In
the current information age, the realization of memory devices
with energy efficient design, high storage density, nonvolatility,
fast access, and low cost is still a great challenge. As a promising
technology to meet these stringent requirements, nonvolatile multistates
memory (NMSM) has attracted lots of attention over the past years.
Owing to the capability to store data in more than a single bit (0
or 1), the storage density is dramatically enhanced without scaling
down the memory cell, making memory devices more efficient and less
expensive. Multistates in a single cell also provide an unconventional
in-memory computing platform beyond the Von Neumann architecture and
enable neuromorphic computing with low power consumption. In this
review, an in-depth perspective is presented on the recent progress
and challenges on the device architectures, material innovation, working
mechanisms of various types of NMSMs, including flash, magnetic random-access
memory (MRAM), resistive random-access memory (RRAM), ferroelectric
random-access memory (FeRAM), and phase-change memory (PCM). The intriguing
properties and performance of these NMSMs, which are the key to realizing
highly integrated memory hierarchy, are discussed and compared.
Acting on a broad spectrum of extracellular, intracellular, and membrane-associated substrates, the matrix metalloproteinases (MMPs) are critical to the biological processes of organisms; when aberrantly expressed, many pathological conditions may be born or exacerbated. The prospect of MMP inhibition for therapeutic benefit in cancer, cardiovascular disease, and stroke is reviewed here. MMP inhibitor (MMPI) development constitutes an important branch of research in both academic and industrial settings and advances our knowledge on the structure-function relationship of MMPs. Targeting MMPs in disease treatment is complicated by the fact that MMPs are indispensable for normal development and physiology and by their multi-functionality, possible functional redundancy or contradiction, and context-dependent expression and activity. This complexity was revealed by previous efforts to inhibit MMP activity in the treatment of cancer patients that yielded unsatisfactory results. This review focuses on MMPI development since the late 90s, in terms of natural products and their derivatives, and synthetic compounds of low molecular mass incorporating specific zinc-binding groups (ZBGs). A few polyphenols and flavonoids that exhibit MMPI activities may have chemopreventive and neuro- and cardiovascular-protective effects. A new generation of potent and selective MMPIs with novel ZBGs and inhibition mechanisms have been designed, synthesized, and tested. Although only one collagenase inhibitor (Periostat, doxycycline hyclate) has been approved by the Food and Drug Administration as a drug for the treatment of periodontal disease, new hope is emerging in the form of natural and synthetic MMPIs for the prevention and treatment of stroke, cardiovascular disease, cancer, and other medical conditions.
Co-doped wurtzite ZnO [Zn(1−x)CoxO] thin films have been grown on Al2O3(0001) substrates by using oxygen plasma-assisted molecular beam epitaxy at the low growth temperature of 450°C. The epitaxial films of Co concentration at 0⩽x⩽0.12 are single crystalline, which were examined by reflection high energy electron diffraction and x-ray diffraction. Both of optical transmission spectrum and in situ. x-ray photoelectron spectroscopy studies confirmed the incorporation of Co2+ cations into wurtzite ZnO lattice. Magnetic measurements revealed that the Zn(1−x)CoxO thin films are ferromagnetic with Curie temperature TC above room temperature, and the ferromagnetism shows intrinsic characteristic.
We have carried out a detailed investigation of the magnetism, valence state, and magnetotransport in VSe bulk single crystals, as well as in laminates obtained by mechanical exfoliation. In sharp contrast to the ferromagnetic behavior reported previously, here, no ferromagnetism could be detected for VSe single crystal and laminate from room temperature down to 2 K. Neither did we find the Curie paramagnetism expected due to the 3d odd-electronic configuration of covalent V ions. Rather, intrinsic VSe is a non-magnetic alloy without local moment. Only a weak paramagnetic contribution introduced by defects is noticeable below 50 K. A weak localization effect due to defects was also observed in VSe single crystals for the first time.
Nitrate electrocatalytic reduction (NO3RR) for ammonia production is a promising strategy to close the N‐cycle from nitration contamination, as well as an alternative to the Haber–Bosch process with less energy consumption and carbon dioxide release. However, current long‐term stability of NO3RR catalysts is usually tens of hours, far from the requirements for industrialization. Here, symmetry‐broken Cusingle‐atom catalysts are designed, and the catalytic activity is retained after operation for more than 2000 h, while an average ammonia production rate of 27.84 mg h−1 cm−2 at an industrial level current density of 366 mA cm−2 is achieved, obtaining a good balance between catalytic activity and long‐term stability. Coordination symmetry breaking is achieved by embedding one Cu atom in graphene nanosheets with two N and two O atoms in the cis‐configuration, effectively lowering the coordination symmetry, rendering the active site more polar, and accumulating more NO3− near the electrocatalyst surface. Additionally, the cis‐coordination splits the Cu 3d orbitals, which generates an orbital‐symmetry‐matched π‐complex of the key intermediate *ONH and reduces the energy barrier, compared with the σ‐complex generated with other catalysts. These results reveal the critical role of coordination symmetry in single‐atom catalysts, prompting the design of more coordination‐symmetry‐broken electrocatalysts toward possible industrialization.
Lead halide perovskites recently emerged as promising optoelectronic materials, however moisture instability and the toxicity of Pb and hinder their further application in humidity sensing. Substitution of Pb could cure...
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