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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
81

Absorption of chlorine and mercury in sulfite solutions

Roy, Sharmistha 23 May 2011 (has links)
Not available / text
82

A STUDY OF THE ELECTRODEPOSITION OF METALS FROM AQUEOUS SOLUTIONS USING MERCURY CATHODES

Nelson, Roger Raymond, 1921- January 1963 (has links)
No description available.
83

PRODUCTION OF METASTABLE HG ATOMS BY CHARGE EXCHANGE

Rostron, Robert Walther, 1937- January 1964 (has links)
No description available.
84

Nuclear structure of ¹⁹⁰Hg

De Shon, Markus M. 05 1900 (has links)
No description available.
85

The effects of core-mantle gravitational coupling on the rotational dynamics of Mercury

Veasey, Martin James Unknown Date
No description available.
86

Mercury in the Lower Athabasca River and its Watershed

Radmanovich, Roseanna Unknown Date
No description available.
87

Diffusion of mercury into silver-tin dental alloy (Ag[subscript 3]Sn) including the effect of ultrasonic energy

Freiman, S. W. 08 1900 (has links)
No description available.
88

Cardiovascular effects of lead and mercury and their mixtures in rats

2015 April 1900 (has links)
Cardiovascular diseases are the major cause of death worldwide. It is a group of diseases, which affect the heart, the vasculature and the brain. Lifestyle and metabolic risk factors are major contributors to cardiovascular ill-health. In addition to these risk factors, a growing number of scientific studies show that some environmental pollutants, e.g. lead and mercury, can adversely affect cardiovascular health. Despite the increasing amount of knowledge from human and animal studies, cardiovascular effects of lead, mercury species or their mixtures are not well understood. It is also unknown if safe exposure thresholds for these metals exist or the underlying mechanisms of action for the elicitation of cardiovascular toxicity. The first set of studies had the objectives to elucidate the range of effects of single exposure to lead, inorganic mercury or methylmercury on the cardiovascular system. Therefore, male Wistar rats were exposed to a broad range of doses of lead, inorganic mercury or methylmercury for four weeks through the drinking water. Cardiovascular health of the rats was assessed by measuring the blood pressure and the cardiac electrical activity after four weeks of exposure, while the heart function and blood flow in the carotid artery was measured at baseline and at the end of the exposure duration. The study showed that all three metals differ in their effects on the cardiovascular system. Lead showed bi-phasic dose-response curves for several cardiovascular end-points. No cardiovascular effects were observed for inorganic mercury, while methylmercury showed linear dose-response curves. Based on these results, safe levels of exposure for lead and methylmercury were derived. The second study applied the same experimental design as the previous study in order to investigate the cardiovascular effects of combined exposures to lead, inorganic mercury and methylmercury. The mixture ratios were based on reference and exposure values published in the scientific literature. The adverse cardiovascular effects, which were observed for single exposures were reversed for the mixtures indicating antagonism. In contrast to single exposures, mixtures negatively affected the electrical activity of the heart (synergism), which could lead to arrhythmias and heart failure. The third set of studies focused on the exploration of oxidative stress, kidney function and damage, and global DNA methylation as potential mechanisms of action for the development of elevated blood pressure. Results for lead showed an increase in oxidative stress but not mercury. While only lead was associated with kidney damage, only inorganic mercury was related to altered global DNA methylation. Methylmercury appears to elevate blood pressure through a not investigated mechanism. Therefore, oxidative stress and kidney damage seem to be associated with elevated blood pressure but not global DNA methylation. Overall, the research presented in this thesis shows that lead, inorganic mercury and methylmercury and their mixtures have the ability to adversely affect the cardiovascular system. However, each metal affected the cardiovascular system differently and surprisingly, mixtures showed antagonism or synergism depending on the examined end-point, which was reflected in the results of the mechanistic study. As health problems of the cardiovascular system, e.g. hypertension, occur mainly in the adult population and in particular the elderly, cardiovascular effects should be considered as an important end-point for this age group in addition to neurodevelopmental effects in children.
89

Acute nephrotoxic effects of mercury and other metals in vivo and in vitro

Wilks, Martin F. January 1990 (has links)
No description available.
90

Performance of Treatment Media for the Stabilization of Mercury under Variable Geochemical Conditions

Daugherty, Shannon 06 November 2014 (has links)
Mercury-contaminated sediments are found in many locations throughout North America and the world. Release of Hg from such sediments and subsequent biological uptake can result in biomagnification in associated ecosystems. This study focused specifically on a stabilization technique involving the addition of reactive media to the sediment matrix to immobilize Hg and reduce its bioavailability. A series of batch and column experiments was conducted over a range of physical and geochemical conditions to evaluate the propensity of a diverse set of reactive media to stabilize Hg in sediment with high organic carbon and clay content. The additives, selected to promote adsorption and precipitation of Hg, included natural attapulgite (palygorskite) clay, organically-modified clay, elemental sulfur, a strong reductant, and mixtures thereof. The results of the batch experiments indicated that addition of reactive media to the sediment led to substantially lower aqueous concentrations of Hg relative to untreated sediment. The stabilization of Hg was observed to be dependent on mass of added reagent, with generally greater treatment observed for the higher masses of reagent evaluated. Aqueous concentrations of Hg were reduced from > 800 ng L-1 in control samples to < 50 ng L-1 in treated samples for all of the reactive media at the highest mass proportions evaluated. The effectiveness of Hg stabilization using the sulfur-based blends was strongly affected by contact with atmospheric oxygen, with better treatment observed in oxygen-limited conditions. The results of the column tests showed that relatively low concentrations of Hg (< 50 ng L-1) were leached from untreated sediment, maintained under anoxic conditions, with steadily percolating water. However, increased concentrations of Hg (> 200 ng L-1) were observed in column effluent collected from the untreated sediment following flow interruption. This release of high concentrations of Hg was not observed for the columns containing treated sediment after stagnation. Particularly low Hg concentrations were maintained in effluent collected from the sulfur-based treatment mixtures (< 40 ng Hg L-1) for the entirety of the experimental duration, regardless of flow perturbations.

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