Earth-abundant
nickel is a typical non-noble-metal cocatalyst used
for photocatalytic hydrogen evolution (PHE). Ni nanoparticles, however,
tend to aggregate during the hydrogen production process, significantly
lowering their PHE activity. To avoid aggregation, we used single
atom form Ni and anchored them on vacancies in nitrogen-doped graphene
(Ni-NG) as a cocatalyst for PHE. We demonstrated that Ni-NG is a robust
and highly active cocatalyst for PHE from water. With only 0.0013
wt % of Ni loading, the PHE activity of composite Ni-NG/CdS photocatalyst
improves by 3.4 times compared to that of NG/CdS, and it does not
decay even after 10 rounds of 5-hour running. The quantum efficiency
of Ni-NG/CdS for PHE reaches 48.2% at 420 nm, one of the highest efficiencies
for non-noble-metal-based cocatalysts reported in the literature.
Photoluminescence spectral analyses and electrochemical examinations
indicated that Ni-NG coupled to CdS serves not only as an electron
storage medium to suppress electron–hole recombination but
also as an active catalyst for proton reduction reaction. Density
functional theory calculations show that the high activity of Ni-NG/CdS
composite results from the single Ni atoms trapped in NG vacancies,
which significantly reduces the activation energy barrier of the hydrogen
evolution reaction. This research may be valuable for developing robust
and highly active noble metal free cocatalysts for solar hydrogen
production.
Organic luminogens constitute promising prototypes for various optoelectronic applications. Since gaining distinct color emissions normally requires the alternation of the conjugated backbone, big issues remain in material synthetic cost and skeleton compatibility while pursuing full‐color luminescence. Upon a facile one‐step coupling, three simple but smart perchalcogenated (O, S, and Se) arenes are synthesized. They exhibit strong luminescent tricolor primaries (i.e., blue, green, and red, respectively) in the solid state with a superior quantum yield up to >40% (5–10 times higher than that in corresponding solutions). The properties originate from a fluorescence–phosphorescence–phosphorescence triple‐channel emission effect, which is regulated by S and Se heavy atoms–dependent intersystem crossing upon molecular packing, as well as Se–Se atom interaction–caused energy splittings. Consequently, full‐color luminescence, including a typical white‐light luminescence with a Commission Internationale de I'Eclairage coordinate of (0.30, 0.35), is realized by complementarily incorporating these tricolor luminescent materials in the film. Moreover, mechanochromic luminescent color conversions are also observed to achieve the fine‐tuning of the luminescent tints. This strategy can be smart to address full‐color luminescence on the same molecular skeleton, showing better material compatibility as an alternative to the traditional multiple‐luminophore engineering.
In this paper, we demonstrate for the first time the use of gliadin particles to structure algal oil (rich in DHA) and to exert chemical stability against lipid oxidation via the Pickering high internal phase emulsion (HIPE) strategy. The gliadin/chitosan colloid particles (GCCPs) were effectively adsorbed and anchored at the algal oil-water interface. Concomitantly, the particle-coated droplets as building blocks constructed a percolating 3D-network framework, endowing Pickering HIPEs with viscoelastic and self-supporting attributes. In addition, Pickering HIPEs loaded with shell (HIP-curEs) or core curcumin (HIPEs-cur) were constructed to depress the oxidation of algal oil. The content of primary (lipid hydroperoxides) and secondary (malondialdehyde and hexanal) oxidation products in HIPEs was lower than that in bulk oil. The oxidative stability of HIPEs was further improved in shell and core curcumin. An in vitro gastrointestinal (GI) model was constructed to characterize the lipid digestion, lipid oxidation as well as curcumin bioaccessibility of the ingested Pickering HIPEs. Lipid oxidation in the Pickering HIPEs was retarded under GI fluids, especially in the presence of core curcumin. The free fatty acid (FFA) fraction released was below 30% for all HIPEs, reflecting that the Pickering HIPEs formed restrict the digestion of fat or oil and potentially help to fight obesity. Interestingly, this route enhanced the bioaccessibility of curcumin from only 2.13% (bulk algal oil) to 53.61% (core curcumin); in particular, it reached 76.82% for shell curcumin. These results help to fill the gap between the physicochemical performance of the gliadin particle stabilized Pickering HIPEs and their potential applications as oral delivery systems of nutraceuticals. This work opens concomitantly an attractive strategy to convert liquid oils into antioxidant soft solids without artificial trans fats, as a potential alternative for PHOs.
In this paper, we demonstrate the use of gliadin/chitosan complex particles (GCCPs) as particulate stabilizers of oil-in-water emulsions of natural oils and water. For this purpose, we fabricated GCCPs through a facile anti-solvent procedure and demonstrated their usage in the formation of Pickering emulsions and Pickering high internal phase emulsions (HIPEs). The GCCPs can be used to produce surfactant-free o/w Pickering emulsions and Pickering HIPEs; unfortunately these emulsions were labile to coalescence. NaCl addition and/or pH regulation, and the combination were used to modify the surface wettability of the complex particles to achieve stable emulsions. The microstructures, e.g., interfacial frameworks, GCCP partition between the continuous phase and interfacial region, and the state of the droplets, of Pickering emulsions were visualized by confocal laser scanning microscopy (CLSM), confirming that the inclusion of NaCl and slightly adjusting pH toward 4.0 and/or 5.0 benefited the adsorption and accumulation of colloid particles at the droplet surface to form an engineered interfacial structure, bridging droplets together through a percolating layer of colloidal particles at the oil/water interface. A schematic representation for the formation route of the emulsions is proposed to relate the physical performance and rheological property with the interfacial structures and aggregate behaviors in the Pickering system stabilized by the complex particles. Interestingly, direct freeze-drying of the emulsions transformed unstable Pickering emulsions into stable oil powders. This study opens a promising route based on Pickering HIPEs or oil powders to structure liquid oils into solid-like fats without artificial trans-fat, which outlines new directions for future fundamental research.
Pickering high internal-phase emulsions
(HIPEs) and porous materials
derived from the Pickering HIPEs have received increased attention
in various research fields. Nevertheless, nondegradable inorganic
and synthetic stabilizers present toxicity risks, thus greatly limiting
their wider applications. In this work, we successfully developed
nontoxic porous materials through the Pickering HIPE-templating process
without chemical reactions. The obtained porous materials exhibited
appreciable absorption capacity to corn oil and reached the state
of saturated absorption within 3 min. The Pickering HIPE templates
were stabilized by gliadin–chitosan complex particles (GCCPs),
in which the volume fraction of the dispersed phase (90%) was the
highest of all reported food-grade-particle-stabilized Pickering HIPEs
so far, further contributing to the interconnected pore structure
and high porosity (>90%) of porous materials. The interfacial particle
barrier (Pickering mechanism) and three-dimensional network formed
by the GCCPs in the continuous phase play crucial roles in stabilization
of HIPEs with viscoelastic and self-supporting attributes and also
facilitate the development of porous materials with designed pore
structure. These materials, with favorable biocompatibility and biodegradability,
possess excellent application prospects in foods, pharmaceuticals,
materials, environmental applications, and so on.
Intensive research focuses on the development of nanoparticles, not only for their fundamental scientific interest, but also for a variety of technological applications. Monodisperse nanoparticles with a size variation of less than 5% exceptionally have been received much attention, due to their novel and high performance induced by the strong dependence of properties upon the dimension of the nanoparticles. Their unique properties result in a great of potential applications in the area of ultra-high density magnetic storage media, electronics, biomedical usage, medical diagnosis, catalyst, etc. This is stimulating a high level of interest in the development of large scale synthesis techniques of monodisperse nanoparticles. In this article, the recent advance about the relevant aspects of large scale synthesis approaches for various monodisperse nanoparticles was summarized.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.