1,821 research outputs found
pH electrode performance under automated management conditions
pH is frequently measured in laboratories, but to have confidence in
the results it is necessary to know that it was measured properly. For an electrode to give accurate results it must be treated well and calibrated correctly. In this paper, an automated system for pH measurement is described; the system uses the operational pH scale and calibrates using two or three buffer solutions, taking proper account of the effects of temperature on the system. The system can be programmed with standard methods and procedures to ensure that the electrode gives the best possible performance. Calibrations and measurements within the system are reproducible, and the
automated system is more robust than the manual pH meter, and requires less operator time
The FERRUM Project: experimental and theoretical transition rates of forbidden [Sc II] lines and radiative lifetimes of metastable Sc II levels
Context. In many plasmas, long-lived metastable atomic levels are depopulated
by collisions (quenched) before they decay radiatively. In low-density regions,
however, the low collision rate may allow depopulation by electric dipole (E1)
forbidden radiative transitions, so-called forbidden lines (mainly M1 and E2
transitions). If the atomic transition data are known, these lines are
indicators of physical plasma conditions and used for abundance determination.
Aims. Transition rates can be derived by combining relative intensities between
the decay channels, so-called branching fractions (BFs), and the radiative
lifetime of the common upper level. We use this approach for forbidden [Sc ii]
lines, along with new calculations. Methods. Neither BFs for forbidden lines,
nor lifetimes of metastable levels, are easily measured in a laboratory.
Therefore, astrophysical BFs measured in Space Telescope Imaging Spectrograph
(STIS) spectra of the strontium filament of Eta Carinae are combined with
lifetime measurements using a laser probing technique on a stored ion-beam
(CRYRING facility,MSL, Stockholm). These quantities are used to derive the
absolute transition rates (A-values). New theoretical transition rates and
lifetimes are calulated using the CIV3 code. Results. We report experimental
lifetimes of the Sc ii levels 3d2 a3P0,1,2 with lifetimes 1.28, 1.42, and 1.24
s, respectively, and transition rates for lines from these levels down to 3d4s
a3D in the region 8270-8390 A. These are the most important forbidden [Sc ii]
transitions. New calculations for lines and metastable lifetimes are also
presented, and are in good agreement with the experimental data.Comment: 5 pages. Accepted for A&
The Abundance of Interstellar Nitrogen
Using the HST Goddard High Resolution Spectrograph (GHRS), we have obtained
high S/N echelle observations of the weak interstellar N I 1160, 1161 A
absorption doublet toward the stars Gamma Cas, Lambda Ori, Iota Ori, Kappa Ori,
Delta Sco, and Kappa Sco. In combination with a previous GHRS measurement of N
I toward Zeta Oph, these new observations yield a mean interstellar gas phase
nitrogen abundance (per 10 H atoms) of 10 N/H = 75 +/- 4. There are no
statistically significant variations in the measured N abundances from
sightline to sightline and no evidence of density-dependent depletion from the
gas-phase. Since N is not expected to be depleted much into dust grains in
these diffuse sightlines, its gas-phase abundance should reflect the total
interstellar abundance. Consequently, the GHRS observations imply that the
abundance of interstellar nitrogen (gas plus grains) in the local Milky Way is
about 80% of the solar system value of 10 N/H = 93 +/- 16. Although this
interstellar abundance deficit is somewhat less than that recently found for
oxygen and krypton with GHRS, the solar N abundance and the N I oscillator
strengths are too uncertain to definitively rule out either a solar ISM N
abundance or a 2/3 solar ISM N abundance similar to that of O and Kr.Comment: 14 pages, LaTeX, 2 Postscript figures; ApJ Letters, in pres
The influence of electron collisions on non-LTE Li line formation in stellar atmospheres
The influence of the uncertainties in the rate coefficient data for
electron-impact excitation and ionization on non-LTE Li line formation in cool
stellar atmospheres is investigated. We examine the electron collision data
used in previous non-LTE calculations and compare them to recent calculations
that use convergent close-coupling (CCC) techniques and to our own calculations
using the R-matrix with pseudostates (RMPS) method. We find excellent agreement
between rate coefficients from the CCC and RMPS calculations, and reasonable
agreement between these data and the semi-empirical data used in non-LTE
calculations up to now. The results of non-LTE calculations using the old and
new data sets are compared and only small differences found: about 0.01 dex (~
2%) or less in the abundance corrections. We therefore conclude that the
influence on non-LTE calculations of uncertainties in the electron collision
data is negligible. Indeed, together with the collision data for the charge
exchange process Li(3s) + H Li^+ + H^- now available, and barring the
existence of an unknown important collisional process, the collisional data in
general is not a source of significant uncertainty in non-LTE Li line formation
calculations.Comment: 8 pages, accepted by Astronomy and Astrophysics; Replaced with minor
corrections following proof
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