413 research outputs found
An Empirical Relation Between The Large-Scale Magnetic Field And The Dynamical Mass In Galaxies
The origin and evolution of cosmic magnetic fields as well as the influence
of the magnetic fields on the evolution of galaxies are unknown. Though not
without challenges, the dynamo theory can explain the large-scale coherent
magnetic fields which govern galaxies, but observational evidence for the
theory is so far very scarce. Putting together the available data of
non-interacting, non-cluster galaxies with known large-scale magnetic fields,
we find a tight correlation between the integrated polarized flux density,
S(PI), and the rotation speed, v(rot), of galaxies. This leads to an almost
linear correlation between the large-scale magnetic field B and v(rot),
assuming that the number of cosmic ray electrons is proportional to the star
formation rate, and a super-linear correlation assuming equipartition between
magnetic fields and cosmic rays. This correlation cannot be attributed to an
active linear alpha-Omega dynamo, as no correlation holds with global shear or
angular speed. It indicates instead a coupling between the large-scale magnetic
field and the dynamical mass of the galaxies, B ~ M^(0.25-0.4). Hence, faster
rotating and/or more massive galaxies have stronger large-scale magnetic
fields. The observed B-v(rot) correlation shows that the anisotropic turbulent
magnetic field dominates B in fast rotating galaxies as the turbulent magnetic
field, coupled with gas, is enhanced and ordered due to the strong gas
compression and/or local shear in these systems. This study supports an
stationary condition for the large-scale magnetic field as long as the
dynamical mass of galaxies is constant.Comment: 23 pages, 4 figures, accepted for publication in the Astrophysical
Journal Letter
Inversion of droplet aerosol analyzer data for long-term aerosol–cloud interaction measurements
The droplet aerosol analyzer (DAA) was developed to study the influence of
aerosol properties on clouds. It measures the ambient particle size of
individual droplets and interstitial particles, the size of the dry
(residual) particles after the evaporation of water vapor and the number
concentration of the dry (residual) particles. A method was developed for the
evaluation of DAA data to obtain the three-parameter data set: ambient
particle diameter, dry (residual) particle diameter and number concentration.
First results from in-cloud measurements performed on the summit of Mt.
Brocken in Germany are presented. Various aspects of the cloud–aerosol
data set are presented, such as the number concentration of interstitial
particles and cloud droplets, the dry residue particle size distribution,
droplet size distributions, scavenging ratios due to cloud droplet formation
and size-dependent solute concentrations. This data set makes it possible to
study clouds and the influence of the aerosol population on clouds
Short- and long-term stratospheric impact of smoke from the 2019–2020 Australian wildfires
At the end of December 2019 and beginning of 2020,
massive firestorms in Australia formed pyrocumulonimbus clouds (pyroCbs) that
acted like enormous smokestacks, pumping smoke to the upper troposphere and
stratosphere. We study the smoke with data from four satellite-based
sensors: the aerosol observation platforms CALIOP (Cloud-Aerosol Lidar with Orthogonal Polarization), OMPS-LP (Ozone Mapping and Profiler Suite Limb Profiler), and OMPS-NM (Ozone Mapping and Profiler Suite Nadir Mapper) and
water vapor retrievals from MLS (Microwave Limb Sounder). Smoke was lofted to the upper troposphere
and stratosphere during two events and spread almost exclusively within the
extratropics. Smoke from the first event, starting 29Â December, was injected
directly into the stratosphere by pyroCbs, causing a rapid initial increase
in AOD (aerosol optical depth). CALIOP identifies a rapid decline in this stratospheric smoke
(half-life: 10 d), not captured in previous studies of the Australian
fires, indicating photochemical processing of organic aerosol. This decay
rate is in line with model predictions of mid-tropospheric organic aerosol
loss by photolytic removal and is in agreement with our estimates of decay
rates after the North American fires in August 2017. PyroCbs from the second
event, 4Â January, injected small amounts of smoke directly into the
stratosphere. Large amounts of smoke were injected to the upper troposphere,
from where it ascended into the stratosphere during several weeks, forming a
second peak in the aerosol load. Hence, we find that pyroCbs can impact the
stratospheric aerosol load both via direct injection to the stratosphere
and through injection of smoke to the upper troposphere from where the smoke
ascends into the stratosphere. The stratospheric AOD from the second-event
fires decreased more slowly than the AOD from the first event, likely due to a
combination of photolytic loss starting already in the troposphere and
continued supply of smoke from the upper troposphere offsetting the loss
rate. Together these injections yielded a major increase in the aerosol load
for almost 1Â year.</p
Comprehensive screening of genomic and metagenomic data reveals a large diversity of tetracycline resistance genes
Tetracyclines are broad-spectrum antibiotics used to prevent or treat a variety of bacterial infections. Resistance is often mediated through mobile resistance genes, which encode one of the three main mechanisms: active efflux, ribosomal target protection or enzymatic degradation. In the last few decades, a large number of new tetracycline-resistance genes have been discovered in clinical settings. These genes are hypothesized to originate from environmental and commensal bacteria, but the diversity of tetracycline-resistance determinants that have not yet been mobilized into pathogens is unknown. In this study, we aimed to characterize the potential tetracycline resistome by screening genomic and metagenomic data for novel resistance genes. By using probabilistic models, we predicted 1254 unique putative tetracycline resistance genes, representing 195 gene families (<70 % amino acid sequence identity), whereof 164 families had not been described previously. Out of 17 predicted genes selected for experimental verification, 7 induced a resistance phenotype in an Escherichia coli host. Several of the predicted genes were located on mobile genetic elements or in regions that indicated mobility, suggesting that they easily can be shared between bacteria. Furthermore, phylogenetic analysis indicated several events of horizontal gene transfer between bacterial phyla. Our results also suggested that acquired efflux pumps originate from proteobacterial species, while ribosomal protection genes have been mobilized from Firmicutes and Actinobacteria. This study significantly expands the knowledge of known and putatively novel tetracycline resistance genes, their mobility and evolutionary history. The study also provides insights into the unknown resistome and genes that may be encountered in clinical settings in the future
Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008-2010 based on CARIBIC observations
Large volcanic eruptions impact significantly on climate and lead to ozone depletion due to injection of particles and gases into the stratosphere where their residence times are long. In this the composition of volcanic aerosol is an important but inadequately studied factor. Samples of volcanically influenced aerosol were collected following the Kasatochi (Alaska), Sarychev (Russia) and also during the Eyjafjallajökull (Iceland) eruptions in the period 2008–2010. Sampling was conducted by the CARIBIC platform during regular flights at an altitude of 10–12 km as well as during dedicated flights through the volcanic clouds from the eruption of Eyjafjallajökull in spring 2010. Elemental concentrations of the collected aerosol were obtained by acceleratorbased analysis. Aerosol from the Eyjafjallajökull volcanic clouds was identified by high concentrations of sulphur and elements pointing to crustal origin, and confirmed by trajectory analysis. Signatures of volcanic influence were also used to detect volcanic aerosol in stratospheric samples collected following the Sarychev and Kasatochi eruptions. In total it was possible to identify 17 relevant samples collected between 1 and more than 100 days following the eruptions studied. The volcanically influenced aerosol mainly consisted of ash, sulphate and included a carbonaceous component. Samples collected in the volcanic cloud from Eyjafjallajökull were dominated by the ash and sulphate component (~45% each) while samples collected in the tropopause region and LMS mainly consisted of sulphate (50–77 %) and carbon (21–43 %). These fractions were increasing/decreasing with the age of the aerosol. Because of the long observation period, it was possible to analyze the evolution of the relationship between the ash and sulphate components of the volcanic aerosol. From this analysis the residence time (1/e) of sulphur dioxide in the studied volcanic cloud was estimated to be 45±22 days
Composition and evolution of volcanic aerosol from eruptions of Kasatochi, Sarychev and Eyjafjallajökull in 2008-2010 based on CARIBIC observations
Large volcanic eruptions impact significantly on climate and lead to ozone depletion due to injection of particles and gases into the stratosphere where their residence times are long. In this the composition of volcanic aerosol is an important but inadequately studied factor. Samples of volcanically influenced aerosol were collected following the Kasatochi (Alaska), Sarychev (Russia) and also during the Eyjafjallajökull (Iceland) eruptions in the period 2008–2010. Sampling was conducted by the CARIBIC platform during regular flights at an altitude of 10–12 km as well as during dedicated flights through the volcanic clouds from the eruption of Eyjafjallajökull in spring 2010. Elemental concentrations of the collected aerosol were obtained by acceleratorbased analysis. Aerosol from the Eyjafjallajökull volcanic clouds was identified by high concentrations of sulphur and elements pointing to crustal origin, and confirmed by trajectory analysis. Signatures of volcanic influence were also used to detect volcanic aerosol in stratospheric samples collected following the Sarychev and Kasatochi eruptions. In total it was possible to identify 17 relevant samples collected between 1 and more than 100 days following the eruptions studied. The volcanically influenced aerosol mainly consisted of ash, sulphate and included a carbonaceous component. Samples collected in the volcanic cloud from Eyjafjallajökull were dominated by the ash and sulphate component (~45% each) while samples collected in the tropopause region and LMS mainly consisted of sulphate (50–77 %) and carbon (21–43 %). These fractions were increasing/decreasing with the age of the aerosol. Because of the long observation period, it was possible to analyze the evolution of the relationship between the ash and sulphate components of the volcanic aerosol. From this analysis the residence time (1/e) of sulphur dioxide in the studied volcanic cloud was estimated to be 45±22 days
Comparison between CARIBIC Aerosol Samples Analysed by Accelerator-Based Methods and Optical Particle Counter Measurements
Inter-comparison of results from two kinds of aerosol systems in the CARIBIC
(Civil Aircraft for the Regular Investigation of the atmosphere Based on a
Instrument Container) passenger aircraft based observatory, operating during
intercontinental flights at 9–12 km altitude, is presented. Aerosol from
the lowermost stratosphere (LMS), the extra-tropical upper troposphere (UT)
and the tropical mid troposphere (MT) were investigated. Aerosol particle
volume concentration measured with an optical particle counter (OPC) is
compared with analytical results of the sum of masses of all major and
several minor constituents from aerosol samples collected with an impactor.
Analyses were undertaken with the following accelerator-based methods: particle-induced
X-ray emission (PIXE) and particle elastic scattering analysis (PESA). Data
from 48 flights during 1 year are used, leading to a total of 106
individual comparisons. The ratios of the particle volume from the OPC and
the total mass from the analyses were in 84% within a relatively narrow
interval. Data points outside this interval are connected with inlet-related
effects in clouds, large variability in aerosol composition, particle size
distribution effects and some cases of non-ideal sampling. Overall, the
comparison of these two CARIBIC measurements based on vastly different
methods show good agreement, implying that the chemical and size information
can be combined in studies of the MT/UT/LMS aerosol
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