444 research outputs found
Holographic Superconductor on Q-lattice
We construct the simplest gravitational dual model of a superconductor on
Q-lattices. We analyze the condition for the existence of a critical
temperature at which the charged scalar field will condense. In contrast to the
holographic superconductor on ionic lattices, the presence of Q-lattices will
suppress the condensate of the scalar field and lower the critical temperature.
In particular, when the Q-lattice background is dual to a deep insulating
phase, the condensation would never occur for some small charges. Furthermore,
we numerically compute the optical conductivity in the superconducting regime.
It turns out that the presence of Q-lattice does not remove the pole in the
imaginary part of the conductivity, ensuring the appearance of a delta function
in the real part. We also evaluate the gap which in general depends on the
charge of the scalar field as well as the Q-lattice parameters. Nevertheless,
when the charge of the scalar field is relatively large and approaches the
probe limit, the gap becomes universal with which is
consistent with the result for conventional holographic superconductors.Comment: 20 pages, version to appear in JHE
SFCNeXt: a simple fully convolutional network for effective brain age estimation with small sample size
Deep neural networks (DNN) have been designed to predict the chronological
age of a healthy brain from T1-weighted magnetic resonance images (T1 MRIs),
and the predicted brain age could serve as a valuable biomarker for the early
detection of development-related or aging-related disorders. Recent DNN models
for brain age estimations usually rely too much on large sample sizes and
complex network structures for multi-stage feature refinement. However, in
clinical application scenarios, researchers usually cannot obtain thousands or
tens of thousands of MRIs in each data center for thorough training of these
complex models. This paper proposes a simple fully convolutional network
(SFCNeXt) for brain age estimation in small-sized cohorts with biased age
distributions. The SFCNeXt consists of Single Pathway Encoded ConvNeXt (SPEC)
and Hybrid Ranking Loss (HRL), aiming to estimate brain ages in a lightweight
way with a sufficient exploration of MRI, age, and ranking features of each
batch of subjects. Experimental results demonstrate the superiority and
efficiency of our approach.Comment: This paper has been accepted by IEEE ISBI 202
Convolutional Neural Networks for Crystal Material Property Prediction Using Hybrid Orbital-Field Matrix and Magpie Descriptors
Computational prediction of crystal materials properties can help to do large-scale in-silicon screening. Recent studies of material informatics have focused on expert design of multi-dimensional interpretable material descriptors/features. However, successes of deep learning such as Convolutional Neural Networks (CNN) in image recognition and speech recognition have demonstrated their automated feature extraction capability to effectively capture the characteristics of the data and achieve superior prediction performance. Here, we propose CNN-OFM-Magpie, a CNN model with OFM (Orbital-field Matrix) and Magpie descriptors to predict the formation energy of 4030 crystal material by exploiting the complementarity of two-dimensional OFM features and Magpie features. Experiments showed that our method achieves better performance than conventional regression algorithms such as support vector machines and Random Forest. It is also better than CNN models using only the OFM features, the Magpie features, or the basic one-hot encodings. This demonstrates the advantages of CNN and feature fusion for materials property prediction. Finally, we visualized the two-dimensional OFM descriptors and analyzed the features extracted by the CNN to obtain greater understanding of the CNN-OFM model
Computational Screening of New Perovskite Materials Using Transfer Learning and Deep Learning
As one of the most studied materials, perovskites exhibit a wealth of superior properties that lead to diverse applications. Computational prediction of novel stable perovskite structures has big potential in the discovery of new materials for solar panels, superconductors, thermal electric, and catalytic materials, etc. By addressing one of the key obstacles of machine learning based materials discovery, the lack of sufficient training data, this paper proposes a transfer learning based approach that exploits the high accuracy of the machine learning model trained with physics-informed structural and elemental descriptors. This gradient boosting regressor model (the transfer learning model) allows us to predict the formation energy with sufficient precision of a large number of materials of which only the structural information is available. The enlarged training set is then used to train a convolutional neural network model (the screening model) with the generic Magpie elemental features with high prediction power. Extensive experiments demonstrate the superior performance of our transfer learning model and screening model compared to the baseline models. We then applied the screening model to filter out promising new perovskite materials out of 21,316 hypothetical perovskite structures with a large portion of them confirmed by existing literature
Cross-language differences in the brain network subserving intelligible speech
SIGNIFICANCE: Language processing is generally left hemisphere dominant. However, whether the interactions among the typical left hemispheric language regions differ across different languages is largely unknown. An ideal method to address this question is modeling cortical interactions across language groups, but this is usually constrained by the model space with the prior hypothesis due to massive computation demands. With cloud-computing, we used functional MRI dynamic causal modeling analysis to compare more than 4,000 models of cortical dynamics among critical language regions in the temporal and frontal cortex, established the bias-free information flow maps that were shared or specific for processing intelligible speech in Chinese and English, and revealed the neural dynamics between the left and right hemispheres in Chinese speech comprehension.
ABSTRACT: How is language processed in the brain by native speakers of different languages? Is there one brain system for all languages or are different languages subserved by different brain systems? The first view emphasizes commonality, whereas the second emphasizes specificity. We investigated the cortical dynamics involved in processing two very diverse languages: a tonal language (Chinese) and a nontonal language (English). We used functional MRI and dynamic causal modeling analysis to compute and compare brain network models exhaustively with all possible connections among nodes of language regions in temporal and frontal cortex and found that the information flow from the posterior to anterior portions of the temporal cortex was commonly shared by Chinese and English speakers during speech comprehension, whereas the inferior frontal gyrus received neural signals from the left posterior portion of the temporal cortex in English speakers and from the bilateral anterior portion of the temporal cortex in Chinese speakers. Our results revealed that, although speech processing is largely carried out in the common left hemisphere classical language areas (Broca’s and Wernicke’s areas) and anterior temporal cortex, speech comprehension across different language groups depends on how these brain regions interact with each other. Moreover, the right anterior temporal cortex, which is crucial for tone processing, is equally important as its left homolog, the left anterior temporal cortex, in modulating the cortical dynamics in tone language comprehension. The current study pinpoints the importance of the bilateral anterior temporal cortex in language comprehension that is downplayed or even ignored by popular contemporary models of speech comprehension
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