Ultrafine 5 nm ceria isotropic nanoparticles were prepared using the rapid chemical precipitation approach from cerium(III) nitrate and ammonium hydroxide aqueous solutions. The as-prepared nanoparticles were shown to contain predominantly Ce(IV) species. The solubility of nanocrystalline CeO 2 at several pH values was determined using ICP-MS and radioactive tracer methods. Phase composition of the ceria samples remained unchanged upon partial dissolution, while the shape of the particles changed dramatically, yielding nanorods under neutral pH conditions. According to X-ray absorption spectroscopy investigation of the supernatant, Ce(III) was the main cerium species in solution at pH < 4. Based on the results obtained, a reductive dissolution model was used for data interpretation. According to this model, the solubility product for ceria nanoparticles was determined to be logK sp =-59.3 ± 0.3 in 0.01M NaClO 4. Taken together, our results show that the pH-dependence of ceria anti-and pro-oxidant activity can be related to the dissolution of CeO 2 in aqueous media.
Surface-enhanced Raman spectroscopy (SERS) of living cells has rapidly become a powerful trend in biomedical diagnostics. It is a common belief that highly ordered, artificially engineered substrates are the best future decision in this field. This paper, however, describes an alternative successful solution, a new effortless chemical approach to the design of nanostructured silver and heterometallic continuous coatings with a stochastic ''coffee ring'' morphology. The coatings are formed from an ultrasonic mist of aqueous diamminesilver hydroxide, free of reducing agents and nonvolatile pollutants, under mild conditions, at about 200-270 C in air. They consist of 30-100 micrometer wide and 100-400 nm high silver rings composed, in turn, of a porous silver matrix with 10-50 nm silver grains decorating the sponge. This hierarchic structure originates from ultrasonic droplet evaporation, contact-line motion, silver(I) oxide decomposition and evolution of a growing ensemble of silver rings. The fabricated substrates are a remarkable example of a new scalable and low cost material suitable for SERS analyses of living cells. They evoke no hemolysis and reduce erythrocyte lateral mobility due to suitable ''coffee ring'' sizes and a tight contact with the silver nanostructure. A high SERS enhancement, characteristic of pure silver rings, made it possible to record Raman scattering spectra from submembrane hemoglobin in its natural cellular environment inside single living erythrocytes, thus making the substrates promising for various biosensor chips.
X-ray absorption experiments at Ce L3 and M5 edges and theoretical calculations demonstrate that in addition to the nanoceria charge stability, the formation of hydroxyl groups at the surface affects the chemical performance of nanomaterials.
Extremely defect
graphene oxide (dGO) is proposed as an advanced
sorbent for treatment of radioactive waste and contaminated natural
waters. dGO prepared using a modified Hummers oxidation procedure,
starting from reduced graphene oxide (rGO) as a precursor, shows significantly
higher sorption of U(VI), Am(III), and Eu(III) than standard graphene
oxides (GOs). Earlier studies revealed the mechanism of radionuclide
sorption related to defects in GO sheets. Therefore, explosive thermal
exfoliation of graphite oxide was used to prepare rGO with a large
number of defects and holes. Defects and holes are additionally introduced
by Hummers oxidation of rGO, thus providing an extremely defect-rich
material. Analysis of characterization by XPS, TGA, and FTIR shows
that dGO oxygen functionalization is predominantly related to defects,
such as flake edges and edge atoms of holes, whereas standard GO exhibits
oxygen functional groups mostly on the planar surface. The high abundance
of defects in dGO results in a 15-fold increase in sorption capacity
of U(VI) compared to that in standard Hummers GO. The improved sorption
capacity of dGO is related to abundant carboxylic group attached hole
edge atoms of GO flakes as revealed by synchrotron-based extended
X-ray absorption fine structure (EXAFS) and high-energy resolution
fluorescence detected X-ray absorption near edge structure (HERFD-XANES)
spectroscopy.
Pristine, oxidized and defunctionalized carbon nanotubes (CNTs) were studied by Raman spectroscopy, X-ray diffraction, transmission electron microscopy and low temperature nitrogen adsorption. The Raman spectra of the studied samples in the range of 900-1800 cm were deconvoluted into five components to reveal the CNT oxidation mechanism. It was found that the oxidation resulted in the reduction of graphite components and ordering of both the structured and defect part of CNTs. Acid treatment also led to different types of disorders in the surface layers of CNTs. Polyene-type, polyphenylene-type and turbostratic fragments were detected as a result of partial exfoliation. Investigation of defunctionalized CNTs showed the ordering of edge carbon atoms as well as the invariability of the total amount of defects. The study of CNTs as supports for Co-based catalysts revealed a simultaneous decrease in the number of defect fragments and increase in the number of edge carbon atoms during catalyst preparation and reduction.
This is the accepted version of a paper published in Carbon. This paper has been peerreviewed but does not include the final publisher proof-corrections or journal pagination.
The optical properties of carbon nanowall (CNW) films in the visible range have been studied and reported for the first time. Depending on the film structure, ultra-low total reflectance up to 0.13% can be reached, which makes the CNW films a promising candidate for the black body-like coating, and thus for a wide range of applications as a light absorber. We have estimated important trends in the optical property variation from sample to sample, and identified the presence of edge states and domain boundaries in carbon nanowalls as well as the film mass density variation as the key factors. Also we demonstrated that at much lower film thickness and density than for a carbon nanotube forest the CNWs yield one order higher specific light absorption.
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