We report a simple and yet effective method to introduce Mn(2+) ions into semiconducting nanoclusters with atomically precise control. Our method utilizes one type of micrometer-sized crystals, composed of well-defined isolated supertetrahedral chalcogenide nanoclusters (∼2 nm, [Cd6In28S52(SH)4]) whose core metal site is unoccupied in as-synthesized pristine form. This unique model structure with vacant core site makes it possible to achieve ordered distribution of Mn(2+) dopants, and at the same time effectively preclude the formation of Mn(2+) clusters in the host matrix. A two-step synthesis strategy is applied to realize an atomically precise doping of Mn(2+) ion into the core site of the nanoclusters, and to achieve uniform distribution of Mn(2+) dopants in the crystal lattice. The PL, X-ray photoelectron (XPS), as well as the electron paramagnetic resonance (EPR) spectra reveal the successful incorporation of Mn(2+) ion into the core site of the nanocluster. Different from the pristine host material with weak green emission (∼490 nm), the Mn(2+)-doped material shows a strong red emission (630 nm at room temperature and 654 nm at 30 K), which is significantly red-shifted relative to the orange emission (∼585 nm) observed in traditional Mn(2+)-doped II-VI semiconductors. Various experiments including extensive synthetic variations and PL dynamics have been performed to probe the mechanistic aspects of synthesis process and resultant unusual structural and PL properties. The quaternary semiconductor material reported here extends the emission window of Mn(2+)-doped II-VI semiconductor from yellow-orange to red, opening up new opportunities in applications involving photonic devices and bioimaging.
We apply a two-step strategy to realize ordered distribution of multiple components in one nanocluster (NC) with a crystallographically ordered core/shell structure. A coreless supertetrahedral chalcogenide Cd-In-S cluster is prepared, and then a copper ion is inserted at its void core site through a diffusion process to form a Cu-Cd-In-S quaternary NC. This intriguing molecular cluster with mono-copper core and Cd-In shell exhibits enhanced visible-light-responsive optical and photoelectric properties compared to the parent NC.
We herein present the first case of energy transfer process in an inorganic chalcogenide-based semiconductor zeolite material (coded as RWY) serving as UV−vis light-harvesting host. A multistep vectorial energy transfer assay was fabricated by encapsulating acridine orange (AO) molecules into the RWY porous framework and further covering the formed capsules with rhodamine B (RhB) molecules. The UV high-energy excitations absorbed by RWY host were channeled to AO molecules and then onto RhB molecules to give rise to visible-light emission. The steady-state fluorescence and confocal microscope as well as fluorescent dynamics of emission reveal successfully the process of multistep vectorial energy transfer. This inorganic-host-involved energy transfer process has never been observed in an insulating oxide-based zeolite host system. Therefore, chalcogenide-based semiconductor zeolites could be a class of promising host materials to be further explored in the field of energy transfer and electron transfer between inorganic host and organic guest.
Optogenetic
therapy has emerged as a promising technique for the
treatment of ocular diseases; however, most optogenetic tools rely
on external blue light to activate the photoswitch, whose relatively
strong phototoxicity may induce retinal damage. Herein, we present
the demonstration of camouflage nanoparticle-based vectors for in situ bioluminescence-driven optogenetic therapy of retinoblastoma.
In biomimetic vectors, the photoreceptor CRY2 and its interacting
partner CIB1 plasmid are camouflaged with folic acid ligands and luciferase
NanoLuc-modified macrophage membranes. To conduct proof-of-concept
research, this study employs a mouse model of retinoblastoma. In comparison
to external blue light irradiation, the developed system enables an in situ bioluminescence-activated apoptotic pathway to inhibit
tumor growth with greater therapeutic efficacy, resulting in a significant
reduction in ocular tumor size. Furthermore, unlike external blue
light irradiation, which causes retinal damage and corneal neovascularization,
the camouflage nanoparticle-based optogenetic system maintains retinal
structural integrity while avoiding corneal neovascularization.
Herein, we designed and synthesized a novel microRNA
(miR)-responsive
nanoantenna capable of early diagnosis and smart treatment of acute
kidney injury (AKI). The nanoantenna was made of two miniature gold
nanorods (AuNRs) (e.g., length: ∼48 nm; width:
∼9 nm) linked together by a rectangular DNA origami nanostructure
(rDONs) scaffold (e.g., length: ∼90 nm; width:
∼60 nm) (rDONs@AuNR dimer). The surface plasmon resonance peak
of the constructed nanoantenna is located within the NIR-II window
(e.g., ∼1060 nm), thus guaranteeing photoacoustic
(PA) imaging of the nanoantenna in deep tissues. Intriguingly, the
nanoantenna displayed exclusive kidney retention in both healthy mice
and ischemia reperfusion-induced AKI mice by leveraging the kidney-targeting
ability of rDONs. Distinguished from the stable signals in the healthy
mice, the PA signals of the nanoantenna would turn down in the AKI
mice due to the AuNR detached from rDONs upon interaction with miR-21,
which were up-expressed in AKI mice. The limit of detection toward
miR-21 was down to 2.8 nM, enabling diagnosis of AKI as early as 10
min post-treatment with ischemia reperfusion, around 2 orders of magnitude
earlier than most established probes. Moreover, the naked rDON scaffold
generated by AKI could capture more reactive oxygen species (e.g., 1.5-fold more than rDONs@AuNR dimer), alleviating
ischemic AKI. This strategy provided a new avenue for early diagnosis
and smart treatment of AKI.
Microporous layer (MPL) is a vital component for proton-exchange membrane fuel cells (PEMFCs) to improve the cell performance. However, the conventional preparation of MPL, involving the mixing of carbon black with hydrophobic agent polytetrafluoroethylene (PTFE), followed by high-temperature annealing, is often complicated and costly. Herein, we present a facile and low-cost method to fabricate the MPL by functionalization of carbon black via covalent bonding with hydrophobic agent. Upon chemical grafting with fluoroalkylsilane (FAS-17), the water contact angle of carbon black is increased from 66.4 to 150.4°, resulting in superhydrophobicity. The MPL prepared with the resultant superhydrophobic carbon endows the PEMFC with enhanced gas and water permeability and hereby improved electrochemical performance over traditional MPL, and a maximum power density of 1211 mW cm −2 for the PEMFC can be obtained. This work offers a feasible strategy to construct an efficient MPL for the PEMFC via a chemical grafting approach.
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