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An ochreous precipitate isolated from a stream receiving acid-sulfate mine drainage was found to consist primarily of goethite and lesser amounts of ferrihydrite-like materials. The Fe-oxide fraction, including goethite, was almost totally soluble in acid ammonium oxalate. Similar materials were produced in the laboratory by hydrolysis of ferric nitrate solutions containing 250 to 2000 μg/ml sulfate as Na2SO4. Initial precipitates of natrojarosite transformed to Fe-oxides upon aging for 30 days at pH 6.0. The proportion of goethite in the final products decreased with increasing sulfate (SO4/Fe = 0.2 to 1.8) in the initial hydrolysis solutions; only ferrihydrite-like materials were produced at SO4/Fe ratios > 1.5. Variations in SO4/Fe solution ratios also produced systematic changes in the color (10R to 7.5YR) and surface areas (49 to 310 m2/g) of the dried precipitates, even though total S contents were relatively constant at 2.5 to 4.0%.
The Arizona Department of Health Services identified unusually high levels of influenza activity and severe complications during the 2015–2016 influenza season leading to concerns about potential increased disease severity compared with prior seasons. We estimated state-level burden and severity to compare across three seasons using multiple data sources for community-level illness, hospitalisation and death. Severity ratios were calculated as the number of hospitalisations or deaths per community case. Community influenza-like illness rates, hospitalisation rates and mortality rates in 2015–2016 were higher than the previous two seasons. However, ratios of severe disease to community illness were similar. Arizona experienced overall increased disease burden in 2015–2016, but not increased severity compared with prior seasons. Timely estimates of state-specific burden and severity are potentially feasible and may provide important information during seemingly unusual influenza seasons or pandemic situations.
Cerebrovascular reactivity monitoring has been used to identify the lower limit of pressure autoregulation in adult patients with brain injury. We hypothesise that impaired cerebrovascular reactivity and time spent below the lower limit of autoregulation during cardiopulmonary bypass will result in hypoperfusion injuries to the brain detectable by elevation in serum glial fibrillary acidic protein level.
Methods
We designed a multicentre observational pilot study combining concurrent cerebrovascular reactivity and biomarker monitoring during cardiopulmonary bypass. All children undergoing bypass for CHD were eligible. Autoregulation was monitored with the haemoglobin volume index, a moving correlation coefficient between the mean arterial blood pressure and the near-infrared spectroscopy-based trend of cerebral blood volume. Both haemoglobin volume index and glial fibrillary acidic protein data were analysed by phases of bypass. Each patient’s autoregulation curve was analysed to identify the lower limit of autoregulation and optimal arterial blood pressure.
Results
A total of 57 children had autoregulation and biomarker data for all phases of bypass. The mean baseline haemoglobin volume index was 0.084. Haemoglobin volume index increased with lowering of pressure with 82% demonstrating a lower limit of autoregulation (41±9 mmHg), whereas 100% demonstrated optimal blood pressure (48±11 mmHg). There was a significant association between an individual’s peak autoregulation and biomarker values (p=0.01).
Conclusions
Individual, dynamic non-invasive cerebrovascular reactivity monitoring demonstrated transient periods of impairment related to possible silent brain injury. The association between an impaired autoregulation burden and elevation in the serum brain biomarker may identify brain perfusion risk that could result in injury.
The objective of this study was to investigate the effects of a flaxseed-supplemented diet on archaeal abundance and gene expression of methanogens in the rumen of dairy cows. In all, 11 non-lactating dairy cows were randomly divided into two groups: group A (five cows) and B (six cows). The two diets fed were: (1) the control diet, a conventional dry cow ration; and (2) the flaxseed-supplemented diet, the conventional dry cow ration adjusted with 12.16% ground flaxseed incorporated into the total mixed ration. A cross-over experiment was performed with the two groups of cows fed the two different diets for five 21-day periods, which included the first adaptation period followed by two treatment and two wash out periods. At the end of each feeding period, rumen fluid samples were collected via rumenocentesis and DNA was extracted. Quantitative PCR was utilized to analyze the gene abundance of 16S ribosomal RNA (16S rRNA) targeting the ruminal archaea population and the mcrA gene coding for methyl coenzyme-M reductase subunit A, a terminal enzyme in the methanogenesis pathway. Results demonstrated a 49% reduction of 16S rRNA and 50% reduction of mcrA gene abundances in the rumen of dairy cows fed the flaxseed-supplemented diet in comparison with those fed the control diet. This shows flaxseed supplementation effectively decreases the methanogenic population in the rumen. Future studies will focus on the mechanisms for such reduction in the rumen of dairy cattle, as well as the relationship between methanogenic gene expression and methane production.
The current status of SiC bulk growth is reviewed, while specific
attention is given to the effect of defects in SiC substrates and
epitaxial layers on device performance and yield. The progress in SiC
wafer quality is reflected in the achievement of micropipe densities
as low as 0.92 cm−2 for a 3-inch n-type 4H-SiC wafer, which
provides the basis for a high yielding fabrication process
of large area SiC power devices. Using a Murphy Probe Yield Analysis for the
breakdown characteristics of 10 kV PiN diodes we have extracted
an “effective” defect density for 4H-SiC material to be as low as
30 cm−2, providing valuable information to further isolate and
address the specific material defects critical for device performance.
We address the problematic degradation of the forward characteristics
(Vf-drift) of bipolar SiC PiN diodes [CITE].
The underlying mechanism due to stacking fault formation in the epitaxial
layers and possible effects of device processing are investigated.
An improved device design is demonstrated, which effectively stabilizes
this Vf-drift. We show the progression in the development of
semi-insulating SiC grown by the sublimation technique from extrinsically
doped material to high purity semi-insulating (HPSI) 4H-SiC bulk crystals of
up to 100 mm diameter without resorting to the intentional introduction
of elemental deep level dopants, such as vanadium. Uniform resistivities
in 3-inch HPSI wafers greater than 3 × 1011 Ω-cm
have been achieved. Secondary ion mass spectrometry, deep level transient
spectroscopy and electron paramagnetic resonance data suggest that the
semi-insulating behavior in HPSI material originates from deep levels
associated with intrinsic point defects. MESFETs produced on HPSI wafers
are free of backgating effects and have resulted in the best combination of
power density and efficiency reported to date for SiC MESFETs of
5.2 W/mm and 63% power added efficiency (PAE) at 3.5 GHz.
A new synthesis route, based on internal oxidation reactions in multiphase alloys, is proposed for the controlled production of near-surface, complex ceramic-ceramic or ceramic-metallic composite structures. Using this approach, a microdispersion of a complex nitride perovskite, Cr3PtN, was formed in Cr2N or Cr(Pt) by internal nitridation of a two-phase Cr(Pt) + Cr3Pt precursor alloy. A framework for use of this phenomenon to synthesize island micro- (and potentially meso- or nano-) composite functional surface structures is presented.
A design-of-experiments methodology was implemented to assess the commercial equipment viability to fabricate the high-K dielectrics Ta2O5, TiO2 and BST (70/30 and 50/50 compositions) for use as gate dielectrics. The high-K dielectrics were annealed in 100% or 10% O2 for different times and temperatures in conjunction with a previously prepared NH3 nitrided or 14N implanted silicon surface. Five metal electrode configurations—Ta, TaN, W, WN and TiN—were concurrently examined. Three additional silicon surface configurations were explored in conjunction with a more in-depth set of time and temperature anneals for Ta2O5. Electrical characterization of capacitors fabricated with the above high-K gate dielectrics, as well as SIMS and TEM analysis, indicate that the post high-K deposition annealing temperature was the most significant variable impacting the leakage current density, although there was minimal influence on the capacitance. Further studies are required, however, to clarify the physical mechanisms underlying the electrical data presented.
This work describes the development of a new grow-deposit-grow cluster process to grow ultra-thin stacked oxides. Two approaches for stacked oxide synthesis are discussed, namely thermal and chemical stacked oxides. Fabrication of chemical stacked oxide involves forming the first grown layer chemically after pre-gate cleaning, subsequent deposition of a TEOS-SiO2 layer and final densification/oxidation in a single low pressure (LP) furnace operation. In comparison, all three steps for thermal stacked oxide are accomplished by the LP cluster operation. Both processes offer the advantages of reduced cycle time and higher throughput to the stacked gate technology that produces superior Si/SiO2 interfaces and exhibits higher resistance to plasma-damage during ultra large scale integrated circuit (ULSI) processing. The quality and electrical characteristics of the stacked oxides are discussed.
Pipecuronium bromide, a long acting non-depolarizing neuromuscular blocking agent was administered to four groups of 10 patients using the priming technique.The effects of the combination of two different priming doses (0.01 or 0.015 mg kg−1) given at two different time intervals (3 or 4 min) before the ‘main’ intubating dose (0.07 or 0.065 mg kg−1) were investigated. Onset times were recorded and the intubation conditions were scored and compared with a group of patients receiving the same total amount of pipecuronium(0.08 mg kg−1) in a single bolus injection. Intubating conditions at 90 s after administration of the intubating dose were found to be significantly improved in all primed groups but the onset times, evaluated using the response of the adductor pollicis muscle to a single twitch stimulation, were similar to that observed after the single bolus injection. The optimal priming combination is considered to be 0.01 mg kg−1 of pipecuronium followed 3 to 4 min later by 0.07 mg kg−1.
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