In pondering of new promising transparent conductors to replace the cost rising tin-doped indium oxide (ITO), metal nanowires have been widely concerned. Herein, we demonstrate an approach for successful synthesis of long and fine Cu nanowires (NWs) through a novel catalytic scheme involving nickel ions. Such Cu NWs in high aspect ratio (diameter of 16.2 ± 2 nm and length up to 40 μm) provide long distance for electron transport and, meanwhile, large space for light transmission. Transparent electrodes fabricated using the Cu NW ink achieve a low sheet resistance of 1.4 Ohm/sq at 14% transmittance and a high transparency of 93.1% at 51.5 Ohm/sq. The flexibility and stability were tested with 100-timebending by 180°and no resistance change occurred. Ohmic contact was achieved to the p- and n-GaN on blue light emitting diode chip and bright electroluminescence from the front face confirmed the excellent transparency.
Immune checkpoint blockade therapy has been successful in treating some types of cancers but has not shown clinical benefits for treating leukemia
1
. This result suggests that leukemia exploits unique escape mechanisms. Certain immune inhibitory receptors that are expressed by normal immune cells are also present on leukemia cells. It remains unknown whether these receptors can initiate immune-related primary signaling in tumor cells. Here we show that LILRB4, an ITIM-containing receptor and a monocytic leukemia marker, supports tumor cell infiltration into tissues and suppresses T cell activity via ApoE/LILRB4/SHP-2/uPAR/Arginase-1 signaling axis in acute myeloid leukemia (AML) cells. Blocking LILRB4 signaling using knockout and antagonistic antibody approaches impeded AML development. Thus, LILRB4 orchestrates tumor invasion pathways in monocytic leukemia cells by creating an immune-suppressive microenvironment. LILRB4 represents a compelling target for treatment of monocytic AML.
Nickel nanoparticles were prepared from the thermal decomposition of nickel(II)
acetylacetonate in alkylamines and characterized by powder x-ray diffraction, transmission
electron microscopy and magnetic measurement. The reaction temperature, heating rate
and solvent type play an important role in the control over the crystalline phase.
Depending on the reaction conditions, face-centered cubic (fcc) or hexagonal close-packed
(hcp) nickel nanoparticles can be obtained. Monodisperse nickel nanoparticles were also
obtained by introducing surfactants. The results of magnetic characterization showed that
the magnetic properties of the hcp nickel nanoparticles are quite different from those of the
fcc nickel nanoparticles.
The preparation of noble metal-semiconductor hybrid nanocrystals with controlled morphologies has received intensive interest in recent years. In this study, facile one-pot reactions have been developed for the synthesis of Au-ZnO hybrid nanocrystals with different interesting morphologies, including petal-like and urchin-like nanoflowers, nanomultipods and nanopyramids. In the synthesis strategy, oleylamine-containing solution serves as the reaction medium, and the in situ generated Au seeds play an important role in the subsequently induced growth of ZnO nanocrystals. With the aid of several surfactants, hybrid nanocrystals with different morphologies that have considerable influences on their optical and photocatalytic activities are readily achieved. Through high-resolution transmission electron microscopy measurements, an observed common orientation relationship between ZnO and Au is that ZnO nanocrystals prefer to grow with their polar {001} facets on the {111} facets of Au nanocrystals, and well-defined interfaces are evident. Surface plasmon resonance bands of Au with different positions are observed in the UV-vis spectra, and the UV and visible emissions of ZnO are found to be dramatically reduced. Finally, the as-prepared Au-ZnO nanocrystals exhibit excellent photocatalytic activity for the photodegradation of rhodamine B compared with pure ZnO nanocrystals. The Au-ZnO hybrid nanopyramids show the highest catalytic efficiency, which is correlated with the exposed crystal facets, crystallinity and the formation of hybrid nanostructures. The as-prepared Au-ZnO hybrid nanocrystals are expected to find diverse potential applications in the fields such as photocatalysis, solar energy conversion, sensing and biological detection.
A highly shape selective synthesis of Cu and Cu@Cu-Ni nanocubes and nanowires has been developed by modulating the coordination chemistry of transition metal ions with a trioctylphosphine (TOP)-Cl(-) ligand pair in oleylamine under mild organic solvent conditions. The as-prepared nanocubes have a face-centered cubic (fcc) phase and are covered by six {100} facets, whereas the as-prepared nanowires have a multi-twinned structure and grow along the [110] direction. Both the Ni(2+) and Cl(-) ions, along with TOP, play vital roles in determining the final morphology of the as-prepared nanocrystals (NCs). TOP can be used to selectively generate single-crystal seeds at the initial stage, which then grow into nanocubes in the presence of Cl(-) ions, while the absence of TOP leads to the formation of multi-twined crystal seeds that finally develop into nanowires. Moreover, Ni can be incorporated to form a Cu-Ni alloy shell over a Cu core at higher temperatures in a one-pot process, which makes diamagnetic Cu NCs magnetically responsive and has a significant influence on their optical properties.
Sub-5 nm ultra-fine iron phosphide
(FeP) nano-dots-modified porous graphitic carbon nitride (g-C3N4) heterojunction nanostructures are successfully
prepared through the gas-phase phosphorization of Fe3O4/g-C3N4 nanocomposites. The incorporation
of zero-dimensional (0D) ultra-small FeP nanodots co-catalysts not
only effectively facilitate charge separation but also serve as reaction
active sites for hydrogen (H2) evolution. Herein, the strongly
coupled FeP/g-C3N4 hybrid systems are employed
as precious-metal-free photocatalysts for H2 production
under visible-light irradiation. The optimized FeP/g-C3N4 sample displays a maximum H2 evolution rate
of 177.9 μmol h–1 g–1 with
the apparent quantum yield of 1.57% at 420 nm. Furthermore, the mechanism
of photocatalytic H2 evolution using 0D/2D FeP/g-C3N4 heterojunction interfaces is systematically
corroborated by steady-state photoluminescence (PL), time-resolved
PL spectroscopy, and photoelectrochemical results. Additionally, an
increased donor density in FeP/g-C3N4 is evidenced
from the Mott–Schottky analysis in comparison with that of
parent g-C3N4, signifying the enhancement of
electrical conductivity and charge transport owing to the emerging
role of FeP. The density functional theory calculations reveal that
the FeP/g-C3N4 hybrids could act as a promising
catalyst for the H2 evolution reaction. Overall, this work
not only paves a new path in the engineering of monodispersed FeP-decorated
g-C3N4 0D/2D robust nanoarchitectures but also
elucidates potential insights for the utilization of noble-metal-free
FeP nanodots as remarkable co-catalysts for superior photocatalytic
H2 evolution.
Synthesis of stable and monodisperse Cu nanocrystals of controlled morphology has been a long-standing challenge. In this article, we report a facile disproportionation reaction approach for the synthesis of such nanocrystals in organic solvents. Either spherical or cubic shapes can be produced, depending on conditions. The typical Cu nanospheres are single crystals with a size of 23.4±1.5 nm, and can self-assemble into three-dimensional (3D) nanocrystal superlattices with a large scale. By manipulating the chemical additives, monodisperse Cu nanocubes with tailorable sizes have also been obtained. The probable formation mechanism of these Cu nanocrystals is discussed. The narrow size distribution results in strong surface plasmon resonance (SPR) peaks even though the resonance is located in the interband transition region. Double SPR peaks are observed in the extinction spectra for the Cu nanocubes with relative large sizes. Theoretical simulation of the extinction spectra indicates that the SPR band located at longer wavelengths is caused by assembly of Cu nanocubes into more complex structures. The synthesis procedure that we report here is expected to foster systematic investigations on the physical properties and self-assembly of Cu nanocrystals with shape and size singularity for their potential applications in photonic and nanoelectronic devices.
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