20,650 research outputs found
Cosmological Gravitational Wave Backgrounds
An overview is presented of possible cosmologically distant sources of
gravitational wave backgrounds, especially those which might produce detectable
backgrounds in the LISA band between 0.1 and 100 mHz. Examples considered here
include inflation-amplified vacuum fluctuations in inflaton and graviton
fields, bubble collisions in first-order phase transitions, Goldstone modes of
classical self-ordering scalars, and cosmic strings and other gauge defects.
Characteristic scales and basic mechanisms are reviewed and spectra are
estimated for each of these sources. The unique impact of a LISA detection on
fundamental physics and cosmology is discussed.Comment: 8 pages, LaTex, to appear in the "Second International LISA Symposium
on Gravitational Waves", ed. W. Folkner (AIP, in press
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The full-spectrum correlated-k method for longwave atmospheric radiative transfer using an effective Planck function
The correlated k-distribution (CKD) method is widely used in the radiative transfer schemes of atmospheric models and involves dividing the spectrum into a number of bands and then reordering the gaseous absorption coefficients within each one. The fluxes and heating rates for each band may then be computed by discretizing the reordered spectrum into of order 10 quadrature points per major gas and performing a monochromatic radiation calculation for each point. In this presentation it is shown that for clear-sky longwave calculations, sufficient accuracy for most applications can be achieved without the need for bands: reordering may be performed on the entire longwave spectrum. The resulting full-spectrum correlated k (FSCK) method requires significantly fewer monochromatic calculations than standard CKD to achieve a given accuracy. The concept is first demonstrated by comparing with line-by-line calculations for an atmosphere containing only water vapor, in which it is shown that the accuracy of heating-rate calculations improves approximately in proportion to the square of the number of quadrature points. For more than around 20 points, the root-mean-squared error flattens out at around 0.015 K/day due to the imperfect rank correlation of absorption spectra at different pressures in the profile. The spectral overlap of m different gases is treated by considering an m-dimensional hypercube where each axis corresponds to the reordered spectrum of one of the gases. This hypercube is then divided up into a number of volumes, each approximated by a single quadrature point, such that the total number of quadrature points is slightly fewer than the sum of the number that would be required to treat each of the gases separately. The gaseous absorptions for each quadrature point are optimized such that they minimize a cost function expressing the deviation of the heating rates and fluxes calculated by the FSCK method from line-by-line calculations for a number of training profiles. This approach is validated for atmospheres containing water vapor, carbon dioxide, and ozone, in which it is found that in the troposphere and most of the stratosphere, heating-rate errors of less than 0.2 K/day can be achieved using a total of 23 quadrature points, decreasing to less than 0.1 K/day for 32 quadrature points. It would be relatively straightforward to extend the method to include other gases
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