283 research outputs found
Temperature Conditions Existing in a Diffusion Type Cloud Chamber
There are many types of detectors of radioactive rays, such as Geiger Counters, ionization chambers, photographic emulsions, electroscopes, and cloud chambers. Many of these give only information such as the amount of radiation or the minimum energy of the rays because the information is registered as a change in voltage or a âcountâ. Outstanding among the different kinds of detectors is the type commonly called âcloud chambersâ. In a cloud chamber the path of the ray* can actually be seen and photographed, its radius of curvature in an electric or magnetic field can be measured, the amount of ionization can be measured by counting the number of ions per length of path, and the amount of deviation from the predicted normal path can be studied. From this type of information the mass, velocity, and charge of the ray can be determined. The basic principle utilized in any chamber is that a gas which is supersaturated with a vapor will act as a means of detection of radioactive rays by forming a cloud trail along the path of the ray. The most common method of obtaining a gas which is supersaturated with a vapor is by cooling. Gas which has been saturated with vapor can be cooled until a high degree of supersaturation is reached if there are no particles in it to act as nuclei around which droplets can form. J.Aitken during his investigations (about 1880) indicated that dust particles do act as such nuclei and utilized the fact to count dust particles. In 1896 C.T.R. Wilson showed that ions formed in a supersaturated gas could also act as centers of condensation. This fact led Wilson to the discovery of his famous âexpansionâ cloud chamber. It is theorized that high energy rays in their motion through matter ionize many atoms along their path. These ions form nuclei for condensation, thus producing a trail of droplets which are visible to the eye and which also can be photographed if desired. The method used by Wilson for obtaining the supersaturated gas is expansion of a saturated gas by means of piston on the floor of the chamber. This sudden increase of volume causes a decrease of temperature, thus causing the gas to become supersaturated. The main disadvantage in Wilsonâs chamber is that it will show tracks for only a very short period of time after expansion and then must be recycled for the next expansion. Therefore, there has been considerable interest in some kind of chamber that would be continuously sensitive. The first continuously sensitive cloud chamber was reported by L.G. Hoxton in 1933. This cloud chamber operated by passing air over water at 70C and thence into a water-jacketed observing channel at room temperature. Condensation phenomena were produced by electric discharges but not by radiation, so this method was not satisfactory. In 1936 R. E. Vollrath described a continuous cloud chamber that operated by interdiffusion of two vapors such as hydrochloric acid vapor and water vapor, at the interface of which the gas became supersaturated with respect to the mixture (dilute hydrochloric acid). A.Langsdorf, Jr. reported progress on a continuous diffusion cloud chamber in 1936. The construction of Langsdorfâs chamber is essentially a glass cylinder with a refrigerated floor and a heated roof. Through the roof the vapor of a liquid with a high vapor pressure is allowed to diffuse and saturate the gas in the chamber. Then as the saturated gas diffuses downward it becomes cooled and thus supersaturated and within a limited region acts as an ion detector. Although diffusion chambers have the advantage of being continuous, they frequently have the disadvantage of having diffuse, fuzzy, or distorted tracks which do not generally present a great problem in a well-designed Wilson expansion chamber. There is a definite need to find out more about the conditions that exist in diffusion chambers in order to improve their design. The purpose of this paper is to investigate some of the conditions that exist in a diffusion chamber, similar to the type proposed by Langsdorf
Probing the Processes of Planet Formation via Studies of the Ï” Chameleonitis Association
Nearby Young Moving Groups (NYMGs), i.e., loose groups of stars of age \u3c100 Myr in the solar vicinity, present ideal, accessible observational laboratories for studies on star and planet formation. Studying individual members of NYMGs, especially those hosting protoplanetary disks, in the infrared and millimeter regimes gives astronomers key information on disk evolution and the planet formation process. In this dissertation, I present an analysis of newly available data for members of one of the youngest known NYMGs, the Epsilon Chameleonitis Association (ECA), including detailed studies of two ECA members that host protoplanetary disks viewed at high inclinations (i.e. within ~30 degrees of edge-on). Through analysis of Gaia Space Astrometry Mission data for the ECA, I present updated constraints on the Galactic positions and kinematics and color-magnitude diagram positions of ECA members and candidates. I reassess their membership status and refine estimates of the multiplicity and disk fraction of the group. I determine a mean distance to ECA of 101.0±4.6 pc and confirm that, at an age of 5±3 Myr, it represents the youngest stellar group within ~100 pc of Earth. The two nearly edge-on star-disk systems studied here are representative of the diversity of planet-forming environments around young stars. The first, 2M1155-79B, was discovered during the aforementioned Gaia study of the ECA. Near-infrared spectra of 2M1155-79B, along with analysis of photometry from Gaia EDR3, 2MASS, VHS, and WISE, reveal that 2M1155-79B is most likely a young, late-M, star near the hydrogen-burning limit that is partially obscured by, and actively accreting from, a nearly edge-on circumstellar disk. The second planet-forming disk studied here orbits T Cha, a near solar-mass ECA member. I present archival Atacama Large Millimeter Array images of the millimeter continuum and 12CO (3-2) and 13CO (3-2) emission from the highly inclined (i~73°) T Cha disk. Radial brightness profiles show a limb-brightened ring of CO gas orbiting inside of the large dust grains generating the millimeter continuum, surrounded by a radially and vertically extended region of CO gas out to radii of ~200 AU that modelling reveals is likely probing the vertical freeze-out. These analyses illustrate the future potential of the ECA for providing new insights into star and planet formation processes
A Penetration Depth Study on Li2Pd3B and Li2Pt3B
In this paper we present a penetration depth study on the newly discovered
superconductors LiPdB and LiPtB. Surprisingly, the
low-temperature penetration depth demonstrates distinct behavior in
these two isostructural compounds. In LiPdB, follows an
exponential decay and can be nicely fitted by a two-gap BCS superconducting
model with a small gap K and a large gap K.
However, linear temperature dependence of is observed in LiPtB
below 0.3, giving evidence of line nodes in the energy gap.Comment: 2 pages, submitted to LT2
Assessing Internal Audit Quality
Internal audit quality is an issue of great importance to both the internal and external audit professions. PCAOB Auditing Standard No 2 highlights this importance when addressing the reliance that the external auditor can place on the internal audit work product. The study discussed here experimentally tests the influence of the source of the internal audit function on both the internal and external auditors\u27 evaluation of the quality of the internal audit function. To assess the importance of the internal audit function\u27s sourcing arrangement in the internal audit function\u27s quality assessment, the researchers employ a case study approach, modifying a case that has been used in prior research. The researchers find that for three of the four measured internal audit function quality characteristics, there was no difference in the assessment of the internal audit function between internal and external auditors, regardless of whether or not the internal audit function was provided in-house or was outsourced to a CPA firm other than the external auditor\u27s firm
Auditor Perceptions of Audit Workloads, Audit Quality, and Job Satisfaction
In this study, we use a survey instrument to obtain perspectives from over 700 auditors about present-day audit workloads and the relationship between audit workloads, audit quality, and job satisfaction. Our findings indicate that auditors are working, on average, five hours per week above the threshold at which they believe audit quality begins to deteriorate and often 20 hours above this threshold at the peak of busy season. Survey respondents perceive deadlines and staffing shortages as two of the primary reasons for high workloads and further believe that high workloads result in decreased audit quality via compromised audit procedures (including taking shortcuts), impaired audit judgment (including reduced professional skepticism), and difficulty retaining staff with appropriate knowledge and skills. We also find that auditorsâ job satisfaction and their excitement about auditing as a career are negatively impacted by high audit workload, particularly when the workload exceeds a threshold that is perceived to impair audit quality. Overall, our findings provide support for the PCAOBâs recent concern that heavy workloads are continuing to threaten audit quality and suggest that the primary drivers of workload (i.e., deadlines and staffing problems) might be the actual âroot causeâ of workload-related audit deficiencies
Penetration depth study of LaOsSb: Multiband s-wave superconductivity
We measured the magnetic penetration depth in single crystals of
LaOsSb (=0.74 K) down to 85 mK using a tunnel diode
oscillator technique. The observed low-temperature exponential dependence
indicates a s-wave gap. Fitting the low temperature data to BCS s-wave
expression gives the zero temperature gap value which is significantly smaller than the BCS value of 1.76. In
addition, the normalized superfluid density shows an unusually long
suppression near , and are best fit by a two-band s-wave model.Comment: 5 pages, 2 figure
S-wave/spin-triplet order in superconductors without inversion symmetry: LiPdB and LiPtB
We investigate the order parameter of noncentrosymmetric superconductors
LiPdB and LiPtB via the behavior of the penetration depth
. The low-temperature penetration depth shows BCS-like behavior in
LiPdB, while in LiPtB it follows a linear temperature
dependence. We propose that broken inversion symmetry and the accompanying
antisymmetric spin-orbit coupling, which admix spin-singlet and spin-triplet
pairing, are responsible for this behavior. The triplet contribution is weak in
LiPdB, leading to a wholly open but anisotropic gap. The significantly
larger spin-orbit coupling in LiPtB allows the spin-triplet component
to be larger in LiPtB, producing line nodes in the energy gap as
evidenced by the linear temperature dependence of . The
experimental data are in quantitative agreement with theory.Comment: Phys. Rev. Lett. (in press). More details are include
Evolution of superconducting order in Pr(OsRu)Sb
We report measurements of the magnetic penetration depth in single
crystals of Pr(OsRu)Sb down to 0.1 K. Both
and superfluid density exhibit an exponential behavior for the
0.4 samples, going from weak (=0.4,0.6), to moderate, coupling
(=0.8). For the 0.2 samples, both and vary as
at low temperatures, but is s-wave-like at intermediate to
high temperatures. Our data are consistent with a three-phase scenario, where a
fully-gapped phase at undergoes two transitions: first to an
unconventional phase at , then to a nodal low-
phase at , for small values of .Comment: Changed title, enlarged numbering in figures 5 pages, 4 figures, 1
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Effects of Geochemical and Environmental Parameters on Abiotic Organic Chemistry Driven by Iron Hydroxide Minerals
Geological conditions play a significant role in prebiotic/abiotic organic chemistry, especially when reactive minerals are present. Previous studies of the prebiotic synthesis of amino acids and other products in mineralâcontaining systems have shown that a diverse array of compounds can be produced, depending on the experimental conditions. However, these previous experiments have not simulated the effects of varying geochemical conditions, in which factors such as pH, iron redox state, or chemical concentrations may vary over time and space in a natural environment. In geochemical systems that contain overlapping gradients, many permutations of individual conditions could exist and affect the outcome of an organic reaction network. We investigated reactions of pyruvate and glyoxylate, two compounds that are central to the emergence of metabolism, in simulated geological gradients of redox, pH, and ammonia concentration. Our results show that the positioning of pyruvate/glyoxylate reactions in this environmental parameter space determines the organic product distribution that results. Therefore, the distribution pattern of amino acids and alphaâhydroxy acids produced prebiotically in a system reflects the specific reaction conditions, and would be distinct at various locations in an environment depending on local geochemistry. This is significant for origin of life chemistry in which the composition and function of oligomers could be affected by the environmentally driven distribution of monomers available. Also, for astrobiology and planetary science where organic distribution patterns are sometimes considered as a possible biosignature, it is important to consider environmentally driven abiotic organic reactions that might produce similar effects
Demonstration of Bias-Controlled Algorithmic Tuning of Quantum Dots in a Well (DWELL) MidIR Detectors
The quantum-confined Stark effect in intersublevel transitions present in quantum-dots-in-a-well (DWELL) detectors gives rise to a midIR spectral response that is dependent upon the detector\u27s operational bias. The spectral responses resulting from different biases exhibit spectral shifts, albeit with significant spectral overlap. A postprocessing algorithm was developed by Sakoglu that exploited this bias-dependent spectral diversity to predict the continuous and arbitrary tunability of the DWELL detector within certain limits. This paper focuses on the experimental demonstration of the DWELL-based spectral tuning algorithm. It is shown experimentally that it is possible to reconstruct the spectral content of a target electronically without using any dispersive optical elements for tuning, thereby demonstrating a DWELL-based algorithmic spectrometer. The effects of dark current, detector temperature, and bias selection on the tuning capability are also investigated experimentally
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