1,401 research outputs found
Extracellular glutamate accumulates only in final, ischemic stage of progressive epidural mass lesion in cats
Epidural mass lesions may cause ischemia due to progressive intracranial hypertension. In order to 1) investigate the impact of intracranial pressure (ICP) on accumulation of neuroactive substances, and 2) test the significance of neurochemical monitoring for early prediction of fatal outcome, we gradually raised ICP in cats by inflation of an epidural balloon: We assessed extracellular substrate alterations in the contralateral cortex in relation to changes of ICP, cerebral perfusion pressure (CPP) and mean arterial blood pressure (MABP). In a complementary experiment, regional cerebral blood flow was assessed by sequential positron emission tomography (PET).peer-reviewe
Modeling chemistry in and above snow at Summit, Greenland – Part 1: Model description and results
Sun-lit snow is increasingly recognized as a chemical reactor that plays an active role in uptake, transformation, and release of atmospheric trace gases. Snow is known to influence boundary layer air on a local scale, and given the large global surface coverage of snow may also be significant on regional and global scales. We present a new detailed one-dimensional snow chemistry module that has been coupled to the 1-D atmospheric boundary layer model MISTRA. The new 1-D snow module, which is dynamically coupled to the overlaying atmospheric model, includes heat transport in the snowpack, molecular diffusion, and wind pumping of gases in the interstitial air. The model includes gas phase chemical reactions both in the interstitial air and the atmosphere. Heterogeneous and multiphase chemistry on atmospheric aerosol is considered explicitly. The chemical interaction of interstitial air with snow grains is simulated assuming chemistry in a liquid-like layer (LLL) on the grain surface. The coupled model, referred to as MISTRA-SNOW, was used to investigate snow as the source of nitrogen oxides (NOx) and gas phase reactive bromine in the atmospheric boundary layer in the remote snow covered Arctic (over the Greenland ice sheet) as well as to investigate the link between halogen cycling and ozone depletion that has been observed in interstitial air. The model is validated using data taken 10 June–13 June, 2008 as part of the Greenland Summit Halogen-HOx experiment (GSHOX). The model predicts that reactions involving bromide and nitrate impurities in the surface snow can sustain atmospheric NO and BrO mixing ratios measured at Summit, Greenland during this period
Air–snowpack exchange of bromine, ozone and mercury in the springtime Arctic simulated by the 1-D model PHANTAS – Part 2: Mercury and its speciation
Atmospheric mercury depletion events (AMDEs) refer to a recurring depletion
of mercury occurring in the springtime Arctic (and Antarctic) boundary layer,
in general, concurrently with ozone depletion events (ODEs). To close some of
the knowledge gaps in the physical and chemical mechanisms of AMDEs and ODEs,
we have developed a one-dimensional model that simulates multiphase chemistry
and transport of trace constituents throughout porous snowpack and in the
overlying atmospheric boundary layer (ABL). This paper constitutes Part 2 of
the study, describing the mercury component of the model and its application
to the simulation of AMDEs. Building on model components reported in Part 1
("In-snow bromine activation and its impact on ozone"), we have developed a
chemical mechanism for the redox reactions of mercury in the gas and aqueous
phases with temperature dependent reaction rates and equilibrium constants
accounted for wherever possible. Thus the model allows us to study the
chemical and physical processes taking place during ODEs and AMDEs within a
single framework where two-way interactions between the snowpack and the
atmosphere are simulated in a detailed, process-oriented manner. Model runs
are conducted for meteorological and chemical conditions that represent the
springtime Arctic ABL characterized by the presence of "haze" (sulfate
aerosols) and the saline snowpack on sea ice. The oxidation of gaseous
elemental mercury (GEM) is initiated via reaction with Br-atom to form HgBr,
followed by competitions between its thermal decomposition and further
reactions to give thermally stable Hg(II) products. To shed light on
uncertain kinetics and mechanisms of this multi-step oxidation process, we
have tested different combinations of their rate constants based on published
laboratory and quantum mechanical studies. For some combinations of the rate
constants, the model simulates roughly linear relationships between the
gaseous mercury and ozone concentrations as observed during AMDEs/ODEs by
including the reaction HgBr + BrO and assuming its rate constant to be the
same as for the reaction HgBr + Br, while for other combinations the
results are more realistic by neglecting the reaction HgBr + BrO.
Speciation of gaseous oxidized mercury (GOM) changes significantly depending
on whether or not BrO is assumed to react with HgBr to form Hg(OBr)Br.
Similarly to ozone (reported in Part 1), GEM is depleted via bromine radical
chemistry more vigorously in the snowpack interstitial air than in the
ambient air. However, the impact of such in-snow sink of GEM is found to be
often masked by the re-emissions of GEM from the snow following the
photo-reduction of Hg(II) deposited from the atmosphere. GOM formed in the
ambient air is found to undergo fast "dry deposition" to the snowpack by
being trapped on the snow grains in the top ~1 mm layer. We
hypothesize that liquid-like layers on the surface of snow grains are
connected to create a network throughout the snowpack, thereby facilitating
the vertical diffusion of trace constituents trapped on the snow grains at
much greater rates than one would expect inside solid ice crystals.
Nonetheless, on the timescale of a week simulated in this study, the signal
of atmospheric deposition does not extend notably below the top 1 cm of the
snowpack. We propose and show that particulate-bound mercury (PBM) is
produced mainly as HgBr<sub>4</sub><sup>2−</sup> by taking up GOM into bromide-enriched
aerosols after ozone is significantly depleted in the air mass. In the
Arctic, "haze" aerosols may thus retain PBM in ozone-depleted air masses,
allowing the airborne transport of oxidized mercury from the area of its
production farther than in the form of GOM. Temperature dependence of
thermodynamic constants calculated in this study for Henry's law and
aqueous-phase halide complex formation of Hg(II) species is a critical factor
for this proposition, calling for experimental verification. The proposed
mechanism may explain observed changes in the GOM–PBM partitioning with
seasons, air temperature and the concurrent progress of ozone depletion in
the high Arctic. The net deposition of mercury to the surface snow is shown
to increase with the thickness of the turbulent ABL and to correspond well
with the column amount of BrO in the atmosphere
A box model study on photochemical interactions between VOCs and reactive halogen species in the marine boundary layer
International audienceA new chemical scheme is developed for the multiphase photochemical box model SEAMAC (size-SEgregated Aerosol model for Marine Air Chemistry) to investigate photochemical interactions between volatile organic compounds (VOCs) and reactive halogen species in the marine boundary layer (MBL). Based primarily on critically evaluated kinetic and photochemical rate parameters as well as a protocol for chemical mechanism development, the new scheme has achieved a near-explicit description of oxidative degradation of up to C3-hydrocarbons (CH4, C2H6, C3H8, C2H4, C3H6, and C2H2) initiated by reactions with OH radicals, Cl- and Br-atoms, and O3. Rate constants and product yields for reactions involving halogen species are taken from the literature where available, but the majority of them need to be estimated. In particular, addition reactions of halogen atoms with alkenes will result in forming halogenated organic intermediates, whose photochemical loss rates are carefully evaluated in the present work. Model calculations with the new chemical scheme reveal that the oceanic emissions of acetaldehyde (CH3CHO) and alkenes (especially C3H6) are important factors for regulating reactive halogen chemistry in the MBL by promoting the conversion of Br atoms into HBr or more stable brominated intermediates in the organic form. The latter include brominated hydroperoxides, bromoacetaldehyde, and bromoacetone, which sequester bromine from a reactive inorganic pool. The total mixing ratio of brominated organic species thus produced is likely to reach 10-20% or more of that of inorganic gaseous bromine species over wide regions over the ocean. The reaction between Br atoms and C2H2 is shown to be unimportant for determining the degree of bromine activation in the remote MBL. These results imply that reactive halogen chemistry can mediate a link between the oceanic emissions of VOCs and the behaviors of compounds that are sensitive to halogen chemistry such as dimethyl sulfide, NOx, and O3 in the MBL
Formation of dispersive hybrid bands at an organic-metal interface
An electronic band with quasi-one dimensional dispersion is found at the
interface between a monolayer of a charge-transfer complex (TTF-TCNQ) and a
Au(111) surface. Combined local spectroscopy and numerical calculations show
that the band results from a complex mixing of metal and molecular states. The
molecular layer folds the underlying metal states and mixes with them
selectively, through the TTF component, giving rise to anisotropic hybrid
bands. Our results suggest that, by tuning the components of such molecular
layers, the dimensionality and dispersion of organic-metal interface states can
be engineered
Suppression of the soybean cyst nematode, Heterodera glycines, by short-term field cultivation and soil incorporation of mung bean.
© Koninklijke Brill NV, Leiden, 2021. This is the accepted manuscript version of an article which has been published in final form at https://doi.org/10.1163/15685411-bja10042Our previous study using pots reported that short-term growth of mung bean (Vigna radiata) may be useful to decrease the density of the soybean cyst nematode (SCN), Heterodera glycines, in soil. The objective of this study was to determine whether short-term growth of mung bean and its incorporation by ploughing decreased SCN density in infested fields. Firstly, we did pot experiments to evaluate the optimum temperature and moisture for hatching in soil. SCN hatching was stimulated at 25 and 30°C and not at 20°C; however, it was stimulated at alternating temperature conditions between 20 and 25°C. Soil moisture levels with pF 2.76 or less were required to stimulate SCN hatch in soil. Field experiments were done in Saitama, Kanagawa and Nara Prefectures, Japan. SCN density was reduced by nearly half even in control plots, in which mung bean was not cultivated and ploughed, in Saitama and Nara Prefectures. However, SCN density was reduced by nearly 80% or more in the three Prefectures, except for one plot in Kanagawa, and the soil temperature and moisture conditions were kept at around 20-30°C and at <pF 2.8. Increase in yield of green soybean by SCN control was estimated at 350 kg (1000 m)−2. Overall, the present study revealed that short-term field cultivation of mung bean and ploughing was a profitable method to decrease SCN density in infested fields and thereby to increase yield of green soybean.Peer reviewedFinal Accepted Versio
Effect of cold-water irrigation on bacterial wilt pathogen of tomato.
Bacterial wilt caused by Ralstonia solanacearum is one of the most devastating bacterial diseases of plants worldwide. Management of bacterial wilt in tomato and other crops has been difficult, and so novel but easily implemented control methods are being sought. To evaluate the effect of cold-water irrigation on bacterial wilt of tomato, four treatments were used in which CF (chemically fertilized) soil and CF + FYM (chemical fertilizer + farmyard manure [FYM]) soil were inoculated with a bacterial suspension (R. solanacearum strain YU1Rif43) at 106 colony forming units (CFU) g−1 soil. Tomato seedlings were grown in Agri-pots in a plant growth chamber. The soil was irrigated with water that was kept at the same temperature in each treatment: 4, 10, 20, or 30°C. Incidence and severity of wilt, counting of the colonies of the culturable population of pathogen, and dry-mass and height of the plants were examined. After 45 days and in both kinds of soil, most of the plants had wilted in soil irrigated at 30°C. Wilt incidence was substantially reduced when transplanted seedlings were irrigated at lower temperatures (4–20°C). Survival of R. solanacearum was also reduced after being irrigated with water at lower temperatures, indicating that the reduced incidence of wilt was linked to reduced survival of the pathogen. Dry-mass and plant height were slightly higher under control conditions than in soils irrigated at lower temperatures. This study suggests that cold-water irrigation could significantly reduce bacterial wilt of tomato and have an adverse effect on survival of the wilt pathogen
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