422 research outputs found
A probable Milli-Parsec Supermassive Binary Black Hole in the Nearest Quasar Mrk 231
Supermassive binary black holes (BBHs) are unavoidable products of galaxy
mergers and are expected to exist in the cores of many quasars. Great effort
has been made during the past several decades to search for BBHs among quasars;
however, observational evidence for BBHs remains elusive and ambiguous, which
is difficult to reconcile with theoretical expectations. In this paper, we show
that the distinct optical-to-UV spectrum of Mrk 231 can be well interpreted as
emission from accretion flows onto a BBH, with a semimajor axis of ~590AU and
an orbital period of ~1.2 year. The flat optical and UV continua are mainly
emitted from a circumbinary disk and a mini-disk around the secondary black
hole (BH), respectively; and the observed sharp drop off and flux deficit at
wavelength lambda ~ 4000-2500 Angstrom is due to a gap (or hole) opened by the
secondary BH migrating within the circumbinary disk. If confirmed by future
observations, this BBH will provide a unique laboratory to study the interplay
between BBHs and accretion flows onto them. Our result also demonstrates a new
method to find sub-parsec scale BBHs by searching for deficits in the
optical-to-UV continuum among the spectra of quasars.Comment: a typo in equation (2) and also in equation (5) of the Appendix is
fixed; 9 pages, 7 figure
Uncertainty Estimation on Sequential Labeling via Uncertainty Transmission
Sequential labeling is a task predicting labels for each token in a sequence,
such as Named Entity Recognition (NER). NER tasks aim to extract entities and
predict their labels given a text, which is important in information
extraction. Although previous works have shown great progress in improving NER
performance, uncertainty estimation on NER (UE-NER) is still underexplored but
essential. This work focuses on UE-NER, which aims to estimate uncertainty
scores for the NER predictions. Previous uncertainty estimation models often
overlook two unique characteristics of NER: the connection between entities
(i.e., one entity embedding is learned based on the other ones) and wrong span
cases in the entity extraction subtask. Therefore, we propose a Sequential
Labeling Posterior Network (SLPN) to estimate uncertainty scores for the
extracted entities, considering uncertainty transmitted from other tokens.
Moreover, we have defined an evaluation strategy to address the specificity of
wrong-span cases. Our SLPN has achieved significant improvements on two
datasets, such as a 5.54-point improvement in AUPR on the MIT-Restaurant
dataset.Comment: 11 pages, 2 figure
Continuous-Time Graph Learning for Cascade Popularity Prediction
Information propagation on social networks could be modeled as cascades, and
many efforts have been made to predict the future popularity of cascades.
However, most of the existing research treats a cascade as an individual
sequence. Actually, the cascades might be correlated with each other due to the
shared users or similar topics. Moreover, the preferences of users and
semantics of a cascade are usually continuously evolving over time. In this
paper, we propose a continuous-time graph learning method for cascade
popularity prediction, which first connects different cascades via a universal
sequence of user-cascade and user-user interactions and then chronologically
learns on the sequence by maintaining the dynamic states of users and cascades.
Specifically, for each interaction, we present an evolution learning module to
continuously update the dynamic states of the related users and cascade based
on their currently encoded messages and previous dynamic states. We also devise
a cascade representation learning component to embed the temporal information
and structural information carried by the cascade. Experiments on real-world
datasets demonstrate the superiority and rationality of our approach.Comment: 9 pages, 5 figures, IJCAI 202
Structural basis for DNMT3A-mediated de novo DNA methylation.
DNA methylation by de novo DNA methyltransferases 3A (DNMT3A) and 3B (DNMT3B) at cytosines is essential for genome regulation and development. Dysregulation of this process is implicated in various diseases, notably cancer. However, the mechanisms underlying DNMT3 substrate recognition and enzymatic specificity remain elusive. Here we report a 2.65-ångström crystal structure of the DNMT3A-DNMT3L-DNA complex in which two DNMT3A monomers simultaneously attack two cytosine-phosphate-guanine (CpG) dinucleotides, with the target sites separated by 14 base pairs within the same DNA duplex. The DNMT3A-DNA interaction involves a target recognition domain, a catalytic loop, and DNMT3A homodimeric interface. Arg836 of the target recognition domain makes crucial contacts with CpG, ensuring DNMT3A enzymatic preference towards CpG sites in cells. Haematological cancer-associated somatic mutations of the substrate-binding residues decrease DNMT3A activity, induce CpG hypomethylation, and promote transformation of haematopoietic cells. Together, our study reveals the mechanistic basis for DNMT3A-mediated DNA methylation and establishes its aetiological link to human disease
Design, synthesis and antitubercular evaluation of benzothiazinones containing a piperidine moiety
We herein report the design and synthesis of benzothiazinones containing a piperidine moiety as new antitubercular agents based on the structure feature of IMB-ZR-1 discovered in our lab. Some of them were found to have good in vitro activity (MIC < 1 μg/mL) against drug-susceptible Mycobacterium tuberculosis H37RV strain. After two set of modifications, compound 2i were found to display comparable in vitro anti-TB activity (MIC < 0.016 μg/mL) to PBTZ169 against drug-sensitive and resistant mycobacterium tuberculosis strains. Compound 2i also showed acceptable PK profiles. Studies to determine PK profiles in lung and in vivo efficacy of 2i are currently under way
Experimental quantum advantage with quantum coupon collector
An increasing number of communication and computational schemes with quantum
advantages have recently been proposed, which implies that quantum technology
has fertile application prospects. However, demonstrating these schemes
experimentally continues to be a central challenge because of the difficulty in
preparing high-dimensional states or highly entangled states. In this study, we
introduce and analyse a quantum coupon collector protocol by employing coherent
states and simple linear optical elements, which was successfully demonstrated
using realistic experimental equipment. We showed that our protocol can
significantly reduce the number of samples needed to learn a specific set
compared with the classical limit of the coupon collector problem. We also
discuss the potential values and expansions of the quantum coupon collector by
constructing a quantum blind box game. The information transmitted by the
proposed game also broke the classical limit. These results strongly prove the
advantages of quantum mechanics in machine learning and communication
complexity.Comment: 10 pages, 3 figures, 3 tables, Accepted by Researc
Experimental Quantum Communication Overcomes the Rate-loss Limit without Global Phase Tracking
Secure key rate (SKR) of point-point quantum key distribution (QKD) is
fundamentally bounded by the rate-loss limit. Recent breakthrough of twin-field
(TF) QKD can overcome this limit and enables long distance quantum
communication, but its implementation necessitates complex global phase
tracking and requires strong phase references which not only add to noise but
also reduce the duty cycle for quantum transmission. Here, we resolve these
shortcomings, and importantly achieve even higher SKRs than TF-QKD, via
implementing an innovative but simpler measurement-device-independent QKD which
realizes repeater-like communication through asynchronous coincidence pairing.
Over 413 and 508 km optical fibers, we achieve finite-size SKRs of 590.61 and
42.64 bit/s, which are respectively 1.80 and 4.08 times of their corresponding
absolute rate limits. Significantly, the SKR at 306 km exceeds 5 kbit/s and
meets the bitrate requirement for live one-time-pad encryption of voice
communication. Our work will bring forward economical and efficient intercity
quantum-secure networks.Comment: 29 pages, 10 figures, 3 table
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