9,910 research outputs found
Surface-sensitive NMR in optically pumped semiconductors
We present a scheme of surface-sensitive nuclear magnetic resonance in
optically pumped semiconductors, where an NMR signal from a part of the surface
of a bulk compound semiconductor is detected apart from the bulk signal. It
utilizes optically oriented nuclei with a long spin-lattice relaxation time as
a polarization reservoir for the second (target) nuclei to be detected. It
provides a basis for the nuclear spin polarizer [IEEE Trans. Appl. Supercond.
14, 1635 (2004)], which is a polarization reservoir at a surface of the
optically pumped semiconductor that polarizes nuclear spins in a target
material in contact through the nanostructured interfaces.Comment: 4 pages, 5 figure
Goto's generalized Kaehler stability theorem
In these notes we give a shortened and more direct proof of Goto's
generalized Kaehler stability theorem stating that if (J_1,J_2) is a
generalized kaehler structure for which J_2 is determined by a nowhere
vanishing closed form, then small deformations of J_1 can be coupled with small
deformations of J_2 so that the pair remains a generalized Kaehler structure.Comment: 9 pages, 5 figure
Chemical Analysis of a Diffuse Cloud along a Line of Sight Toward W51: Molecular Fraction and Cosmic-Ray Ionization Rate
Absorption lines from the molecules OH+, H2O+, and H3+ have been observed in
a diffuse molecular cloud along a line of sight near W51 IRS2. We present the
first chemical analysis that combines the information provided by all three of
these species. Together, OH+ and H2O+ are used to determine the molecular
hydrogen fraction in the outskirts of the observed cloud, as well as the
cosmic-ray ionization rate of atomic hydrogen. H3+ is used to infer the
cosmic-ray ionization rate of H2 in the molecular interior of the cloud, which
we find to be zeta_2=(4.8+-3.4)x10^-16 per second. Combining the results from
all three species we find an efficiency factor---defined as the ratio of the
formation rate of OH+ to the cosmic-ray ionization rate of H---of
epsilon=0.07+-0.04, much lower than predicted by chemical models. This is an
important step in the future use of OH+ and H2O+ on their own as tracers of the
cosmic-ray ionization rate.Comment: 21 pages, 1 figure, 4 table
Fundamental Vibrational Transitions of HCl Detected in CRL 2136
We would like to understand the chemistry of dense clouds and their hot cores
more quantitatively by obtaining more complete knowledge of the chemical
species present in them. We have obtained high-resolution infrared absorption
spectroscopy at 3-4 um toward the bright infrared source CRL 2136. The
fundamental vibration-rotation band of HCl has been detected within a dense
cloud for the first time. The HCl is probably located in the warm compact
circumstellar envelope or disk of CRL 2136. The fractional abundance of HCl is
(4.9-8.7)e-8, indicating that approximately 20 % of the elemental chlorine is
in gaseous HCl. The kinetic temperature of the absorbing gas is 250 K, half the
value determined from infrared spectroscopy of 13CO and water. The percentage
of chlorine in HCl is approximately that expected for gas at this temperature.
The reason for the difference in temperatures between the various molecular
species is unknown.Comment: 6 pages, 3 figures, A&A in pres
Absorption Line Survey of H3+ toward the Galactic Center Sources III. Extent of the Warm and Diffuse Clouds
We present follow-up observations to those of Geballe & Oka (2010), who found
high column densities of H3+ ~100 pc off of the Galactic center (GC) on the
lines of sight to 2MASS J17432173-2951430 (J1743) and 2MASS J17470898-2829561
(J1747). The wavelength coverages on these sightlines have been extended in
order to observe two key transitions of H3+, R(3,3)l and R(2,2)l, that
constrain the temperatures and densities of the environments. The profiles of
the H3+ R(3,3)l line, which is due only to gas in the GC, closely matches the
differences between the H3+ R(1,1)l and CO line profiles, just as it does for
previously studied sightlines in the GC. Absorption in the R(2,2)l line of H3+
is present in J1747 at velocities between -60 and +100 km/s. This is the second
clear detection of this line in the interstellar medium after GCIRS 3 in the
Central Cluster. The temperature of the absorbing gas in this velocity range is
350 K, significantly warmer than in the diffuse clouds in other parts of the
Central Molecular Zone. This indicates that the absorbing gas is local to Sgr B
molecular cloud complex. The warm and diffuse gas revealed by Oka et al. (2005)
apparently extends to ~100 pc, but there is a hint that its temperature is
somewhat lower in the line of sight to J1743 than elsewhere in the GC. The
observation of H3+ toward J1747 is compared with the recent Herschel
observation of H2O+ toward Sgr B2 and their chemical relationship and
remarkably similar velocity profiles are discussed.Comment: 6 pages, 3 figures, 2 tables, Accepted for publication in
Publications of the Astronomical Society of Japa
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