2,024 research outputs found
The Representation of Tropical Cyclones Within the Global William Putman Non-Hydrostatic Goddard Earth Observing System Model (GEOS-5) at Cloud-Permitting Resolutions
The Goddard Earth Observing System Model (GEOS-S), an earth system model developed in the NASA Global Modeling and Assimilation Office (GMAO), has integrated the non-hydrostatic finite-volume dynamical core on the cubed-sphere grid. The extension to a non-hydrostatic dynamical framework and the quasi-uniform cubed-sphere geometry permits the efficient exploration of global weather and climate modeling at cloud permitting resolutions of 10- to 4-km on today's high performance computing platforms. We have explored a series of incremental increases in global resolution with GEOS-S from irs standard 72-level 27-km resolution (approx.5.5 million cells covering the globe from the surface to 0.1 hPa) down to 3.5-km (approx. 3.6 billion cells)
The four leading arms of the Magellanic Cloud system
The Magellanic Cloud System (MCS) interacts via tidal and drag forces with
the Milky Way galaxy. Using the Parkes Galactic All-Sky Survey (GASS) of atomic
hydrogen we explore the role of drag on the evolution of the so-called Leading
Arm (LA). We present a new image recognition algorithm that allows us to
differentiate features within a 3-D data cube (longitude, latitude, radial
velocity) and to parameterize individual coherent structures. We compiled an HI
object catalog of LA objects within an area of 70 degr x 85 degr (1.6 sr) of
the LA region. This catalog comprises information of location, column density,
line width, shape and asymmetries of the individual LA objects above the
4-sigma threshold of Delta T_b simeq 200 mK. We present evidence of a fourth
arm segment (LA4). For all LA objects we find an inverse correlation of
velocities v_GSR in Galactic Standard of Rest frame with Magellanic longitude.
High-mass objects tend to have higher radial velocities than low-mass ones.
About 1/4 of all LA objects can be characterized as head-tail (HT) structures.
Using image recognition with objective criteria, it is feasible to isolate most
of LA emission from the diffuse Milky Way HI gas. Some blended gas components
(we estimate 5%) escape detection, but we find a total gas content of the LA
that is about 50% higher than previously assumed. These methods allow the
deceleration of the LA clouds to be traced towards the Milky Way disk by drag
forces. The derived velocity gradient strongly supports the assumption that the
whole LA originates entirely in the Large Magellanic Cloud (LMC). LA4 is
observed opposite to LA1, and we propose that both arms are related, spanning
about 52kpc in space. HT structures trace drag forces even at tens of kpc
altitudes above the Milky Way disk.Comment: 12 pages, 7 figures, 2 tables, accepted for publication Astronomy &
Astrophysics 201
Toward GEOS-6, A Global Cloud System Resolving Atmospheric Model
NASA is committed to observing and understanding the weather and climate of our home planet through the use of multi-scale modeling systems and space-based observations. Global climate models have evolved to take advantage of the influx of multi- and many-core computing technologies and the availability of large clusters of multi-core microprocessors. GEOS-6 is a next-generation cloud system resolving atmospheric model that will place NASA at the forefront of scientific exploration of our atmosphere and climate. Model simulations with GEOS-6 will produce a realistic representation of our atmosphere on the scale of typical satellite observations, bringing a visual comprehension of model results to a new level among the climate enthusiasts. In preparation for GEOS-6, the agency's flagship Earth System Modeling Framework [JDl] has been enhanced to support cutting-edge high-resolution global climate and weather simulations. Improvements include a cubed-sphere grid that exposes parallelism; a non-hydrostatic finite volume dynamical core, and algorithm designed for co-processor technologies, among others. GEOS-6 represents a fundamental advancement in the capability of global Earth system models. The ability to directly compare global simulations at the resolution of spaceborne satellite images will lead to algorithm improvements and better utilization of space-based observations within the GOES data assimilation syste
The Magellanic Bridge: The Nearest Purely Tidal Stellar Population
We report on observations of the stellar populations in twelve fields
spanning the region between the Magellanic Clouds, made with the Mosaic-II
camera on the 4-meter telescope at the Cerro-Tololo Inter-American Observatory.
The two main goals of the observations are to characterize the young stellar
population (which presumably formed in situ in the Bridge and therefore
represents the nearest stellar population formed from tidal debris), and to
search for an older stellar component (which would have been stripped from
either Cloud as stars, by the same tidal forces which formed the gaseous
Bridge). We determine the star-formation history of the young inter-Cloud
population, which provides a constraint on the timing of the gravitational
interaction which formed the Bridge. We do not detect an older stellar
population belonging to the Bridge in any of our fields, implying that the
material that was stripped from the Clouds to form the Magellanic Bridge was
very nearly a pure gas.Comment: 19 pages, 9 figures. Accepted to Ap
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