Low temperature nucleation of thermochromic VO2crystal domains in nanocolumnar porous thin films.

The low temperature formation of monoclinic VO2crystal domains in nanocolumnar vanadium/oxygen thin films prepared by magnetron sputtering at oblique angles is analyzed. The synthesis procedure involved the deposition of amorphous nanocolumnar VO1.9thin films at room temperature and its subsequent annealing at temperatures between 250 °C and 330 °C in an oxygen atmosphere. The thermochromic transition of these films was found at a temperature of 47 °C when the annealing temperature was 270 °C and 58 °C when the annealing temperature was 280 °C and 290 °C, presenting a clear drop of the optical transmittance in the infrared region of the spectrum. The significant downshift in the temperature window to obtain VO2in comparison with compact films and other strategies in literature is explained by the particular morphology of the nanocolumnar structures, which contains numerous defects along with open and embedded porosity.

Self-Lubricity of WSex Nanocomposite Coatings.

Transition metal chalcogenides with lamellar structure are known for their use in tribological applications although limited to vacuum due to their easy degradation in the presence of oxygen and/or moisture. Here we present a tailored WSex coating with low friction (0.07) and low wear rates (3×10(-7) mm3 Nm(-1)) even in ambient air. To understand the low friction behavior and lower chemical reactivity a tribological study is carried out in a high-vacuum tribometer under variable pressure (atmospheric pressure to 1×10(-8) mbar). A detailed investigation of the film nanostructure and composition by advanced transmission electron microscopy techniques with nanoscale resolution determined that the topmost layer is formed by nanocrystals of WSe2 embedded in an amorphous matrix richer in W, a-W(Se). After the friction test, an increased crystalline order and orientation of WSe2 lamellas along the sliding direction were observed in the interfacial region. On the basis of high angle annular dark field, scanning transmission electron microscopy, and energy dispersive X-ray analysis, the release of W atoms from the interstitial basal planes of the a-W(Se) phase is proposed. These W atoms reaching the surface, play a sacrificial role preventing the lubricant WSe2 phase from oxidation. The increase of the WSe2 crystalline order and the buffer effect of W capturing oxygen atoms would explain the enhanced chemical and tribological response of this designed nanocomposite material.

A new bottom-up methodology to produce silicon layers with a closed porosity nanostructure and reduced refractive index.

A new approach is presented to produce amorphous porous silicon coatings (a-pSi) with closed porosity by magnetron sputtering of a silicon target. It is shown how the use of He as the process gas at moderated power (50-150 W RF) promotes the formation of closed nanometric pores during the growth of the silicon films. The use of oblique-angle deposition demonstrates the possibility of aligning and orientating the pores in one direction. The control of the deposition power allows the control of the pore size distribution. The films have been characterized by a variety of techniques, including scanning and transmission electron microscopy, electron energy loss spectroscopy, Rutherford back scattering and x-ray photoelectron spectroscopy, showing the incorporation of He into the films (most probably inside the closed pores) and limited surface oxidation of the silicon coating. The ellipsometry measurements show a significant decrease in the refractive index of porous coatings (n(500 nm) = 3.75) in comparison to dense coatings (n(500 nm) = 4.75). The capability of the method to prepare coatings with a tailored refractive index is therefore demonstrated. The versatility of the methodology is shown in this paper by preparing intrinsic or doped silicon and also depositing (under DC or RF discharge) a-pSi films on a variety of substrates, including flexible materials, with good chemical and mechanical stability. The fabrication of multilayers of silicon films of controlled refractive index in a simple (one-target chamber) deposition methodology is also presented.

Behaviour of Au-citrate nanoparticles in seawater and accumulation in bivalves at environmentally relevant concentrations.

The degree of aggregation and/or coalescence of Au-citrate nanoparticles (AuNPs, mean size 21.5 ± 2.9 nm), after delivery in simulated seawater, are shown to be concentration-dependent. At low concentrations no coalescence and only limited aggregation of primary particles were found. Experiments were performed in which the marine bivalve (Ruditapes philippinarum) was exposed to AuNPs or dissolved Au and subsequently, bivalve tissues were studied by Scanning and Transmission Electron Microscopy and chemical analyses. We show that the bivalve accumulates gold in both cases within either the digestive gland or gill tissues, in different concentrations (including values of predicted environmental relevance). After 28 days of exposure, electron-dense deposits (corresponding to AuNPs, as proven by X-ray microanalysis) were observed in the heterolysosomes of the digestive gland cells. Although non-measurable solubility of AuNPs in seawater was found, evidence is presented of the toxicity produced by Au(3+) dissolved species (chloroauric acid solutions) and its relevance is discussed.

Gold nanoparticles with different capping systems: an electronic and structural XAS analysis.

Gold nanoparticles (NPs) have been prepared with three different capping systems: a tetralkylammonium salt, an alkanethiol, and a thiol-derivatized neoglycoconjugate. Also gold NPs supported on a porous TiO(2) substrate have been investigated. X-ray absorption spectroscopy (XAS) has been used to determine the electronic behavior of the different capped/supported systems regarding the electron/hole density of d states. Surface and size effects, as well as the role of the microstructure, have been also studied through an exhaustive analysis of the EXAFS (extended X-ray absorption fine structure) data. Very small gold NPs functionalized with thiol-derivatized molecules show an increase in d-hole density at the gold site due to Au-S charge transfer. This effect is overcoming size effects (which lead to a slightly increase of the d-electron density) for high S:Au atomic ratios and core-shell microstructures where an atomically abrupt Au-S interface likely does not exist. It has been also shown that thiol functionalization of very small gold NPs is introducing a strong distortion as compared to fcc order. To the contrary, electron transfer from reduced support oxides to gold NPs can produce a higher increase in d-electron density at the gold site, as compared to naked gold clusters.

Permanent magnetism, magnetic anisotropy, and hysteresis of thiol-capped gold nanoparticles.

We report on the experimental observation of magnetic hysteresis up to room temperature in thiol-capped Au nanoparticles with 1.4 nm size. The coercive field ranges from 860 Oe at 5 K to 250 Oe at 300 K. It is estimated that the Au atoms exhibit a magnetic moment of mu=0.036mu(B). However, Au nanoparticles with similar size but stabilized by means of a surfactant, i.e., weak interaction between protective molecules and Au surface atoms, are diamagnetic, as bulk Au samples are. The apparent ferromagnetism is consequently associated with 5d localized holes generated through Au-S bonds. These holes give rise to localized magnetic moments that are frozen in due to the combination of the high spin-orbit coupling (1.5 eV) of gold and the symmetry reduction associated with two types of bonding: Au-Au and Au-S.

Lack of evidence for the size principle of selective vulnerability of axons in toxic neuropathies. I. The effects of subcutaneous injections of 2,5-hexanedione on behavior and muscle spindle function.

2,5-Hexanedione (HD) produces a central-peripheral distal axonopathy. It has been suggested that agents which produce this type of axonopathy show a predilection to the largest diameter fibers. This has been based primarily on morphological data. However, electrophysiological evidence and some clinical and morphological data suggest that this may not be the case. In particular, in acrylamide neuropathy, muscle spindle primary afferents do not show this selectivity, as well as autonomic fibers. This study was carried out to determine whether the largest diameter axons were selectively vulnerable to HD. We found that subcutaneous injections of HD in cats produced a dose-dependent increase in behavioral deficits such as contact placing, stepping, and locomotion. There was also a dose-dependent decrease in the position sensitivity of muscle spindle primary and secondary endings. However, the secondary endings, which are innervated by smaller axons, were affected prior to the primary endings. Also, the velocity sensitivity of the primary endings was depressed at a similar time frame as the position sensitivity of these same endings. These data are consistent with the hypothesis that the caliber of the axon is not the only determinant of the selective vulnerability of axons in distal axonopathy.

Effects of 2,5-hexanedione on deefferented muscle spindle position sensitivity.

2,5-Hexanedione (HD) produces a neurofilamentous axonpathy in humans and experimental animals. The present study was carried out to determine the time course of the effects of HD on muscle spindle position sensitivity to permit comparisons with similar effects of other toxicants which produce a neurofilamentous axonopathy. Cats were administered HD either via their drinking water or via osmotic minipumps. Muscle spindle position sensitivity was tested after a total HD dose of 2.43 or 4.85 g/kg via the drinking water or 0.96, 1.91, or 4.78 g/kg via an osmotic minipump. The position sensitivities of both primary and secondary endings were depressed regardless of the route of administration. However, secondary muscle spindle afferents in the animals intoxicated with HD via the minipumps were affected to a greater extent than primary muscle spindle afferents at all doses studied. These data show that HD alters muscle spindle function and lends support to the suggestion that the largest diameter fibers are not the most vulnerable to HD.

Primary afferent terminal function following acrylamide: alterations in the dorsal root potential and reflex.

The dorsal root potential (DRP) and the dorsal root reflex (DRR) were studied in acrylamide (ACR)-induced axonopathy to determine the nature and extent of primary afferent terminal (PAT) dysfunction. Cats were administered 30 mg/kg/day ACR for either 5 (ACR 5D) or 10 (ACR 10D) days. The day after the last injection, the spinal cord as isolated in situ and the DRP and DRR were elicited. It was found that only 21% of the ACR 10D animals exhibited a DRP. Furthermore, in that 21%, the DRP appeared to degrade over distance differently from the control group. There was no change in the DRP evoked in the ACR 5D group. ACR affected the DRR when evoked from the cutaneous sural nerve (SU) to a greater extent than when evoked from the medial gastrocnemius (MG) nerve. A SU-evoked DRR could not be elicited in any of the animals in the ACR 10D group and in only 20% of the ACR 5D group. There was no difference in the ability to elicit a MG-evoked DDR in either ACR-treated group when compared to control. However, the maximum-evoked area under the DRR elicited from the MG nerve was significantly smaller in the ACR-treated groups than in control. These data show that ACR does indeed impair PAT function. ACR preferentially affects the PAT processing of the SU when compared to the MG nerve, which may indicate that the selective vulnerability of the largest diameter fibers to ACR is not necessarily true.