106 research outputs found
Modeling and simulation in supersonic three-temperature carbon dioxide turbulent channel flow
This paper pioneers the direct numerical simulation (DNS) and physical
analysis in supersonic three-temperature carbon dioxide (CO2) turbulent channel
flow. CO2 is a linear and symmetric triatomic molecular, with the thermal
non-equilibrium three-temperature effects arising from the interactions among
translational, rotational and vibrational modes under room temperature. Thus,
the rotational and vibrational modes of CO2 are addressed. Thermal
non-equilibrium effect of CO2 has been modeled in an extended three-temperature
BGK-type model, with the calibrated translational, rotational and vibrational
relaxation time. To solve the extended BGK-type equation accurately and
robustly, non-equilibrium high-accuracy gas-kinetic scheme is proposed within
the well-established two-stage fourth-order framework. Compared with the
one-temperature supersonic turbulent channel flow, supersonic three-temperature
CO2 turbulence enlarges the ensemble heat transfer of the wall by approximate
20%, and slightly decreases the ensemble frictional force. The ensemble density
and temperature fields are greatly affected, and there is little change in Van
Driest transformation of streamwise velocity. The thermal non-equilibrium
three-temperature effects of CO2 also suppress the peak of normalized
root-mean-square of density and temperature, normalized turbulent intensities
and Reynolds stress. The vibrational modes of CO2 behave quite differently with
rotational and translational modes. Compared with the vibrational temperature
fields, the rotational temperature fields have the higher similarity with
translational temperature fields, especially in temperature amplitude. Current
thermal non-equilibrium models, high-accuracy DNS and physical analysis in
supersonic CO2 turbulent flow can act as the benchmark for the long-term
applicability of compressible CO2 turbulence.Comment: Carbon dioxide flow, Vibrational modes, Three-temperature effects,
Supersonic turbulent channel flow
Interactions between inertial particles and shocklets in compressible turbulent flow
Numerical simulations are conducted to investigate the dynamics of inertial particles being passively convected in a compressible homogeneous turbulence. Heavy and light particles exhibit very different types of non-uniform distributions due to their different behaviors near shocklets. Because of the relaxation nature of the Stokes drag, the heavy particles are decelerated mainly at downstream adjacent to the shocklets and form high-number-density clouds. The light particles are strongly decelerated by the added-mass effect and stay in the compression region for a relatively long time period. They cluster into thin filament structures near shocklets
Fructose metabolism and its role in pig production: A mini-review
Epidemiological studies have shown that excessive intake of fructose is largely responsible for the increasing incidence of non-alcoholic fatty liver, obesity, and diabetes. However, depending on the amount of fructose consumption from diet, the metabolic role of fructose is controversial. Recently, there have been increasing studies reporting that diets low in fructose expand the surface area of the gut and increase nutrient absorption in mouse model, which is widely used in fructose-related studies. However, excessive fructose consumption spills over from the small intestine into the liver for steatosis and increases the risk of colon cancer. Therefore, suitable animal models may be needed to study fructose-induced metabolic changes. Along with its use in global meat production, pig is well-known as a biomedical model with an advantage over murine and other animal models as it has similar nutrition and metabolism to human in anatomical and physiological aspects. Here, we review the characteristics and metabolism of fructose and summarize observations of fructose in pig reproduction, growth, and development as well as acting as a human biomedical model. This review highlights fructose metabolism from the intestine to the blood cycle and presents the critical role of fructose in pig, which could provide new strategies for curbing human metabolic diseases and promoting pig production
Carotid Atherosclerosis Detected by Ultrasonography: A National Cross‐Sectional Study
Background: Carotid atherosclerosis (CA) is a reflector of generalized atherosclerosis that is associated with systemic vascular disease. Data are limited on the epidemiology of carotid lesions in a large, nationally representative population sample. We aimed to evaluate the prevalence of CA detected by carotid ultrasonography and related risk factors based on a national survey in China. Methods and Results: A total of 107 095 residents aged ≥40 years from the China National Stroke Prevention Project underwent carotid ultrasound examination. Participants with carotid endarterectomy or carotid stenting and those with stroke or coronary heart disease were excluded. Data from 84 880 participants were included in the analysis. CA was defined as increased intima–media thickness (IMT) ≥1 mm or presence of plaques. Of the 84 880 participants, 46.4% were men, and the mean age was 60.7±10.3 years. The standardized prevalence of CA was 36.2% overall, increased with age, and was higher in men than in women. Prevalence of CA was higher among participants living in rural areas than in urban areas. Approximately 26.5% of participants had increased IMT, and 13.9% presented plaques. There was an age‐related increase in participants with increased IMT, plaque presence, and stenosis. In multiple logistic regression analysis, older age, male sex, residence in rural areas, smoking, alcohol consumption, physical inactivity, obesity, hypertension, diabetes mellitus, and dyslipidemia were associated with CA. Conclusions: CA was highly prevalent in a middle‐aged and older Chinese population. This result shows the potential clinical importance of focusing on primary prevention of atherosclerosis progression
Precursors and Pathways Leading to Enhanced Secondary Organic Aerosol Formation during Severe Haze Episodes
Publisher Copyright: © 2021 American Chemical SocietyMolecular analyses help to investigate the key precursors and chemical processes of secondary organic aerosol (SOA) formation. We obtained the sources and molecular compositions of organic aerosol in PM2.5in winter in Beijing by online and offline mass spectrometer measurements. Photochemical and aqueous processing were both involved in producing SOA during the haze events. Aromatics, isoprene, long-chain alkanes or alkenes, and carbonyls such as glyoxal and methylglyoxal were all important precursors. The enhanced SOA formation during the severe haze event was predominantly contributed by aqueous processing that was promoted by elevated amounts of aerosol water for which multifunctional organic nitrates contributed the most followed by organic compounds having four oxygen atoms in their formulae. The latter included dicarboxylic acids and various oxidation products from isoprene and aromatics as well as products or oligomers from methylglyoxal aqueous uptake. Nitrated phenols, organosulfates, and methanesulfonic acid were also important SOA products but their contributions to the elevated SOA mass during the severe haze event were minor. Our results highlight the importance of reducing nitrogen oxides and nitrate for future SOA control. Additionally, the formation of highly oxygenated long-chain molecules with a low degree of unsaturation in polluted urban environments requires further research.Peer reviewe
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