198 research outputs found
Combinatorics of double loop suspensions, evaluation maps and Cohen groups
We reformulate Milgram's model of a double loop suspension in terms of a
preoperad of posets, each stage of which is the poset of all ordered partitions
of a finite set. Using this model, we give a combinatorial model for the
evaluation map and use it to study the Cohen representation for the group of
homotopy classes of maps between double loop suspensions. Demonstrating the
general theory, we recover Wu's shuffle relations and further provide a type of
secondary relations in Cohen groups by using Toda brackets. In particular, we
prove certain maps are null-homotopic by combining our relations and the
classical James-Hopf invariants.Comment: 37 pages; to appear in Journal of the Mathematical Society of Japa
Achieving high strength and ductility in magnesium alloys via densely hierarchical double contraction nanotwins.
Light-weight magnesium alloys with high strength are especially desirable for the applications in transportation, aerospace, electronic components, and implants owing to their high stiffness, abundant raw materials, and environmental friendliness. Unfortunately, conventional strengthening methods mainly involve the formation of internal defects, in which particles and grain boundaries prohibit dislocation motion as well as compromise ductility invariably. Herein, we report a novel strategy for simultaneously achieving high specific yield strength (∼160 kN m kg-1) and good elongation (∼23.6%) in a duplex magnesium alloy containing 8 wt % lithium at room temperature, based on the introduction of densely hierarchical {1011}-{101 1} double contraction nanotwins (DCTWs) and full-coherent hexagonal close-packed (hcp) particles in twin boundaries by ultrahigh pressure technique. These hierarchical nanoscaled DCTWs with stable interface characteristics not only bestow a large fraction of twin interface but also form interlaced continuous grids, hindering possible dislocation motions. Meanwhile, orderly aggregated particles offer supplemental pinning effect for overcoming latent softening roles of twin interface movement and detwinning process. The processes lead to a concomitant but unusual situation where double contraction twinning strengthens rather than weakens magnesium alloys. Those cutting-edge results provide underlying insights toward designing alternative and more innovative hcp-type structural materials with superior mechanical properties
Phosphorus-doped porous carbons as efficient electrocatalysts for oxygen reduction
Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG geförderten) Allianz- bzw. Nationallizenz frei zugänglich.This publication is with permission of the rights owner freely accessible due to an Alliance licence and a national licence (funded by the DFG, German Research Foundation) respectively.Efficient electrocatalysts for the oxygen reduction reaction (ORR) play a critical role in the performance of fuel cells and metal–air batteries. In this study, we report a facile synthesis of phosphorus (P)-doped porous carbon as a highly active electrocatalyst for the ORR. Phosphorus-doped porous carbon was prepared by simultaneous doping and activation of carbon with phosphoric acid (H3PO4) in the presence of Co. Both phosphorus and cobalt were found to play significant roles in improving the catalytic activity of carbon for the ORR. The as-prepared phosphorus-doped porous carbon exhibited considerable catalytic activity for the ORR as evidenced by rotating ring-disk electrode studies. At the same mass loading, the Tafel slope of phosphorus-doped porous carbon electrocatalysts is comparable to that of the commercial Pt/C catalysts (20 wt% Pt on Vulcan XC-72, Johnson Matthey) with stability superior to Pt/C in alkaline solutions
Collaborative Noisy Label Cleaner: Learning Scene-aware Trailers for Multi-modal Highlight Detection in Movies
Movie highlights stand out of the screenplay for efficient browsing and play
a crucial role on social media platforms. Based on existing efforts, this work
has two observations: (1) For different annotators, labeling highlight has
uncertainty, which leads to inaccurate and time-consuming annotations. (2)
Besides previous supervised or unsupervised settings, some existing video
corpora can be useful, e.g., trailers, but they are often noisy and incomplete
to cover the full highlights. In this work, we study a more practical and
promising setting, i.e., reformulating highlight detection as "learning with
noisy labels". This setting does not require time-consuming manual annotations
and can fully utilize existing abundant video corpora. First, based on movie
trailers, we leverage scene segmentation to obtain complete shots, which are
regarded as noisy labels. Then, we propose a Collaborative noisy Label Cleaner
(CLC) framework to learn from noisy highlight moments. CLC consists of two
modules: augmented cross-propagation (ACP) and multi-modality cleaning (MMC).
The former aims to exploit the closely related audio-visual signals and fuse
them to learn unified multi-modal representations. The latter aims to achieve
cleaner highlight labels by observing the changes in losses among different
modalities. To verify the effectiveness of CLC, we further collect a
large-scale highlight dataset named MovieLights. Comprehensive experiments on
MovieLights and YouTube Highlights datasets demonstrate the effectiveness of
our approach. Code has been made available at:
https://github.com/TencentYoutuResearch/HighlightDetection-CLCComment: Accepted to CVPR202
The role of IMP dehydrogenase 2 in Inauhzin-induced ribosomal stress
The ‘ribosomal stress (RS)-p53 pathway’ is triggered by any stressor or genetic alteration that disrupts ribosomal biogenesis, and mediated by several ribosomal proteins (RPs), such as RPL11 and RPL5, which inhibit MDM2 and activate p53. Inosine monophosphate (IMP) dehydrogenase 2 (IMPDH2) is a rate-limiting enzyme in de novo guanine nucleotide biosynthesis and crucial for maintaining cellular guanine deoxy- and ribonucleotide pools needed for DNA and RNA synthesis. It is highly expressed in many malignancies. We previously showed that inhibition of IMPDH2 leads to p53 activation by causing RS. Surprisingly, our current study reveals that Inauzhin (INZ), a novel non-genotoxic p53 activator by inhibiting SIRT1, can also inhibit cellular IMPDH2 activity, and reduce the levels of cellular GTP and GTP-binding nucleostemin that is essential for rRNA processing. Consequently, INZ induces RS and the RPL11/RPL5-MDM2 interaction, activating p53. These results support the new notion that INZ suppresses cancer cell growth by dually targeting SIRT1 and IMPDH2
Hemodialysis catheter-related infection caused by Pannonibacter phragmitetus: a rare case report in China
Pannonibacter phragmitetus (P. phragmitetus) is rarely related with human disease. We reported a case of catheter-related infection caused by P. phragmitetus in a 68-year-old woman on hemodialysis. The patient developed recurrent fever during hemodialysis and blood cultures were positive for P. phragmitetus. The patient’s body temperature returned to normal after intravenous cefoperazone/sulbactam treatment, and the hemodialysis catheter was locked with gentamicin and urokinase. The potential anti-infective treatment against P. phragmitetus was discussed
Coherent interface strengthening of ultrahigh pressure heat-treated Mg-Li-Y alloys.
Achieving good strength-ductility of Mg alloys has always been a crucial issue for the widespread applications of Mg-based structural materials. Herein, an unexpected double-stage strengthening phenomenon was discovered in Mg-8Li-1Y(wt.%) alloys through high pressure (6 GPa) heat treatments over a range of 700-1300°C. Attractively, the yield strength values are improved remarkably without losing their ductility. The low temperature strengthening mechanism is mainly driven by the formation of large-volume nanoscale contraction twins. In contrast, the high-temperature strengthening reason is ascribed to the presence of densely nano-sized stacking faults. Both coherent interfaces contribute effectively to high mechanical strength without any tradeoff in ductility
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