Photothermally controlled structural switching in fluorinated polyene-graphene hybrids.

Fluorination of graphene enables tuning of its electronic properties, provided that control of the fluorination degree and of modification of graphene structure can be achieved. In this work we demonstrate that SF6 modulated plasma fluorination of monolayer graphene yields polyene-graphene hybrids. The extent of fluorination is determined by the plasma exposure time and controlled in real time by monitoring the change in the optical response by spectroscopic ellipsometry. Raman spectroscopy reveals the formation of polyenes in partially fluorinated graphene (F/C < 0.25), which are responsible for changes in conductivity and for opening a transport gap of ∼25 meV. We demonstrate that the cis- and trans-isomers of the polyenes in graphene are tunable using the photothermal switching. Specifically, the room temperature fluorination results in the cis-isomer that can be converted to the trans-isomer by annealing at T > 150 °C, whereas photoirradiation activates the trans-to-cis isomerization. The two isomers give to the polyene-graphene hybrids different optical and conductivity properties providing a way to engineer electrical response of graphene.

Optical properties of silicon semiconductor-supported gold nanoparticles obtained by sputtering.

Gold nanoclusters are deposited directly on silicon by sputtering of a target of metallic gold using an argon plasma to provide a semiconductor-based plasmonic platform. The effects of annealing and substrate temperatures during the nanoparticles deposition and of the silicon surface energy on the shape of the nanoparticles and resulting surface plasmon resonance are investigated. The Au nanoparticles are characterized optically, structurally and morphologically using spectroscopic ellipsometry, transmission electron microscopy and atomic force microscopy to establish a correlation among the Au/Si interface reactivity, the Au nanoparticles shape and plasmonic resonance properties. It is found that post-growth annealing up to 600 degrees C of nanoparticles deposited at 60 degrees C causes aggregation of nanoparticles. Increasing the temperature of the substrate during the sputtering of gold on Si yields pancake-like nanoparticles with a large Si/Au interface reactivity forming a gold-silicides interface layer. The O2 plasma treatment of the Si surface forming a thin intentional SiO2 interface layer prevents the Au/Si interdiffusion yielding polyedrical nanoparticles whose plasmon resonance can be shifted down to 1.5 eV.

Interplay between Thickness, Defects, Optical Properties, and Photoconductivity at the Centimeter Scale in Layered GaS.

From the group-III monochalcogenide (MX, M = Ga, In; X = S, Se, Te) layered semiconductors, gallium monosulfide, GaS, has emerged as a promising material for electronics, optoelectronics, and catalysis applications. In this work, GaS samples of various thicknesses in the range from 38 to 1665 nm have been obtained by mechanical exfoliation to study the interplay between structural, morphological, optical, and photoresponsivity properties as a function of thickness. This interplay has been established by analyzing the structure through Raman spectroscopy and X-ray diffraction, the morphology through scanning electron microscopy and atomic force microscopy, the density and optical properties through spectroscopic ellipsometry, and the photoresponsivity through current-voltage measurements under UV light. This work shows that photoresponsivity increases with increases in GaS thickness, resulting in a UV photoresponsivity of 1.5·10-4 AW-1 stable over several on/off cycles.

Tailoring density and optical and thermal behavior of gold surfaces and nanoparticles exploiting aromatic dithiols.

Self-assembled monolayers (SAMs) derived of 4-methoxy-terphenyl-3'',5''-dimethanethiol (TPDMT) and 4-methoxyterphenyl-4''-methanethiol (TPMT) have been prepared by chemisorption from solution onto gold thin films and nanoparticles. The SAMs have been characterized by spectroscopic ellipsometry, Raman spectroscopy and atomic force microscopy to determine their optical properties, namely the refractive index and extinction coefficient, in an extended spectral range of 0.75-6.5 eV. From the analysis of the optical data, information on SAMs structural organization has been inferred. Comparison of SAMs generated from the above aromatic thiols to well-known SAMs generated from the alkanethiol dodecanethiol revealed that the former aromatic SAMs are densely packed and highly vertically oriented, with a slightly higher packing density and a absence of molecular inclination in TPMT/Au. The thermal behavior of SAMs has also been monitored using ellipsometry in the temperature range 25-500 degrees C. Gold nanoparticles functionalized by the same aromatic thiols have also been discussed for surface enhanced Raman spectroscopy applications. This study represents a step forward tailoring the optical and thermal behavior of surfaces as well as nanoparticles.

Demonstration of surface-enhanced Raman scattering by tunable, plasmonic gallium nanoparticles.

Size-controlled gallium nanoparticles deposited on sapphire were explored as alternative substrates to enhance Raman spectral signatures. Gallium's resilience following oxidation is inherently advantageous in comparison with silver for practical ex vacuo nonsolution applications. Ga nanoparticles were grown using a simple molecular beam epitaxy-based fabrication protocol, and monitoring their corresponding surface plasmon resonance energy through in situ spectroscopic ellipsometry allowed the nanoparticles to be easily controlled for size. The Raman spectra obtained from cresyl fast violet (CFV) deposited on substrates with differing mean nanoparticle sizes represent the first demonstration of enhanced Raman signals from reproducibly tunable self-assembled Ga nanoparticles. Nonoptimized aggregate enhancement factors of approximately 80 were observed from the substrate with the smallest Ga nanoparticles for CFV dye solutions down to a dilution of 10 ppm.

Au nanoparticle in situ decorated RGO nanocomposites for highly sensitive electrochemical genosensors.

A novel hybrid nanocomposite formed by RGO flakes, surface functionalized by 1-pyrene carboxylic acid (PCA), densely and uniformly in situ decorated by Au NPs, that are concomitantly coordinated by the PCA carboxylic group, and by an aromatic thiol used as the reducing agent in the synthesis, both ensuring, at the same time, a stable non-covalent NPs anchorage to the RGO flakes, and an efficient interparticle electron coupling along the NP network onto the RGO, is reported. The obtained solution processable hybrid material is used to modify Screen-Printed Carbon Electrodes (SPCEs). The hybrid modified SPCEs, functionalized with a thiolated DNA capture probe, are tested in a streptavidin-alkaline-phosphatase catalyzed assay, for the detection of the biotinylated miRNA-221, and for its determination in spiked human blood serum samples. The proposed genosensor demonstrates a high sensitivity (LOD of 0.7 pM), attesting for a performance comparable with the most effective reported sensors. The enhanced sensitivity is explained in terms of the very fast heterogeneous electron transfer kinetics, the concomitant decrease of the electron transfer resistance at the electrode/electrolyte interface, the high electroactivity and the high surface area of the nanostructured hybrid modified SPCEs that provide a convenient platform for nucleic acid biosensing.

Photoactive hybrid material based on pyrene functionalized PbS nanocrystals decorating CVD monolayer graphene.

A simple and facile solution-based procedure is implemented for decorating a large area, monolayer graphene film, grown by chemical vapor deposition, with size-tunable light absorbing colloidal PbS nanocrystals (NCs). The hybrid is obtained by exposing a large area graphene film to a solution of 1-pyrene butyric acid surface coated PbS NCs, obtained by a capping exchange procedure onto presynthesized organic-capped NCs. The results demonstrate that at the interface, multiple and cooperative π-π stacking interactions promoted by the pyrene ligand coordinating the NC surface lead to a successful anchoring of the nano-objects on the graphene platform which concomitantly preserves its aromatic structure. Interligand interactions provide organization of the nano-objects in highly interconnected nanostructured multilayer coatings, where the NCs retain geometry and composition. The resulting hybrid exhibits a sheet resistance lower than that of bare graphene, which is explained in terms of electronic communication in the hybrid, due to the interconnection of the NC film and to a hole transfer from photoexcited PbS NCs to graphene, channelled at the interface by pyrene. Such a direct electron coupling makes the manufactured hybrid material an interesting component for optoelectronics, sensors and for optical communication and information technology.