1,317 research outputs found
Residual hepatic disease subsequent to viral hepatitis : with emphasis on diagnosis and diagnostic methods
The oxidation of ascorbic acid and its reduction in vitro and in vivo
The outstanding chemical property of ascorbic acid (vitamin C) is that it is a reducing agent. The suggestion is obvious that its physiological function may be associated with this property, and, if it is oxidized reversibly, with its behavior in an oxidation-reduction system. It is desirable therefore to know the oxidation-reduction potential of ascorbic acid
Room-temperature exciton-polaritons with two-dimensional WS2
Two-dimensional transition metal dichalcogenides exhibit strong optical
transitions with significant potential for optoelectronic devices. In
particular they are suited for cavity quantum electrodynamics in which strong
coupling leads to polariton formation as a root to realisation of inversionless
lasing, polariton condensationand superfluidity. Demonstrations of such
strongly correlated phenomena to date have often relied on cryogenic
temperatures, high excitation densities and were frequently impaired by strong
material disorder. At room-temperature, experiments approaching the strong
coupling regime with transition metal dichalcogenides have been reported, but
well resolved exciton-polaritons have yet to be achieved. Here we report a
study of monolayer WS coupled to an open Fabry-Perot cavity at
room-temperature, in which polariton eigenstates are unambiguously displayed.
In-situ tunability of the cavity length results in a maximal Rabi splitting of
meV, exceeding the exciton linewidth. Our data
are well described by a transfer matrix model appropriate for the large
linewidth regime. This work provides a platform towards observing strongly
correlated polariton phenomena in compact photonic devices for ambient
temperature applications.Comment: 12 pages, 6 figure
Modeling Surface and Subsurface Pesticide Transport Under Three Field Conditions Using PRZM-3 and GLEAMS
Contaminant transport models should be evaluated over a wide range of conditions to determine their limitations. The models PRZM and GLEAMS have been evaluated many times, but few studies are available in which predicted movement in runoff and percolate were simultaneously evaluated against field data. Studies of this type are essential because pesticide leaching and runoff are mutually dependent processes. For this reason, PRZM-3 and GLEAMS were evaluated for their ability to predict metribuzin concentrations in runoff, sediment, subsurface soil, and pan lysimeters under three field conditions (yard waste compost amended, no-till, and conventional-till) on a Lowell silt loam soil. Sensitive input parameters were either site specific (climatic, soil, and chemical) or calibrated (K-factor, C-factor, curve number). In general, both models under-predicted metribuzin concentration in runoff water, runoff sediment, subplow layer soil (15-75 cm), and pan lysimeter water (75 cm). Contrary to field data, both models predicted that a large percentage (\u3e 50%) of metribuzin would move below the “mixing zone” (top 1 cm) during the first rainfall event after application. Relatively little metribuzin was predicted to move beyond the plow layer (top 15 cm) into the pan lysimeters or subsurface soil throughout the simulation period, possibly due to the lack of a macropore component in the models. High metribuzin concentrations in sediment (field data) indicated that relatively little metribuzin moved below the “mixing zone”, possibly because of hysteresis but much of the metribuzin that did move was quickly transported into the pan lysimeters, probably due to macropore flow. GLEAMS more accurately predicted pesticide concentration in sediment and PRZM predicted subsurface soil concentration somewhat more accurately than GLEAMS. Little difference in accuracy was detected between models on metribuzin concentration in runoff or metribuzin concentration in percolate. Although both models generally under-predicted metribuzin concentration in runoff, runoff transport (mass of metribuzin in runoff) for the study period was over-predicted by both models which emphasizes the importance of accurately predicting herbicide concentration and runoff volume soon after application when the surface pesticide concentrations are highest
InfoRio, focus group sessions to test potential for a personal real time travel information concept for public transport, (no 03071, 23 p.)
Nitrate Transport Is Independent of NADH and NAD(P)H Nitrate Reductases in Barley Seedlings
Strain Hardening of Polymer Glasses: Entanglements, Energetics, and Plasticity
Simulations are used to examine the microscopic origins of strain hardening
in polymer glasses. While stress-strain curves for a wide range of temperature
can be fit to the functional form predicted by entropic network models, many
other results are fundamentally inconsistent with the physical picture
underlying these models. Stresses are too large to be entropic and have the
wrong trend with temperature. The most dramatic hardening at large strains
reflects increases in energy as chains are pulled taut between entanglements
rather than a change in entropy. A weak entropic stress is only observed in
shape recovery of deformed samples when heated above the glass transition.
While short chains do not form an entangled network, they exhibit partial shape
recovery, orientation, and strain hardening. Stresses for all chain lengths
collapse when plotted against a microscopic measure of chain stretching rather
than the macroscopic stretch. The thermal contribution to the stress is
directly proportional to the rate of plasticity as measured by breaking and
reforming of interchain bonds. These observations suggest that the correct
microscopic theory of strain hardening should be based on glassy state physics
rather than rubber elasticity.Comment: 15 pages, 12 figures: significant revision
Investigating Coral Bleaching in a Changing Climate: Our State of Understanding and Opportunities to Push the Field Forward
[First Paragraph]
Coral reefs throughout the world are facing the consequences of large-scale changes in Earth’s climate. In particular, ocean warming is leading to frequent coral bleaching, which is threatening the long-term stability of coral reefs. Coral bleaching is a stress response that results in the disassociation of the mutualistic symbioses (i.e., dysbiosis) between corals and their endosymbiotic algae (Symbiodinium spp.). In the past two decades, there have been four substantial bleaching events, which have affected large geographic areas across the globe, including the worst recorded bleaching event on the Great Barrier Reef in 2016 (Berkelmans et al. 2004; Eakin et al. 2010; Stella et al. 2016). These large-scale bleaching events, in combination with many local-scale stressors, have contributed substantially to global declines in coral populations. In addition, bleaching may lead to compromised coral immunity, possibly resulting in additional mortality by a range of post-bleaching diseases (Maynard et al. 2015, Randall et al. 2014). Given their link to patterns of global-climate change and projections of increased warming in the coming decades, mass coral bleaching events are a key concern. In addition, current climate projections estimate that global bleaching is expected to occur annually by late this century, with more than 90% of reefs facing long-term degradation (Frieler et al. 2012). Furthermore, in locations such as the Caribbean, frequent thermal anomalies and consecutive annual bleaching events are expected to be common in less than 25 years (van Hooidonk et al. 2015). In fact, large-scale bleaching two years in a row was documented for the first time in 2014-2015 in Hawaii and in the Florida Keys. However, not all corals (and other symbiotic cnidarians) are equally susceptible to thermal stress, and some corals have been shown to recover from bleaching more quickly than others. Likewise, not all reefs are equally susceptible, and depending on local conditions, susceptibility can vary from one event to the next. Such variability in resilience could be a cornerstone to reef persistence over the coming century. However, the research needed to test this hypothesis remains to be performed
Revisiting the proposed planetary system orbiting the eclipsing polar HU Aquarii
It has recently been proposed, on the basis of eclipse-timing data, that the
eclipsing polar cataclysmic variable HU Aquarii is host to at least two giant
planets. However, that result has been called into question based upon the
dynamical stability of the proposed planets. In this work, we present a
detailed re-analysis of all eclipse timing data available for the HU Aquarii
system, making use of standard techniques used to fit orbits to radial-velocity
data. We find that the eclipse timings can be used to obtain a two-planet
solution that does not require the presence of additional bodies within the
system. We then perform a highly detailed dynamical analysis of the proposed
planetary system. We show that the improved orbital parameters we have derived
correspond to planets that are dynamically unstable on unfeasibly short
timescales (of order 10^4 years or less). Given these results, we discuss
briefly how the observed signal might in fact be the result of the intrinsic
properties of the eclipsing polar, rather than being evidence of dynamically
improbable planets. Taken in concert, our results highlight the need for
caution in interpreting such timing variations as being planetary in nature.Comment: Accepted for publication in MNRA
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