1,203 research outputs found
On the propagation of the highest energy cosmic ray nuclei
We study the propagation of ultra-high energy cosmic ray nuclei through the
background of cosmic microwave and intergalactic infrared photons, using recent
re-estimates for the density of the last ones. We perform a detailed Monte
Carlo simulation to follow the disintegration histories of nuclei starting as
Fe and reaching the Earth from extragalactic sources. We obtain the maximum
energies of the arriving nuclear fragments as well as the mass composition as a
function of the distance traveled. Cosmic rays with energies in excess of
eV cannot originate from Fe nuclei produced in sources beyond
10 Mpc.Comment: 8 page
On the disintegration of cosmic ray nuclei by solar photons
We discuss in detail the possibility of observing pairs of simultaneous
parallel air showers produced by the fragments of cosmic ray nuclei which
disintegrated in collisions with solar photons. We consider scenarios with
different cosmic ray compositions, exploring the predicted rates for existing
and planned detectors and looking for methods to extract information on the
initial composition from the characteristics of the signal. In particular, we
find that fluorescence detectors, such as HiRes or the Telescope Array, due to
their low threshold ( eV) and large area () may
observe several events per year if cosmic rays at those energies are indeed
heavy nuclei. The possibility of exploiting the angular orientation of the
plane containing the two showers to further constrain the cosmic ray
composition is also discussed.Comment: 15 page
Comment on "On the Origin of the Highest Energy Cosmic Rays"
We show that the photodisintegration of heavy cosmic ray nuclei with energies
above 10^20 eV is dominated by interactions with photons from the cosmic
microwave background radiation, rather than from infrared ones. This implies
that the observed air shower events with energies 2-3 10^20 eV cannot originate
from Fe nuclei coming from distances beyond 10 MpcComment: 1 page, 2 figure
Controls on the fate and transport of methylmercury in a boreal headwater catchment, northwestern Ontario, Canada
International audienceThe fate and transport of methylmercury (MeHg) were studied in a small boreal catchment. Hydrological processes largely govern the magnitude of the flux of MeHg. Seasonal and inter-annual variability in hydrology produce variable source strengths of MeHg throughout the catchment. The mass flux of MeHg within, and from the catchment is dependent on the mass flux of water and the relative placement of landscape units in the catchment hydrological cascade. Hydrology also governs the maintenance of the methylating environments in the catchment. Specifically, hydrological processes maintain zones of anoxia in both the catchment uplands and peatlands that support obligate anaerobic sulphate-reducing bacteria. In addition, groundwater flow paths are an essential control on the delivery of sulphate to these bacteria that facilitate in situ mercury methylation. Keywords: methylmercury, methylation, hydrology, boreal catchment, peatland, Ontario, Canada</p
A new method to search for a cosmic ray dipole anisotropy
We propose a new method to determine the dipole (and quadrupole) component of
a distribution of cosmic ray arrival directions, which can be applied when
there is partial sky coverage and/or inhomogeneous exposure. In its simplest
version it requires that the exposure only depends on the declination, but it
can be easily extended to the case of a small amplitude modulation in right
ascension. The method essentially combines a minimization of the
distribution in declination to obtain the multipolar components along the
North-South axis and a harmonic Rayleigh analysis for the components involving
the right ascension direction
Peatlands and the carbon cycle: from local processes to global implications - a synthesis
Peatlands cover only 3% of the Earth's land surface but boreal and subarctic peatlands store about 15-30% of the world's soil carbon ( C) as peat. Despite their potential for large positive feedbacks to the climate system through sequestration and emission of greenhouse gases, peatlands are not explicitly included in global climate models and therefore in predictions of future climate change. In April 2007 a symposium was held in Wageningen, the Netherlands, to advance our understanding of peatland C cycling. This paper synthesizes the main findings of the symposium, focusing on (i) small-scale processes, (ii) C fluxes at the landscape scale, and (iii) peatlands in the context of climate change. The main drivers controlling most are related to some aspects of hydrology. Despite high spatial and annual variability in Net Ecosystem Exchange ( NEE), the differences in cumulative annual NEE are more a function of broad scale geographic location and physical setting than internal factors, suggesting the existence of strong feedbacks. In contrast, trace gas emissions seem mainly controlled by local factors. Key uncertainties remain concerning the existence of perturbation thresholds, the relative strengths of the CO2 and CH4 feedback, the links among peatland surface climate, hydrology, ecosystem structure and function, and trace gas biogeochemistry as well as the similarity of process rates across peatland types and climatic zones. Progress on these research areas can only be realized by stronger co-operation between disciplines that address different spatial and temporal scales
Effect of genome sequence on the force-induced unzipping of a DNA molecule
We considered a dsDNA polymer in which distribution of bases are random at
the base pair level but ordered at a length of 18 base pairs and calculated its
force elongation behaviour in the constant extension ensemble. The unzipping
force vs. extension is found to have a series of maxima and minima.
By changing base pairs at selected places in the molecule we calculated the
change in curve and found that the change in the value of force is of
the order of few pN and the range of the effect depending on the temperature,
can spread over several base pairs. We have also discussed briefly how to
calculate in the constant force ensemble a pause or a jump in the
extension-time curve from the knowledge of
Cosmic ray photodisintegration and the knee of the spectrum
We explore in some detail the scenario proposed to explain the observed knee
of the cosmic ray (CR) spectrum as due to the effects of photodisintegration of
the CR nuclei by interactions with optical and soft UV photons in the source
region. We show that the photon column densities needed to explain the
experimental data are significantly lower than those obtained in previous
estimations which neglected multinucleon emission in the photodisintegration
process. We also treat more accurately the photodisintegration thresholds, we
discuss the effects of photopion production processes and the neutron escape
mechanism, identifying the physical processes responsible for the qualitative
features of the results. This scenario would require the CR nuclei to traverse
column densities of eV/cm after
being accelerated in order to reproduce the observed knee, and predicts that
the CR composition should become lighter above eV.Comment: 17 pp. Comments and references added. To appear in Astroparticle
Physic
Coulomb singularity effects in tunnelling spectroscopy of individual impurities
Non-equilibrium Coulomb effects in resonant tunnelling processes through deep
impurity states are analyzed. It is shown that Coulomb vertex corrections to
the tunnelling transfer amplitude lead to a power-law singularity in current-
voltage characteristicsComment: 7 pages, 2 figure
McGill wetland model: evaluation of a peatland carbon simulator developed for global assessments
We developed the McGill Wetland Model (MWM) based on the general structure of the Peatland Carbon Simulator (PCARS) and the Canadian Terrestrial Ecosystem Model. Three major changes were made to PCARS: (1) the light use efficiency model of photosynthesis was replaced with a biogeochemical description of photosynthesis; (2) the description of autotrophic respiration was changed to be consistent with the formulation of photosynthesis; and (3) the cohort, multilayer soil respiration model was changed to a simple one box peat decomposition model divided into an oxic and anoxic zones by an effective water table, and a one-year residence time litter pool. MWM was then evaluated by comparing its output to the estimates of net ecosystem production (NEP), gross primary production (GPP) and ecosystem respiration (ER) from 8 years of continuous measurements at the Mer Bleue peatland, a raised ombrotrophic bog located in southern Ontario, Canada (index of agreement [dimensionless]: NEP = 0.80, GPP = 0.97, ER = 0.97; systematic RMSE [g C m<sup>−2</sup> d<sup>−1</sup>]: NEP = 0.12, GPP = 0.07, ER = 0.14; unsystematic RMSE: NEP = 0.15, GPP = 0.27, ER = 0.23). Simulated moss NPP approximates what would be expected for a bog peatland, but shrub NPP appears to be underestimated. Sensitivity analysis revealed that the model output did not change greatly due to variations in water table because of offsetting responses in production and respiration, but that even a modest temperature increase could lead to converting the bog from a sink to a source of CO<sub>2</sub>. General weaknesses and further developments of MWM are discussed
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