7,309 research outputs found
The Unusual Spectrum of Comet 96P/Machholz
We report spectra from 3000-5900 A for comet 96P/Machholz, obtained on 2007
Apr 27 UT with the 3-m Shane telescope at Lick Observatory. The spectra are
extremely carbon poor, and show a prominent NH_2 series, but no CN emission.
NH, NH_2, and C_2 gas production rates are (8.36 +/- 2.18)x10^25, (29.88 +/-
3.66)x10^25, and (4.52 +/- 0.61)x10^23 molecules sec^-1, respectively, as
determined from Haser model fits to the data. Upper limits to the gas
production rates for CN and C_3 are 7.5x10^22 and 2.0x10^23, respectively.
Though 96P is depleted in C_2 and C_3 relative to NH, it is even more depleted
in CN than other so-called "carbon-chain depleted" comets.Comment: 14 pages, 4 tables, 2 figures, accepted for publication in ApJ
The cosmological information of shear peaks: beyond the abundance
We study the cosmological information of weak lensing (WL) peaks, focusing on
two other statistics besides their abundance: the stacked tangential-shear
profiles and the peak-peak correlation function. We use a large ensemble of
simulated WL maps with survey specifications relevant to future missions like
Euclid and LSST, to explore the three peak probes. We find that the correlation
function of peaks with high signal-to-noise (S/N) measured from fields of size
144 sq. deg. has a maximum of ~0.3 at an angular scale ~10 arcmin. For peaks
with smaller S/N, the amplitude of the correlation function decreases, and its
maximum occurs on smaller angular scales. We compare the peak observables
measured with and without shape noise and find that for S/N~3 only ~5% of the
peaks are due to large-scale structures, the rest being generated by shape
noise. The covariance matrix of the probes is examined: the correlation
function is only weakly covariant on scales < 30 arcmin, and slightly more on
larger scales; the shear profiles are very correlated for theta > 2 arcmin,
with a correlation coefficient as high as 0.7. Using the Fisher-matrix
formalism, we compute the cosmological constraints for {Om_m, sig_8, w, n_s}
considering each probe separately, as well as in combination. We find that the
correlation function of peaks and shear profiles yield marginalized errors
which are larger by a factor of 2-4 for {Om_m, sig_8} than the errors yielded
by the peak abundance alone, while the errors for {w, n_s} are similar. By
combining the three probes, the marginalized constraints are tightened by a
factor of ~2 compared to the peak abundance alone, the least contributor to the
error reduction being the correlation function. This work therefore recommends
that future WL surveys use shear peaks beyond their abundance in order to
constrain the cosmological model.Comment: 15 pages, 10 figures, submitted to MNRA
Towards optimal estimation of the galaxy power spectrum
The galaxy power spectrum encodes a wealth of information about cosmology and the matter fluctuations. Its unbiased and optimal estimation is therefore of great importance. In this paper, we generalize the framework of Feldman et al. (1994) to take into account the fact that galaxies are not simply a Poisson sampling of the underlying dark matter distribution. Besides finite survey-volume effects and flux limits, our optimal estimation scheme incorporates several of the key tenets of galaxy formation: galaxies form and reside exclusively in dark matter haloes; a given dark matter halo may host several galaxies of various luminosities; galaxies inherit part of their large-scale bias from their host halo. Under these broad assumptions, we prove that the optimal weights do not explicitly depend on galaxy luminosity, other than through defining the maximum survey volume and effective galaxy density at a given position. Instead, they depend on the bias associated with the host halo; the first and second factorial moments of the halo occupation distribution; a selection function, which gives the fraction of galaxies that can be observed in a halo of mass M at position {r} in the survey; and an effective number density of galaxies. If one wishes to reconstruct the matter power spectrum, then, provided the model is correct, this scheme provides the only unbiased estimator. The practical challenges with implementing this approach are also discussed
What do cluster counts really tell us about the Universe?
We study the covariance matrix of the cluster mass function in cosmology. We adopt a two-line attack: first, we employ the counts-in-cells framework to derive an analytic expression for the covariance of the mass function. Secondly, we use a large ensemble of N-body simulations in the Λ cold dark matter framework to test this. Our theoretical results show that the covariance can be written as the sum of two terms: a Poisson term, which dominates in the limit of rare clusters; and a sample variance term, which dominates for more abundant clusters. Our expressions are analogous to those of Hu & Kravtsov for multiple cells and a single mass tracer. Calculating the covariance depends on: the mass function and bias of clusters, and the variance of mass fluctuations within the survey volume. The predictions show that there is a strong bin-to-bin covariance between measurements. In terms of the cross-correlation coefficient, we find r≳ 0.5 for haloes with M≲ 3 × 1014 h−1 M⊙ at z= 0. Comparison of these predictions with estimates from simulations shows excellent agreement. We use the Fisher matrix formalism to explore the cosmological information content of the counts. We compare the Poisson likelihood model, with the more realistic likelihood model of Lima & Hu, and all terms entering the Fisher matrices are evaluated using the simulations. We find that the Poisson approximation should only be used for the rarest objects, M≳ 5 × 1014 h−1 M⊙, otherwise the information content of a survey of size V∼ 13.5 h−3 Gpc3 would be overestimated, resulting in errors that are nearly two times smaller. As an auxiliary result, we show that the bias of clusters, obtained from the cluster-mass cross-variance, is linear on scales >50 h−1 Mpc, whereas that obtained from the auto-variance is non-linea
Production Practices and Sample Costs for a Diversified Organic Vegetable Operation on the Central Coast of California
Organic vegetable farms on the Central Coast region of California are generally intensive operations. That is, two and sometimes three crops may be harvested off the same acreage each year. Many approaches exist for rowing and marketing organic vegetables. This publication describes the range of soil management practices, pest management, crop rotations, cover crops, and harvest and packing methods currently used by organic growers on the Central Coast of California. Marketing options and state and federal regulations governing organic commodities are also discussed. A general sequence of operations, equipment requirements, resource use, costs, yield and return ranges are presented for thirteen vegetable crops and two cover crops. The vegetables included are cabbage, cauliflower, cucumbers, garlic, lettuce (leaf and romaine), onions (red and yellow), snap peas, snow peas, bell peppers (green and red), sweet corn, and winter squash (large and small varieties). Barley and vetch are the two cover crops detailed.Crop Production/Industries,
The cosmology dependence of weak lensing cluster counts
We present the main results of a numerical study of weak lensing cluster
counting. We examine the scaling with cosmology of the projected-density-peak
mass function. Our main conclusion is that the projected-peak and the
three-dimensional mass functions scale with cosmology in an astonishingly close
way. This means that, despite being derived from a two-dimensional field, the
weak lensing cluster abundance can be used to constrain cosmology in the same
way as the three-dimensional mass function probed by other types of surveys.Comment: 4 pages, 2 figures. Accepted for publication in ApJL. Figure 1
modified, unchanged conclusion
Social Psychological Theory and Research on the Novel Coronavirus Disease (COVID-19) Pandemic: Introduction to the Rapid Response Special Section
In this introduction to the rapid response special section on the social psychology of the COVID-19 pandemic, we introduce twelve brief reports that, taken together, explain the psychological underpinnings of viral transmission, including public responses to COVID-19, (non)compliance with public health advice, and intra- and inter-community relations. The brief reports address these issues by applying multiple different theoretical and methodological tools from social psychology. In this introduction, we conceptually integrate the conclusions of these brief reports and summarise their key practical recommendations for stakeholders, and in doing so set out directions for future research into the social psychology of viral transmission, public health behaviour, and intergroup relations during and after pandemics. We conclude that if the medical and epidemiological response to this crisis is informed and mirrored by a rigorous social psychological response, then we may be able to move beyond the current situation united by our common humanity, be better prepared for future pandemics, and better placed to address the long-term inequalities that have been brought into sharp focus by COVID-19
A longitudinal study of factors associated with acute and chronic mastitis and their impact on lamb growth rate in 10 suckler sheep flocks in Great Britain
A 2-year prospective, longitudinal study of 10 suckler sheep flocks in Great Britain was run to identify factors associated with acute mastitis (AM) and chronic mastitis, and their impact on lamb growth rate. Data were collected on AM, intramammary masses (IMM; a marker for chronic mastitis), udder and teat conformation, teat lesions, body condition, ewe nutrition, litter size, lamb weight and general flock management. Each flock was visited twice each year, approximately 4 weeks before lambing and 9 weeks into lactation, for two years and all ewes present at a visit were examined. There were 7021 examinations in total. AM was reported in 2.1–3.0% of ewes/year; this ranged from 0.0% to 37.1% by flock. IMM were detected in 4.7% of ewes in pregnancy and 10.9% of ewes in lactation. Once an IMM had been detected there was an increased risk of future IMM although IMM were not consistently present. The majority of ewes had good udder conformation to suckle lambs. Factors associated with AM, IMM in pregnant and lactating ewes, udder conformation and lamb daily live weight gain were explored using mixed effect multivariable models. An increased risk of AM was associated with underfeeding protein in pregnancy (OR 4.05), forward pointing teats (OR 2.54), downward pointing teats (OR 4.68), rearing ≥ 2 lambs (OR 2.65), non-traumatic teat lesions (OR 2.09); and marginally associated with the presence of IMM. An increased risk of IMM in lactation was associated with AM during lactation (OR 12.39), IMM in pregnancy (OR 4.79), IMM in the previous lactation (OR 4.77), underfeeding energy in pregnancy (OR 6.66) and traumatic teat lesions (OR 2.48). An increased risk of IMM in pregnancy was associated with IMM in the previous pregnancy, IMM in the previous lactation and underfeeding energy in the previous lactation (OR 2.95). Lower lamb daily live weight gain was associated with traumatic teat lesions, IMM in lactation (−0.01 kg/day) and AM (−0.04 kg/day). We conclude that inadequate nutrition is an important cause of mastitis in suckler ewes which farmers could address in part using current nutritional guidelines but further work is needed. The relationship between AM and IMM indicates that separating or culling ewes with IMM would help reduce AM
Towards optimal cluster power spectrum analysis
The power spectrum of galaxy clusters is an important probe of the
cosmological model. In this paper we determine the optimal weighting scheme for
maximizing the signal-to-noise ratio for such measurements. We find a closed
form analytic expression for the optimal weights. Our expression takes into
account: cluster mass, finite survey volume effects, survey masking, and a flux
limit. The implementation of this weighting scheme requires knowledge of the
measured cluster masses, and analytic models for the bias and space-density of
clusters as a function of mass and redshift. Recent studies have suggested that
the optimal method for reconstruction of the matter density field from a set of
clusters is mass-weighting (Seljak et al 2009, Hamaus et al 2010, Cai et al
2011). We compare our optimal weighting scheme with this approach and also with
the original power spectrum scheme of Feldman et al (1994). We show that our
optimal weighting scheme outperforms these approaches for both volume- and
flux-limited cluster surveys. Finally, we present a new expression for the
Fisher information matrix for cluster power spectrum analysis. Our expression
shows that for an optimally weighted cluster survey the cosmological
information content is boosted, relative to the standard approach of Tegmark
(1997).Comment: Significantly shortened: 20 pages; 3 figure
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