Anisotropic Rheology and Friction of Suspended Graphene

Graphene is a powerful membrane prototype for both applications and fundamental research. Rheological phenomena including indentation, twisting, and wrinkling in deposited and suspended graphene are actively investigated to unravel the mechanical laws at the nanoscale. Most studies focused on isotropic set-ups, while realistic graphene membranes are often subject to strongly anisotropic constraints, with important consequences for the rheology, strain, indentation, and friction in engineering conditions

Morphology and Optical Properties of Gas-Phase-Synthesized Plasmonic Nanoparticles: Cu and Cu/MgO

In this paper, an investigation of the properties of Cu and Cu/MgO nanoparticles (NPs) is presented. The NPs were obtained with gas-phase synthesis, and the MgO shells or matrices were formed via the co-deposition method on inert substrates. SEM and AFM were used to investigate the NP morphology on Si/SiOx, quartz, and HOPG. The Cu NPs revealed flattening of their shape, and when they were deposited on HOPG, diffusion and formation of small chains were observed. The embedding of Cu NPs in MgO was confirmed by TEM and EDX maps. XPS showed that Cu was in its metallic state, regardless of the presence of the surrounding MgO. UV–Vis revealed the presence of an intense localized surface plasmon resonance (LSPR) for Cu/MgO and for “bare” NPs. These results confirmed the role of MgO as a protective transparent medium for Cu, and the wavelength position of the LSPR in the Cu/MgO system was consistent with calculations. The wavelength position of the LSPR observed for “bare” and post-oxidized Cu NPs was probably affected by the formation of copper oxide shells after exposure to air. This study paves the way for the use of Cu/MgO NPs as plasmonic nanomaterials in applications such as photovoltaics and sensor technology

Comprehensive study of SrF2 growth on highly oriented pyrolytic graphite (HOPG): Temperature-dependent van der Waals epitaxy

This study explores the molecular beam epitaxy (MBE) growth of SrF2 on highly oriented pyrolytic graphite (HOPG) highlighting the temperature-dependent variations in growth morphology, crystalline structure and electronic properties. The comprehensive characterization of SrF2/HOPG interfaces was carried out using atomic force microscopy (AFM), reflection high-energy electron diffraction (RHEED), ultraviolet photoelectron spectroscopy (UPS) and X-ray photoelectron spectroscopy (XPS). The spectroscopy data suggest that the chemical interaction of the fluoride with the substrate is weak at each deposited thickness and temperature of the substrate during the deposition, indicating a growth under a van der Waals epitaxial regime. SrF2 nanostructures deposited on HOPG depict a distinctive bulk-like character, concerning their crystallinity and composition, even at the very initial growth stage. Remarkably, temperature plays a crucial role in driving the growth patterns, moving from coalescence of dendritic islands at room temperature to induce nearly 1D rows along the step-edges of HOPG terraces at higher temperatures (400 °C)

Influence of size, shape and core\u2013shell interface on surface plasmon resonance in Ag and Ag@MgO nanoparticle films deposited on Si/SiOx

Ag and Ag@MgO core-shell nanoparticles (NPs) with a diameter of d = 3-10 nm were obtained by physical synthesis methods and deposited on Si with its native ultrathin oxide layer SiOx (Si/SiOx). Scanning electron microscopy and transmission electron microscopy (TEM) images of bare Ag NPs revealed the presence of small NP aggregates caused by diffusion on the surface and agglomeration. Atomic resolution TEM gave evidence of the presence of crystalline multidomains in the NPs, which were due to aggregation and multitwinning occurring during NP growth in the nanocluster source. Co-deposition of Ag NPs and Mg atoms in an oxygen atmosphere gave rise to formation of a MgO shell matrix surrounding the Ag NPs. The behaviour of the surface plasmon resonance (SPR) excitation in surface differential reflectivity (SDR) spectra with p-polarised light was investigated for bare Ag and Ag@MgO NPs. It was shown that the presence of MgO around the Ag NPs caused a red shift of the plasmon excitation, and served preserve its existence after prolonged (five months) exposure to air, realizing the possibility of technological applications in plasmonic devices. The Ag NP and Ag@MgO NP film features in the SDR spectra could be reproduced by classical electrodynamics simulations by treating the NP-containing layer as an effective Maxwell Garnett medium. The simulations gave results in agreement with the experiments when accounting for the experimentally observed aggregation

Synergistic effect of graphene and nanodiamonds to achieve ultra-low friction on rough DLC coatings

Diamond-like carbon (DLC) with its protective, antiwear and self-lubricant properties represents an outstanding coating material to improve the tribological performance of bare metal-to-metal contacts. The DLC friction response is strictly related to the generation of a carbon-rich transfer layer on the sliding countersurfaces. This key process may benefit from the DLC surface functionalization with carbon nanomaterials, as attested by the recent observation of wearless sliding and ultra-low friction for nanorough model interfaces. In this study, we show by ball-on-disc tribometer that the tribological response of microrough steel-DLC contacts is considerably improved in dry atmosphere through DLC functionalization with graphene sheets (GSs) and nanodiamonds (NDs). The functionalization effectiveness is demonstrated exclusively with both allotropic forms, that synergically lower friction after a unique run-in period. We attribute the enhanced lubricity, with steady coefficient of friction <0.05 at 1 N load, to the formation of a transfer layer which incorporates GSs, NDs and nanoscroll structures self-assembled during sliding. High-resolution electron microscopy and Raman spectroscopy indicate that NDs, besides enabling the erosion of the highest interfacial micro-asperities, do assist the transfer layer development via GSs milling. Our findings contribute to the current quest for superlubricity in realistic tribocontacts meeting industrial standards

DMTs and Covid-19 severity in MS: a pooled analysis from Italy and France

We evaluated the effect of DMTs on Covid-19 severity in patients with MS, with a pooled-analysis of two large cohorts from Italy and France. The association of baseline characteristics and DMTs with Covid-19 severity was assessed by multivariate ordinal-logistic models and pooled by a fixed-effect meta-analysis. 1066 patients with MS from Italy and 721 from France were included. In the multivariate model, anti-CD20 therapies were significantly associated (OR = 2.05, 95%CI = 1.39–3.02, p < 0.001) with Covid-19 severity, whereas interferon indicated a decreased risk (OR = 0.42, 95%CI = 0.18–0.99, p = 0.047). This pooled-analysis confirms an increased risk of severe Covid-19 in patients on anti-CD20 therapies and supports the protective role of interferon

Controlled AFM detachments and movement of nanoparticles: gold clusters on HOPG at different temperatures

The effect of temperature on the onset of movement of gold nanoclusters (diameter 27 nm)deposited on highly oriented pyrolytic graphite (HOPG) has been studied by atomic forcemicroscopy (AFM) techniques. Using the AFM with amplitude modulation (tapping modeAFM) we have stimulated and controlled the movement of individual clusters. We show how,at room temperature, controlled detachments and smooth movements can be obtained forclusters having dimensions comparable to or smaller than the tip radius. Displacement ispractically visible in real time and it can be started and stopped easily by adjusting only oneparameter, the tip amplitude oscillation. Analysing the energy dissipation signal at the onset ofnanocluster sliding we evaluated a detachment threshold energy as a function of temperaturein the range 300–413 K. We also analysed single cluster thermal induced displacement andcombining this delicate procedure with AFM forced movement behaviour we conclude thatdetachment threshold energy is directly related to the activation energy of nanoclusterdiffusion and it scales linearly with temperature as expected for a single-particle thermallyactivated process

Influence of size, shape and core–shell interface on surface plasmon resonance in Ag and Ag@MgO nanoparticle films deposited on Si/SiOx

Ag and Ag@MgO core-shell nanoparticles (NPs) with a diameter of d = 3-10 nm were obtained by physical synthesis methods and deposited on Si with its native ultrathin oxide layer SiOx (Si/SiOx). Scanning electron microscopy and transmission electron microscopy (TEM) images of bare Ag NPs revealed the presence of small NP aggregates caused by diffusion on the surface and agglomeration. Atomic resolution TEM gave evidence of the presence of crystalline multidomains in the NPs, which were due to aggregation and multitwinning occurring during NP growth in the nanocluster source. Co-deposition of Ag NPs and Mg atoms in an oxygen atmosphere gave rise to formation of a MgO shell matrix surrounding the Ag NPs. The behaviour of the surface plasmon resonance (SPR) excitation in surface differential reflectivity (SDR) spectra with p-polarised light was investigated for bare Ag and Ag@MgO NPs. It was shown that the presence of MgO around the Ag NPs caused a red shift of the plasmon excitation, and served preserve its existence after prolonged (five months) exposure to air, realizing the possibility of technological applications in plasmonic devices. The Ag NP and Ag@MgO NP film features in the SDR spectra could be reproduced by classical electrodynamics simulations by treating the NP-containing layer as an effective Maxwell Garnett medium. The simulations gave results in agreement with the experiments when accounting for the experimentally observed aggregation

Tribological characteristics of few-layer graphene over Ni grain and interface boundaries

The tribological properties of metal supported few layered graphene (FLG) depend strongly on the grain topology of the metal substrate. Inhomogeneous distribution of graphene layers at such regions led to variable landscapes with distinguishable roughness. This discrepancy in morphology significantly affects the wetting and frictional characteristics of the FLG system. We individually measured friction characteristics of FLG covering grains and grain boundaries of polycrystalline Ni metal substrate via an Atomic Force Microscopy (AFM) probe. The friction coefficient of FLG covered at grain boundaries is found to be lower than that on grains in vacuum (at 10-5 Torr pressure) and similar results were obtained in air condition. Sliding history with AFM cantilever, static and dynamic pull-in and pull-off forces were addressed in the course of friction measurements to explain the role of the out-of-plane deformation of graphene layer/s. Finite element simulations show good agreement with experiments and led to rationalize the observations. Thus, with grain boundaries the FLG tribology can be effectively tuned