Water electrolysis is considered as a promising way to store and convert excess renewable energies into hydrogen, which is of high value for many chemical transformation processes such as the Haber-Bosch process. However, to allow for the widespread of the polymer electrolyte membrane water electrolysis (PEMWE) technology, the main challenge lies in the design of robust catalysts for oxygen evolution reaction (OER) under acidic conditions since most of transition metal-based oxides undergo structural degradation under these harsh acidic conditions. To broaden the variety of candidate materials as OER catalysts, a cationexchange synthetic route was recently explored to reach crystalline pronated iridates with unique structural properties and stability. In this work, a new protonated phase H 3.6 IrO 4 •3.7H 2 O, prepared via Sr 2+ /H + cation exchange at room temperature starting from the parent Ruddlesden-Popper Sr 2 IrO 4 phase, is described. This is the first discovery of crystalline protonated iridate forming from a perovskite-like phase, adopting a layered structure with apex-linked IrO 6 octahedra. Furthermore, H 3.6 IrO 4 •3.7H 2 O is found to possess not only an enhanced specific catalytic activity, superior to that of other perovskite-based iridates, but also a mass activity comparable to that of nanosized IrO x particles, while showing an improved catalytic stability owing to its ability to reversibly exchange protons in acid.
Expanding the chemical space for designing novel anionic redox materials from oxides to sulfides has enabled to better apprehend fundamental aspects dealing with cationic-anionic relative band positioning. Pursuing with chalcogenides, but deviating from cationic substitution, we here present another twist to our band positioning strategy that relies on mixed ligands with the synthesis of the Li2TiS3-xSex solid solution series. Through the series the electrochemical activity displays a bell shape variation that peaks at 260 mAh/g for the composition x = 0.6 with barely no capacity for the x = 0 and x = 3 end members. We show that this capacity results from cumulated anionic (Se2−/Sen−) and (S2−/Sn−) and cationic Ti3+/Ti4+ redox processes and provide evidence for a metal-ligand charge transfer by temperature-driven electron localization. Moreover, DFT calculations reveal that an anionic redox process cannot take place without the dynamic involvement of the transition metal electronic states. These insights can guide the rational synthesis of other Li-rich chalcogenides that are of interest for the development of solid-state batteries.
This work focuses on synthesis and characterization of targeted magnetic nanoparticles as magnetic resonance imaging (МRI) agents for in vivo visualization of gliomas. The authors utilize the fact that high-grade gliomas have extensive areas of necrosis and hypoxia, which results in increased secretion of angiogenesis vascular endothelial growth factor (VEGF). Monoclonal antibodies against vascular endothelial growth factor (mAbVEGF) were covalently conjugated to crosslinked BSA coated ferric oxide (Fe3O4) nanoparticles. The results show that these targeted nanoparticles are effective in MRI visualization of the intracranial glioma and may provide a new and promising contrast agent.
All-solid-state batteries (ASSBs) that rely on the use
of solid
electrolytes (SEs) with high ionic conductivity are the holy grail
for future battery technology, since it could enable both greater
energy density and safety. However, practical application of ASSBs
is still being plagued by difficulties in mastering the SE–electrode
interphases. This calls for a wide exploration of electrolyte candidates,
among which halide-based Li+ conductors show promise despite
being not stable against Li or Li
x
In
y
negative electrodes, hence the need to assemble
cells with a dual SE design. In the work described herein, we studied
the electrochemical/chemical compatibility of Li3InCl6 against layered oxide positive electrode (LiNi0.6Mn0.2Co0.2O2, NMC622), carbon
additive, and Li6PS5Cl under both cycling and
aging conditions. Combining electroanalytical and spectroscopic techniques,
we provide evidence for the onset of electrochemically driven parasitic
decomposition reactions between Li3InCl6 and
NMC622/carbon at lower potentials (3.3 V vs LiIn/In) than theoretically
predicted in the literature. Moreover, to combat chemical incompatibility
between dual SEs, we propose a new strategy that consists of depositing
a nanometer-thick (1 or 2 nm) surface protective layer of Li3PO4 made by atomic layer deposition between Li3InCl6 and Li6PS5Cl. Through this
surface engineering process with highly conformal and pinhole-free
thin films, halide-based solid-state cells showing spectacular capacity
retention over 400 cycles were successfully assembled. Altogether,
these findings position halide SEs as serious contenders for the development
of ASSBs.
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