of the antennas are responsible for thermoplasmonic resonances, that is, for strong local temperature increase. At odds with more conventional planar nanoantennas, the vertical antenna structure enables thermal decoupling of the hotspot at the antenna apex from the heat sink constituted by the solid substrate. The temperature increase was evaluated by quantitative comparision of data obtained with the photothermal expansion technique to the results of electromagnetic/thermal simulations. In the case of strong SEIRA by the C=O bond of poly-methylmethacrylate at 1730 cm(-1), for focused mid-infrared laser power of about 20 mW, the evaluated order of magnitude of the nanoscale temperature increase is of 10 K. This result indicates that temperature increases of order of hundreds of K may he attainable with full mid-infrared laser power tuned at specific molecule vibrational fingerprints
Chiral Plasmonic Pinwheels Exhibit Orientation-Independent Linear Differential Scattering under Asymmetric Illumination
Plasmonic nanoantennas have considerably stronger polar-
ization-dependent optical properties than their molecular counterparts,
inspiring photonic platforms for enhancing molecular dichroism and providing
fundamental insight into light-matter interactions. One such insight is that
even achiral nanoparticles can yield strong optical activity when they are
asymmetrically illuminated from a single oblique angle instead of evenly
illuminated. This effect, called extrinsic chirality, results from the overall
chirality of the experimental geometry and strongly depends on the orientation
of the incident light. Although extrinsic chirality has been well-characterized,
an analogous effect involving linear polarization sensitivity has not yet been
discussed. In this study, we investigate the differential scattering of rotationally
symmetric chiral plasmonic pinwheels when asymmetrically irradiated with
linearly polarized light. Despite their high rotational symmetry, we observe
substantial linear differential scattering that is maintained over all pinwheel
orientations. We demonstrate that this orientation-independent linear differential scattering arises from the broken mirror and rotational symmetries of our overall experimental geometry. Our results underscore the necessity of considering both the rotational symmetry of the nanoantenna and the experimental setup, including illumination direction and angle, when performing plasmon- enhanced chiroptical characterizations. Our results demonstrate spectroscopic signatures of an effect analogous to extrinsic chirality for linear polarizations
High-Frequency Light Rectification by Nanoscale Plasmonic Conical Antenna in Point-Contact-Insulator-Metal Architecture
Numerous efforts have been undertaken to develop rectifying antennas operating at high frequencies, especially dedicated to light harvesting and photodetection applications. However, the development of efficient high frequency rectifying antennas has been a major technological challenge both due to a lack of comprehension of the underlying physics and limitations in the fabrication techniques. Various rectification strategies have been implemented, including metal-insulator-metal traveling-wave diodes, plasmonic nanogap optical antennas, and whisker diodes, although all show limited high-frequency operation and modest conversion efficiencies. Here a new type of rectifying antenna based on plasmonic carrier generation is demonstrated. The proposed structure consists of a resonant metallic conical nano-antenna tip in contact with the oxide surface of an oxide/metal bilayer. The conical shape allows for an improved current generation based on plasmon-mediated electromagnetic-to-electron conversion, an effect exploiting the nanoscale-tip contact of the rectifying antenna, and proportional to the antenna resonance and to the surface-electron scattering. Importantly, this solution provides rectification operation at 280 THz (1064 nm) with a 100-fold increase in efficiency compared to previously reported results. Finally, the conical rectifying antenna is also demonstrated to operate at 384 THz (780 nm), hence paving a way toward efficient rectennas toward the visible range
Synthesis of plasmonic gold nanoparticles on soft materials for biomedical applications
Plasmonic metal nanomaterials are usually supported by rigid substrates, typically made of silicon or glass. Recently, there has been growing interest in developing soft plasmonic devices. Such devices are low weight, low cost, exhibit elevated flexibility and improved mechanical properties. Moreover, they maintain the features of conventional nano-optic structures, such as the ability to enhance the local electromagnetic field. On account of these characteristics, they show promise as efficient biosensors in biological, medical, and bio-engineering applications. Here, we demonstrate the fabrication of soft polydimethylsiloxane (PDMS) plasmonic devices. Using a combination of techniques, including electroless deposition, we patterned thin membranes of PDMS with arrays of gold nanoparticle clusters. Resulting devices show regular patterns of gold nanoparticles extending over several hundreds of microns and are moderately hydrophilic, with a contact angle of about 80°. At the nanoscale, scanning electron and atomic force microscopy of samples reveal an average particle size of ∼50 nm. The nanoscopic size of the particles, along with their random distribution in a cluster, promotes the enhancement of electromagnetic fields, evidenced by numerical simulations and experiments. Mechanical characterization and the stress-strain relationship indicate that the device has a stiffness of 2.8 MPa. In biological immunoassay tests, the device correctly identified and detected anti-human immunoglobulins G (IgG) in solution with a concentration of 25 μg/ml
Nanoporous Metals: From Plasmonic Properties to Applications in Enhanced Spectroscopy and Photocatalysis
The field of plasmonics is capable of enabling interesting applications in
the different wavelength ranges, spanning from the ultraviolet up to the
infrared. The choice of plasmonic material and how the material is
nanostructured have significant implications for ultimate performance of any
plasmonic device. Artificially designed nanoporous metals have interesting
material properties including large specific surface area, distinctive optical
properties, high electrical conductivity, and reduced stiffness, implying their
potentials for many applications. This manuscript reviews the wide range of
available nanoporous metals, mainly focusing on their properties as plasmonic
materials. While extensive reports on the use and characterization of NPMs
exist, a detailed discussion on their connection with surface plasmons and
enhanced spectroscopies as well as photocatalysis is missing. Here, we report
on different metals investigated, from the most used nanoporous gold to mixed
metal compounds, and discuss each of these plasmonic materials suitability for
a range of structural design and applications. Finally, we discuss the
potentials and limitations of the traditional and alternative plasmonic
materials for applications in enhanced spectroscopy and photocatalysis
Nanoporous Metals: From Plasmonic Properties to Applications in Enhanced Spectroscopy and Photocatalysis
The field of plasmonics is capable of enabling interesting applications in different wavelength ranges, spanning from the ultraviolet up to the infrared. The choice of plasmonic material and how the material is nanostructured has significant implications for ultimate performance of any plasmonic device. Artificially designed nanoporous metals (NPMs) have interesting material properties including large specific surface area, distinctive optical properties, high electrical conductivity, and reduced stiffness, implying their potentials for many applications. This paper reviews the wide range of available nanoporous metals (such as Au, Ag, Cu, Al, Mg, and Pt), mainly focusing on their properties as plasmonic materials. While extensive reports on the use and characterization of NPMs exist, a detailed discussion on their connection with surface plasmons and enhanced spectroscopies as well as photocatalysis is missing. Here, we report on different metals investigated, from the most used nanoporous gold to mixed metal compounds, and discuss each of these plasmonic materials' suitability for a range of structural design and applications. Finally, we discuss the potentials and limitations of the traditional and alternative plasmonic materials for applications in enhanced spectroscopy and photocatalysis
- …