34 research outputs found
Effect of Nb doping on structural, optical and photocatalytic properties of flame-made TiO2 nanopowder
TiO2:Nb nanopowders within a dopant concentration in the range of 0.1-15at.% were prepared by one-step flame spray synthesis. Effect of niobium doping on structural, optical and photocatalytic properties of titanium dioxide nanopowders was studied. Morphology and structure were investigated by means of Brunauer-Emmett-Teller isotherm, X-ray diffraction and transmission electron microscopy. Diffuse reflectance and the resulting band gap energy were determined by diffuse reflectance spectroscopy. Photocatalytic activity of the investigated nanopowders was revised for the photodecomposition of methylene blue (MB), methyl orange (MO) and 4-chlorophenol under UVA and VIS light irradiation. Commercial TiO2-P25 nanopowder was used as a reference. The specific surface area of the powders was ranging from 42.9m2/g for TiO2:0.1at.% Nb to 90.0m2/g for TiO2:15at.% Nb. TiO2:Nb particles were nanosized, spherically shaped and polycrystalline. Anatase was the predominant phase in all samples. The anatase-related transition was at 3.31eV and rutile-related one at 3.14eV. TiO2:Nb nanopowders exhibited additional absorption in the visible range. In comparison to TiO2-P25, improved photocatalytic activity of TiO2:Nb was observed for the degradation of MB and MO under both UVA and VIS irradiation, where low doping level (Nbâ<â1at.%) was the most effective. Niobium doping affected structural, optical and photocatalytic properties of TiO2. Low dopant level enhanced photocatalytic performance under UVA and VIS irradiation. Therefore, TiO2:Nb (Nbâ<â1at.%) can be proposed as an efficient selective solar light photocatalys
Control of arms of au stars size and its dependent cytotoxicity and photosensitizer effects in photothermal anticancer therapy
Gold nanostars (AuS NPs) are a very attractive nanomaterial, which is characterized by high
effective transduction of the electromagnetic radiation into heat energy. Therefore, AuS NPs can be
used as photosensitizers in photothermal therapy (PTT). However, understanding the photothermal
conversion efficiency in nanostars is very important to select the most appropriate shape and size of
AuS NPs. Therefore, in this article, the synthesis of AuS NPs with different lengths of star arms for
potential application in PTT was investigated. Moreover, the formation mechanism of these AuS
NPs depending on the reducer concentration is proposed. Transmission electron microscopy (TEM)
with selected area diffraction (SEAD) and X-ray diffraction (X-Ray) showed that all the obtained AuS
NPs are crystalline and have cores with similar values of the diagonal (parameter d), from 140 nm
to 146 nm. However, the widths of the star arm edges (parameter c) and the lengths of the arms
(parameter a) vary between 3.75 nm and 193 nm for AuS1 NPs to 6.25 nm and 356 nm for AuS4 NPs.
Ultraviolet-visible (UV-Vis) spectra revealed that, with increasing edge widths and lengths of the star
arms, the surface plasmon resonance (SPR) peak is shifted to the higher wavelengths, from 640 nm for
AuS1 NPs to 770 nm for AuS4 NPs. Moreover, the increase of temperature in the AuS NPs solutions
as well as the values of calculated photothermal efficiency grew with the elongation of the star arms.
The potential application of AuS NPs in the PTT showed that the highest decrease of viability, around
75%, of cells cultured with AuS NPs and irradiated by lasers was noticed for AuS4 NPs with the
longest arms, while the smallest changes were visible for gold nanostars with the shortest arms. The
present study shows that photothermal properties of AuS NPs depend on edge widths and lengths
of the star arms and the values of photothermal efficiency are higher with the increase of the arm
lengths, which is correlated with the reducer concentration
Fe3O4@SiO2@Au nanoparticles for MRI-guidedchemo/NIR photothermal therapy of cancer cells
Novel functionalized (biofunctionalization followed by cisplatin immobilization) Fe3O4@SiO2@Au nanoparticles (NPs) were designed. The encapsulation of Fe3O4 cores inside continuous SiO2 shells preserves their initial structure and strong magnetic properties, while the shell surface can be decorated by small Au NPs, and then cisplatin (cPt) can be successfully immobilized on their surface. The fabricated NPs exhibit very strong T2 contrasting properties for magnetic resonance imaging (MRI). The functionalized Fe3O4@SiO2@Au NPs are tested for a potential application in photothermal cancer therapy, which is simulated by irradiation of two colon cancer cell lines (SW480 and SW620) with a laser (λ = 808 nm, W = 100 mW cmâ2). It is found that the functionalized NPs possess low toxicity towards cancer cells (âŒ10â15%), which however could be drastically increased by laser irradiation, leading to a mortality of the cells of âŒ43â50%. This increase of the cytotoxic properties of the Fe3O4@SiO2@Au NPs, due to the synergic effect between the presence of cPt plus Au NPs and laser irradiation, makes these NPs perspective agents for potential (MRI)-guided stimulated chemo-photothermal treatment of cancer
Effect of Nb doping on structural, optical and photocatalytic properties of flame-made TiO2 nanopowder
TiO2:Nb nanopowders within a dopant concentration in the range of 0.1-15 at.% were prepared by one-step flame spray synthesis. Effect of niobium doping on structural, optical and photocatalytic properties of titanium dioxide nanopowders was studied. Morphology and structure were investigated by means of BrunauerâEmmettâTeller isotherm, X-ray diffraction and transmission electron microscopy. Diffuse reflectance and the resulting band gap energy were determined by diffuse reflectance spectroscopy. Photocatalytic activity of the investigated nanopowders was revised for the photodecomposition of methylene blue (MB), methyl orange (MO) and 4-chlorophenol under UVA and VIS light irradiation. Commercial TiO2-P25 nanopowder was used as a reference. The specific surface area of the powders was ranging from 42.9 m2/g for TiO2:0.1 at.% Nb to 90.0 m2/g for TiO2:15 at.% Nb. TiO2:Nb particles were nanosized, spherically shaped and polycrystalline. Anatase was the predominant phase in all samples. The anatase-related transition was at 3.31 eV and rutile-related one at 3.14 eV. TiO2:Nb nanopowders exhibited additional absorption in the visible range. In comparison to TiO2-P25, improved photocatalytic activity of TiO2:Nb was observed for the degradation of MB and MO under both UVA and VIS irradiation, where low doping level (Nbâ<â1 at.%) was the most effective. Niobium doping affected structural, optical and photocatalytic properties of TiO2. Low dopant level enhanced photocatalytic performance under UVA and VIS irradiation. Therefore, TiO2:Nb (Nbâ<â1 at.%) can be proposed as an efficient selective solar light photocatalyst