5,047 research outputs found
[OIII] Emission and Gas Kinematics in a Lyman-alpha Blob at z ~ 3.1
We present spectroscopic measurements of the [OIII] emission line from two
subregions of strong Lyman-alpha emission in a radio-quiet Lyman-alpha blob
(LAB). The blob under study is LAB1 (Steidel et al. 2000) at z ~ 3.1, and the
[OIII] detections are from the two Lyman break galaxies embedded in the blob
halo. The [OIII] measurements were made with LUCIFER on the 8.4m Large
Binocular Telescope and NIRSPEC on 10m Keck Telescope. Comparing the redshift
of the [OIII] measurements to Lyman-alpha redshifts from SAURON (Weijmans et
al. 2010) allows us to take a step towards understanding the kinematics of the
gas in the blob. Using both LUCIFER and NIRSPEC we find velocity offsets
between the [OIII] and Lyman-alpha redshifts that are modestly negative or
consistent with 0 km/s in both subregions studied (ranging from -72 +/- 42 --
+6 +/- 33 km/s). A negative offset means Lyman-alpha is blueshifted with
respect to [OIII], a positive offset then implies Lyman-alpha is redshifted
with respect to [OIII]. These results may imply that outflows are not primarily
responsible for Lyman alpha escape in this LAB, since outflows are generally
expected to produce a positive velocity offset (McLinden et al. 2011). In
addition, we present an [OIII] line flux upper limit on a third region of LAB1,
a region that is unassociated with any underlying galaxy. We find that the
[OIII] upper limit from the galaxy-unassociated region of the blob is at least
1.4 -- 2.5 times fainter than the [OIII] flux from one of the LBG-associated
regions and has an [OIII] to Lyman-alpha ratio measured at least 1.9 -- 3.4
times smaller than the same ratio measured from one of the LBGs.Comment: submitted to Ap
Exoplanet atmospheres with EChO: spectral retrievals using EChOSim
We demonstrate the effectiveness of the Exoplanet Characterisation
Observatory mission concept for constraining the atmospheric properties of hot
and warm gas giants and super Earths. Synthetic primary and secondary transit
spectra for a range of planets are passed through EChOSim (Waldmann & Pascale
2014) to obtain the expected level of noise for different observational
scenarios; these are then used as inputs for the NEMESIS atmospheric retrieval
code and the retrieved atmospheric properties (temperature structure,
composition and cloud properties) compared with the known input values,
following the method of Barstow et al. (2013a). To correctly retrieve the
temperature structure and composition of the atmosphere to within 2 {\sigma},
we find that we require: a single transit or eclipse of a hot Jupiter orbiting
a sun-like (G2) star at 35 pc to constrain the terminator and dayside
atmospheres; 20 transits or eclipses of a warm Jupiter orbiting a similar star;
10 transits/eclipses of a hot Neptune orbiting an M dwarf at 6 pc; and 30
transits or eclipses of a GJ1214b-like planet.Comment: 13 pages, 15 figures, 1 table. Accepted by Experimental Astronomy.
The final publication will shortly be available at Springer via
http://dx.doi.org/10.1007/s10686-014-9397-
Tracking and Treating Malignant Melanoma Metastases
Dermatology Research and Practice - Special Editio
Line Emission From C⁶⁺, O8+ + Li Electron Capture Collisions
Electron capture cross sections to nl sublevels have been calculated for 1-10keVu−1 collisions of C6+ and O8+ projectiles on a Li target. The classical trajectory Monte Carlo method has been employed with the initial phase distributions for the Li(2s) target obtained from Hartree-Fock calculations. The cross sections are found to maximize at π = 7 for C6+ and n = 8−9 for O8+. The nl cross sections were used to calculate Δ n = 1 line emission cross sections. Comparison of these cross sections with the experimental results of Wolfruni et al indïoitçs good agreement between theory and experiment. © 1992 IOP Publishing Ltd
Molecular Treatment Of Electron Capture By Protons From The Ground And Excited States Of Alkali-metal Atoms
Electron-capture cross sections for H+ plus alkali-metal atom (Na, K, Rb, and Cs) systems have been computed for projectile energies from 10 eV to 10 keV. An impact parameter perturbed-stationary-state theory using molecular states that incorporate electron translation factors was used to calculate the cross sections. The wave functions were generated by employing the pseudopotential method. These yield equilibrium parameters Re and De for the A +2 molecular state that are in good agreement with ab initio results. Interaction energies are also presented for the LiH+ system. Basis sets of up to eight molecular states were used to calculate the electron-capture cross sections from ground (ns) as well as from the first excited (np) states of the alkali-metal atoms. Results for electron capture from the ground-state alkali-metal atom are in good agreement with the recent experiments of Nagata. Electron capture from excited alkali-metal (np) atoms does not yield enhanced cross sections relative to capture from the ground state and, in fact, shows decreased cross sections for the heavy alkali-metal atoms. Such behavior is contrary to predictions made using arguments based on the magnitude of the energy gap E to the electron-capture product states. © 1982 The American Physical Society
Electron-capture collisions of H+ with ground- and excited-state Na
Pseudopotential molecular-structure calculations have been used to obtain the low-lying interaction energies for NaH+. The wave functions were used to calculate accurate radial and rotational coupling matrix elements. Scattering calculations which include electron translational factors were performed using up to eight coupled channels for laboratory energies 0.1 to 10 keV. Electron capture from ground-state Na 3s yields cross sections in the 10-15-cm2 range of which the dominant products are H 2s and H 2p. Electron capture from excited Na 3p does not show an enhanced cross section relative to capture from the ground state even though the energy gap E(R=) to the dominant electron-capture channel is reduced from 1.74 to 0.36 eV. © 1982 The American Physical Society
Catheter entrapment in a pulmonary vein: a unique complication of pulmonary vein isolation.
Ablation strategies for the treatment of atrial fibrillation (AF) are associated with several potential complications. During electro-anatomic mapping of the left atrium (LA) before ablation, the ablation catheter was entrapped in the right inferior pulmonary vein (RIPV). After multiple unsuccessful gentle tractions, stronger maneuvers with rotation of the catheter slowly allowed its retrieval. Examination of the catheter showed a thin, translucent membrane covering its tip, suggesting complete stripping of a vein branch. Occlusion of the superior branch of the RIPV was confirmed by LA angiogram. During the following days, no pericardial effusion was noted, but the patient complained of light chest pain and mild hemoptysis, spontaneously resolving within 48 h. This case shows that catheter entrapment and mechanical disruption of a PV branch can be a rare potential complication of AF ablation. In this case, the outcome was spontaneously favorable and symptoms only included transient mild hemoptysis
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