Controlled
phase conversion in polymorphic transition metal dichalcogenides
(TMDs) provides a new synthetic route for realizing tunable nanomaterials.
Most conversion methods from the stable 2H to metastable 1T phase
are limited to kinetically slow cation insertion into atomically thin
layered TMDs for charge transfer from intercalated ions. Here, we
report that anion extraction by the selective reaction between carbon
monoxide (CO) and chalcogen atoms enables predictive and scalable
TMD polymorph control. Sulfur vacancy, induced by anion extraction,
is a key factor in molybdenum disulfide (MoS2) polymorph
conversion without cation insertion. Thermodynamic MoS2–CO–CO2 ternary phase diagram offers a processing
window for efficient sulfur vacancy formation with precisely controlled
MoS2 structures from single layer to multilayer. To utilize
our efficient phase conversion, we synthesize vertically stacked 1T-MoS2 layers in carbon nanofibers, which exhibit highly efficient
hydrogen evolution reaction catalytic activity. Anion extraction induces
the polymorph conversion of tungsten disulfide (WS2) from
2H to 1T. This reveals that our method can be utilized as a general
polymorph control platform. The versatility of the gas–solid
reaction-based polymorphic control will enable the engineering of
metastable phases in 2D TMDs for further applications.
Amorphous oxide semiconductor (AOS)-based Schottky diodes have been utilized for selectors in crossbar array memories to improve cell-to-cell uniformity with a low-temperature process. However, thermal instability at interfaces between the AOSs and metal electrodes can be a critical issue for the implementation of reliable Schottky diodes. Under post-fabrication annealing, an excessive redox reaction at the ohmic interface can affect the bulk region of the AOSs, inducing an electrical breakdown of the device. Additionally, structural relaxation (SR) of the AOSs can increase the doping concentration at the Schottky interface, which results in a degradation of the rectifying performance. Here, we improved the thermal stability at AOS/metal interfaces by regulating the oxygen vacancy (
V
O
) concentration at both sides of the contact. For a stable quasi-ohmic contact, a Cu-Mn alloy was introduced instead of a single component reactive metal. As Mn only takes up O in amorphous In-Ga-Zn-O (a-IGZO), excessive
V
O
generation in bulk region of a-IGZO can be prevented. At the Schottky interfaces, the barrier characteristics were not degraded by thermal annealing as the Ga concentration in a-IGZO increased. Ga not only reduces the inherent
V
O
concentration but also retards SR, thereby suppressing tunneling conduction and enhancing the thermal stability of devices.
Quercetin (Qu) is a dietary antioxidant and a member of flavonoids in the plant polyphenol family. Qu has a high ability to scavenge reactive oxygen species (ROS) and reactive nitrogen species (RNS) molecules; hence, exhibiting beneficial effects in preventing obesity, diabetes, cancer, cardiovascular diseases, and inflammation. However, quercetin has low bioavailability due to poor water solubility, low absorption, and rapid excretion from the body. To address these issues, the usage of Qu nanosuspensions can improve physical stability, solubility, and pharmacokinetics. Therefore, we developed a Qu and polyethylene glycol nanosuspension (Qu-PEG NS) and confirmed its interaction by Fourier transform infrared analysis. Qu-PEG NS did not show cytotoxicity to HaCaT and RAW 264.7 cells. Furthermore, Qu-PEG NS effectively reduced the nitrogen oxide (NO) production in lipopolysaccharide (LPS)-induced inflammatory RAW 264.7 cells. Additionally, Qu-PEG NS effectively lowered the levels of COX-2, NF-κB p65, and IL-1β in the LPS-induced inflammatory RAW 264.7 cells. Specifically, Qu-PEG NS exhibited anti-inflammatory properties by scavenging the ROS and RNS and mediated the inhibition of NF-κB signaling pathways. In addition, Qu-PEG NS had a high antioxidant effect and antibacterial activity against Escherichia coli and Bacillus cereus. Therefore, the developed novel nanosuspension showed comparable antioxidant, anti-inflammatory, and antibacterial functions and may also improve solubility and physical stability compared to raw quercetin.
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