117 research outputs found
Coagulation Behavior of Aluminum Salts in Eutrophic Water:Â Significance of Al13Species and pH Control
The coagulation behavior of aluminum salts in a eutrophic source water was investigated from the viewpoint of Al(III) hydrolysis species transformation. Particular emphasis was paid to the coagulation effect of Al-13 species on removing particles and organic matter. The coagulation behavior of Al coagulants with different basicities was examined through jar tests and hydrolyzed Al(III) speciation distribution characterization in the coagulation process. The results showed that the coagulation efficiency of Al coagulants positively correlated with the content of Al-13 in the coagulation process rather than in the initial coagulants. Aluminum chloride (AlCl3) was more effective than polyaluminum chloride (PACT) in removing turbidity and dissolved organic matter in eutrophic water because AlCl3 could not only generate Al-13 species but also function as a pH control agent in the coagulation process. The solid-state Al-27 NMR spectra revealed that the precipitates formed from AlCl3 and PACT were significantly different and proved that the preformed Al-13 polymer was more stable than the in situ formed one during the coagulation process. Through regulating Al speciation, pH control could improve the coagulation process especially in DOC removal, and AlCl3 benefited most from pH control
Timing the Transient Execution: A New Side-Channel Attack on Intel CPUs
The transient execution attack is a type of attack leveraging the
vulnerability of modern CPU optimization technologies. New attacks surface
rapidly. The side-channel is a key part of transient execution attacks to leak
data. In this work, we discover a vulnerability that the change of the EFLAGS
register in transient execution may have a side effect on the Jcc (jump on
condition code) instruction after it in Intel CPUs. Based on our discovery, we
propose a new side-channel attack that leverages the timing of both transient
execution and Jcc instructions to deliver data. This attack encodes secret data
to the change of register which makes the execution time of context slightly
slower, which can be measured by the attacker to decode data. This attack
doesn't rely on the cache system and doesn't need to reset the EFLAGS register
manually to its initial state before the attack, which may make it more
difficult to detect or mitigate. We implemented this side-channel on machines
with Intel Core i7-6700, i7-7700, and i9-10980XE CPUs. In the first two
processors, we combined it as the side-channel of the Meltdown attack, which
could achieve 100\% success leaking rate. We evaluate and discuss potential
defenses against the attack. Our contributions include discovering security
vulnerabilities in the implementation of Jcc instructions and EFLAGS register
and proposing a new side-channel attack that does not rely on the cache system
MPprimer: a program for reliable multiplex PCR primer design
<p>Abstract</p> <p>Background</p> <p>Multiplex PCR, defined as the simultaneous amplification of multiple regions of a DNA template or multiple DNA templates using more than one primer set (comprising a forward primer and a reverse primer) in one tube, has been widely used in diagnostic applications of clinical and environmental microbiology studies. However, primer design for multiplex PCR is still a challenging problem and several factors need to be considered. These problems include mis-priming due to nonspecific binding to non-target DNA templates, primer dimerization, and the inability to separate and purify DNA amplicons with similar electrophoretic mobility.</p> <p>Results</p> <p>A program named MPprimer was developed to help users for reliable multiplex PCR primer design. It employs the widely used primer design program Primer3 and the primer specificity evaluation program MFEprimer to design and evaluate the candidate primers based on genomic or transcript DNA database, followed by careful examination to avoid primer dimerization. The graph-expanding algorithm derived from the greedy algorithm was used to determine the optimal primer set combinations (PSCs) for multiplex PCR assay. In addition, MPprimer provides a virtual electrophotogram to help users choose the best PSC. The experimental validation from 2× to 5× plex PCR demonstrates the reliability of MPprimer. As another example, MPprimer is able to design the multiplex PCR primers for DMD (dystrophin gene which caused Duchenne Muscular Dystrophy), which has 79 exons, for 20×, 20×, 20×, 14×, and 5× plex PCR reactions in five tubes to detect underlying exon deletions.</p> <p>Conclusions</p> <p>MPprimer is a valuable tool for designing specific, non-dimerizing primer set combinations with constrained amplicons size for multiplex PCR assays.</p
Online Streaming Video Super-Resolution with Convolutional Look-Up Table
Online video streaming has fundamental limitations on the transmission
bandwidth and computational capacity and super-resolution is a promising
potential solution. However, applying existing video super-resolution methods
to online streaming is non-trivial. Existing video codecs and streaming
protocols (\eg, WebRTC) dynamically change the video quality both spatially and
temporally, which leads to diverse and dynamic degradations. Furthermore,
online streaming has a strict requirement for latency that most existing
methods are less applicable. As a result, this paper focuses on the rarely
exploited problem setting of online streaming video super resolution. To
facilitate the research on this problem, a new benchmark dataset named
LDV-WebRTC is constructed based on a real-world online streaming system.
Leveraging the new benchmark dataset, we proposed a novel method specifically
for online video streaming, which contains a convolution and Look-Up Table
(LUT) hybrid model to achieve better performance-latency trade-off. To tackle
the changing degradations, we propose a mixture-of-expert-LUT module, where a
set of LUT specialized in different degradations are built and adaptively
combined to handle different degradations. Experiments show our method achieves
720P video SR around 100 FPS, while significantly outperforms existing
LUT-based methods and offers competitive performance compared to efficient
CNN-based methods
Virtual sensor array based on MXene for selective detections of VOCs
Two-dimensional transition metal carbides/nitrides, known as MXenes, have recently received significant attention for gas sensing applications. However, MXenes have strong adsorption to many types of volatile organic compounds (VOCs), and therefore gas sensors based on MXenes generally have low selectivity and poor performance in mixtures of VOCs due to cross-sensitivity issues. Herein, we developed a Ti3C2Tx-based virtual sensor array (VSA) which allows both highly accurate detection and identification of different VOCs, as well as concentration prediction of the target VOC in variable backgrounds. The VSA’s responses from the broadband impedance spectra create a unique fingerprint of each VOC without a need for changing temperatures. Based on the methodologies of principal component analysis and linear discrimination analysis, we demonstrate highly accurate identifications for different types of VOCs and mixtures using this MXene based VSA. Furthermore, we demonstrate an accuracy of 93.2% for the prediction of ethanol concentrations in the presence of different concentrations of water and methanol. The high level of identification and concentration prediction shows a great potential of MXene based VSA for detection of VOCs of interest in the presence of known and unknown interferences
High Resolution and Fast Response of Humidity Sensor Based on AlN Cantilever with Two Groups of Segmented Electrodes
Resonant cantilever based on piezoelectric materials is one of the most promising platforms for real-time humidity sensing. In this letter, we propose a humidity sensor based on an AlN piezoelectric microcantilever with a high-order resonant mode and a sensing layer of MoS2. The top electrode of cantilever is designed into two groups of segmented electrodes in order to achieve a high intensity of the resonance peak of the cantilever resonator operated at a high-order mode. Compared with the humidity sensor based on a standard cantilever with the same dimension, the sensitivity of the newly proposed humidity sensor is increased from 5.99 to 778 Hz/%RH when the humidity is about 80%RH. The resolution is increased from 0.21%RH to 0.025%RH because of the improvement of the ratio of sensitivity to noise, which cannot be achieved simply by increasing the frequency. The sensor shows a low hysteresis (5.8%) in a wide humidity sensing range from 10%RH to 90%RH. Moreover, the proposed humidity sensor has good short-term repeatability, fast response (0.6 s) and recovery (8 s) to humidity changes, indicating its great potential for fast-response detection
A flexible virtual sensor array based on laser-induced graphene and MXene for detecting volatile organic compounds in human breath
Detecting volatile organic compounds (VOCs) in human breath is critical for the early diagnosis of diseases. Good selectivity of VOC sensors is crucial for the accurate analysis of VOC biomarkers in human breath, which consists of more than 200 types of VOCs. In this paper, a flexible virtual sensor array (FVSA) was proposed based on a sensing layer of MXene and laser-induced graphene interdigital electrodes (LIG-IDEs) for detecting VOCs in exhaled human breath. The fabrication of LIG-IDEs avoids the costly and complicated procedures required for the preparation of traditional IDEs. The FVSA's responses of multiple parameters help build a unique fingerprint for each VOC, without a need for changing the temperature of the sensing element, which is commonly used in the VSA of semiconductor VOC sensors. Based on machine learning algorithms, we have achieved highly precise recognition of different VOCs and mixtures and accurate prediction (accuracy of 89.1%) of the objective VOC's concentration in variable backgrounds using this proposed FVSA. Moreover, a blind analysis validates the capacity of the FVSA to identify alcohol content in human breath with an accuracy of 88.9% using breath samples from volunteers before and after alcohol consumption. These results show that the proposed FVSA is promising for the detection of VOC biomarkers in human exhaled breath and early diagnosis of diseases
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