Spelling suggestions: "subject:"old lines"" "subject:"old eines""
141 |
Geoconservation of abandoned goldmines and granite quarries in the Vredefort Dome World Heritage Site, South Africa / Jacobus Marthinus Jansen van RensburgVan Rensburg, Jacobus Marthinus Jansen January 2012 (has links)
Since the Vredefort Dome‟s listing as a World Heritage Site in June 2005, the area has seen a steady increase in tourists to both the local towns of Parys and Vredefort and the Vredefort Structure. Tourists venturing into the field in an attempt to explore the area have an insatiable appetite for information. By unfolding the gold and granite mining heritage of the area, a world of interesting facts and fables is exposed.
The special geological character of the Vredefort Dome World Heritage Site is enhanced by the mining interventions which started in the 1800s. The mines provide a glimpse into the earth‟s fresh crust which would otherwise have been obscured form the eye of the scientist/researchers, young potential earth scientists and the enquiring tourist.
This study is aimed at identifying, for the first time, the localities of the major mining and quarrying sites in the area. This enabled investigation into and characterization of the exposed sites on the basis of their tourism and academic value. These sites were classified in order to identify those sites that should be made safe, rehabilitated and allowed access to tourists and scientists and those where access should be restricted but made safe in such a way that will allow access to animals and birds.
The value of this initiative with regard to the stimulation of learners‟ scientific needs should not be under-estimated. The wide spectrum of natural, biological and physical sciences can be inspiring. / Thesis (MSc (Environmental Sciences))--North-West University, Potchefstroom Campus, 2013
|
142 |
Geoconservation of abandoned goldmines and granite quarries in the Vredefort Dome World Heritage Site, South Africa / Jacobus Marthinus Jansen van RensburgVan Rensburg, Jacobus Marthinus Jansen January 2012 (has links)
Since the Vredefort Dome‟s listing as a World Heritage Site in June 2005, the area has seen a steady increase in tourists to both the local towns of Parys and Vredefort and the Vredefort Structure. Tourists venturing into the field in an attempt to explore the area have an insatiable appetite for information. By unfolding the gold and granite mining heritage of the area, a world of interesting facts and fables is exposed.
The special geological character of the Vredefort Dome World Heritage Site is enhanced by the mining interventions which started in the 1800s. The mines provide a glimpse into the earth‟s fresh crust which would otherwise have been obscured form the eye of the scientist/researchers, young potential earth scientists and the enquiring tourist.
This study is aimed at identifying, for the first time, the localities of the major mining and quarrying sites in the area. This enabled investigation into and characterization of the exposed sites on the basis of their tourism and academic value. These sites were classified in order to identify those sites that should be made safe, rehabilitated and allowed access to tourists and scientists and those where access should be restricted but made safe in such a way that will allow access to animals and birds.
The value of this initiative with regard to the stimulation of learners‟ scientific needs should not be under-estimated. The wide spectrum of natural, biological and physical sciences can be inspiring. / Thesis (MSc (Environmental Sciences))--North-West University, Potchefstroom Campus, 2013
|
143 |
An Undivided Landscape: Dissolving Apartheid buffer zones in Johannesburg, South AfricaGreyling, Michelle 22 April 2013 (has links)
Progressive spatial segregation of Whites from other ethnic races in South Africa started
in 1886. Apartheid rulers evicted three and a half million Blacks, Coloureds and Indians
from white urban and residential areas between 1904 and 1994. Apartheid planners
used natural, mining, industrial, and infrastructural buffer zones to spatially enforce
segregation. They based their apartheid spatial governance on separation and control
and not on urban development. Today remnants of apartheid remain deeply embedded
in the urban framework, where large buffer zones continue to enforce segregation and
disrupt economic growth.
Victims of apartheid legislation believed the eradication of apartheid in 1994 meant
the right to live in the city and the end of forced evictions. Since then the post-Apartheid
government has conducted 2 million evictions, reminiscent of the 3.5 million evictions
during the apartheid years. In an attempt to make Johannesburg a `world class city`,
the municipality forcefully removed the poor from the city, and relocated them to rural
locations where their livelihoods are severely challenged. To many, a new ``apartheid`
has been born; one that segregates the rich and the poor.
The government has released several strategies to provide land for the poor near the
city, but the high cost of land in urban areas has disrupted implementation.
The thesis proposes a three-fold strategic design intervention to provide land for the
poor near the city and dissolve the apartheid-designed buffer zone between Soweto
and Johannesburg. The site, a landmark from the apartheid spatial legacy and part of
the Witwatersrand gold mining belt, separates Soweto, home to four million Blacks,
from the city of Johannesburg. About one and a half million people commute to the
city each day passing by the 14 km stretch of this toxic mining land.
The thesis proposes three urban design strategies to transform the site into a
community, which the local people would build: Remediation strategies to address
the toxic mining landscape, infrastructural strategies to provide basic services and
economic strategies to promote economic growth. These strategies operate in a codependent
structure. Co-op centres implement these strategies, transfering strategy
technologies to the local community.
|
144 |
Gold from the gods : traditional small-scale miners in the Philippines / Traditional small-scale miners in the PhilippinesCaballero, Evelyn January 1996 (has links)
Includes bibliographical references (p. 241-252) and index. / xxiii, 263 p. ill., maps 23 cm
|
145 |
Geology, hydrothermal alteration, and geographic information system analysis of the Zortman Mine area, MontanaWampler, Peter J. 13 April 1994 (has links)
Graduation date: 1994
|
146 |
Metalloid mobility at historic mine and industrial processing sites in the South Island of New ZealandHaffert, Laura, n/a January 2009 (has links)
Rocks of the South Island of New Zealand are locally enriched in metalloids, namely arsenic (As), antimony (Sb) and boron (B). Elevated levels of As and Sb can be found in sulphide minerals mostly in association with mesothermal gold deposits, whereas B enrichment occurs in marine influenced coal deposits. The mobility of these metalloids is important because they can be toxic at relatively low levels (e.g. for humans >0.01 mg/L of As). Their mobilisation occurs naturally from background weathering of the bedrock. However, mining and processing of coal and gold deposits, New Zealand's most economically important commodities, can significantly increase metalloid mobility. In particular, historic mines and associated industrial sites are known to generate elevated metalloid levels because of the lack of site remediation upon closure. This work defines and quantifies geological, mining, post-mining and regional processes with respect to metalloid, especially As, mobility.
At the studied historic gold mines, the Blackwater and Bullendale mines, Sb levels in mineralised rocks were generally negligible (<14 ppm) compared to As (up to 10,000 ppm). Thus, Sb concentrations in solids and in water were too low to yield any meaningful information on Sb mobility. In contrast, dissolved As concentrations downstream from mine sites were found to be very high (up to 59 mg/L) (background = 10⁻� mg/L). In addition, very high As concentrations were found in residues (up to 40 wt%) and site substrate (up to 30 wt%) at the Blackwater processing sites (background < 0.05 wt%). Here, roasting of the gold ore converted the orginal As mineral, arsenopyrite, into the mineral arsenolite (As[III] trioxide polymorph) and volatilised the sulphur. The resultant sulphur-defficient chemical system is driven by arsenolite dissolution and differs significantly from mine sites where arsenopyrite is the main As source.
Arsenolite is significantly more soluble than arsenopyrite. In the surficial environment, arsenolite dissolution is limited by kinetics only, which are slow enough to preserve exposed arsenolite over decades in a temperate, wet climate. This process results in surface waters with up to ca. 50 mg/L dissolved As. In reducing conditions, dissolved As concentrations are also controlled by the solubility of arsenolite producing As concentrations up to 330 mg/L.
Field based cathodic stripping voltammetry showed that the As[III]/As[V] redox couple, in particular the oxidation of As[III], has a major control on system pH and Eh. Site acidification is mainly caused by the oxidation of As[III], resulting in a close link between As[V] concentrations and pH. Similarly, a strong correlation between calculated (Nernstian) and measured (electrode) Eh was found in the surface environment, suggesting that the overall Eh of the system is, indeed, defined by the As[III]/As[V] redox couple.
Once the metalloid is mobilised from its original source, its mobility is controlled by at least one of the following attenuation processes: (a) precipitation of secondary metalloid minerals, (b) co-precipitation with - or adsorption to - iron oxyhydroxide (HFO), or (c) dilution with background waters. The precipitation of secondary minerals is most favoured in the case of As due to the relatively low solubility of iron arsenates, especially at low pH (~0.1 mg/L). Observations suggest that scorodite can be the precursor phase to more stable iron arsenates, such as kankite, zykaite, bukovskyite or pharmacosiderite and their stability is mainly controlled by pH, sulphur concentrations and moisture prevalence. Empirical evidence indicates that the sulphur-containing minerals zykaite and bukovskyite have a similar pH dependence to scorodite with solubilities slightly lower than scorodite and kankite. If dissolved As concentrations decline, iron arsenates potentially become unstable. Their dissolution maintains a pH between 2.5 and 3.5. This acidification process is pivotal with respect to As mobility, especially in the absence of other acidification processes, because iron arsenates are several orders of magnitude more soluble in circum-neutral pH regimes (~100 mg/L). From this, it becomes apparent that external pH modifications, for example as part of a remediation scheme, can significantly increase iron arsenate solubility and resultant As mobility. In contrast to As, the precipitation of secondary Sb and B minerals is limited by their high solubilities, which are several orders of magnitude higher than for iron arsenates. Thus, secondary Sb and B minerals are restricted to evaporative waters, from which they can easily re-mobilised during rain events.
Metalloid adsorption to HFO is mainly controlled or limited by the extent of HFO formation, which in turn is governed by the availability of Fe and prevailing Eh-pH conditions. Thus, mineralisation styles and associated geochemical gradients, in particular pyrite abundance, can control the amount of HFO and consequent metalloid attenuation, and these can vary even within the same goldfleld. Furthermore, it was found that there is a mineralogical gradation between ferrihydrite with varying amounts of adsorbed As, amorphous iron arsenates and crystalline iron arsenates, suggesting that the maturity of mine waste is an important factor in As mineralogy.
Once dissolved metalloids enter the hydrosphere, dilution is the main control on metalloid attenuation, which is especially pronounced at the inflow of tributaries. Dilution is, therefore, closely related to the size and frequency of these tributaries, which in turn are controlled by the regional topography and climate. Dilution is a considerably less effective attenuation mechanism and anomalous metalloid concentrations from mining related sites can persist for over 10 km downstream.
The complex and often inter-dependent controls on metalloid mobility mean that management decisions should carefully consider the specific site geochemistry to minimize economic, health and environmental risks that can not be afforded.
On a regional scale, background metalloid flux determines the downstream impact of an anomalous metalloid source upstream. For example, the Bullendale mine is located in a mountainous region, where rapidly eroding slopes expose fresh rock and limit the extent of soil cover and chemical weathering. Consequently, the background As flux is relatively low and As point sources, such as the Bullendale mine, present a significant contribution to the downstream As flux. In contrast, the bedrock at the Blackwater mine has undergone deep chemical weathering, resulting in an increased background mobilisation of As. Thus, the Prohibition mill site discharge, for example, contributes only about 10% to the downstream As flux. This information is relevant to site management decisions because the amount of natural background metalloid mobilisation determines whether site remediation will influence downstream metalloid chemistry on a regional scale.
|
147 |
Metalloid mobility at historic mine and industrial processing sites in the South Island of New ZealandHaffert, Laura, n/a January 2009 (has links)
Rocks of the South Island of New Zealand are locally enriched in metalloids, namely arsenic (As), antimony (Sb) and boron (B). Elevated levels of As and Sb can be found in sulphide minerals mostly in association with mesothermal gold deposits, whereas B enrichment occurs in marine influenced coal deposits. The mobility of these metalloids is important because they can be toxic at relatively low levels (e.g. for humans >0.01 mg/L of As). Their mobilisation occurs naturally from background weathering of the bedrock. However, mining and processing of coal and gold deposits, New Zealand's most economically important commodities, can significantly increase metalloid mobility. In particular, historic mines and associated industrial sites are known to generate elevated metalloid levels because of the lack of site remediation upon closure. This work defines and quantifies geological, mining, post-mining and regional processes with respect to metalloid, especially As, mobility.
At the studied historic gold mines, the Blackwater and Bullendale mines, Sb levels in mineralised rocks were generally negligible (<14 ppm) compared to As (up to 10,000 ppm). Thus, Sb concentrations in solids and in water were too low to yield any meaningful information on Sb mobility. In contrast, dissolved As concentrations downstream from mine sites were found to be very high (up to 59 mg/L) (background = 10⁻� mg/L). In addition, very high As concentrations were found in residues (up to 40 wt%) and site substrate (up to 30 wt%) at the Blackwater processing sites (background < 0.05 wt%). Here, roasting of the gold ore converted the orginal As mineral, arsenopyrite, into the mineral arsenolite (As[III] trioxide polymorph) and volatilised the sulphur. The resultant sulphur-defficient chemical system is driven by arsenolite dissolution and differs significantly from mine sites where arsenopyrite is the main As source.
Arsenolite is significantly more soluble than arsenopyrite. In the surficial environment, arsenolite dissolution is limited by kinetics only, which are slow enough to preserve exposed arsenolite over decades in a temperate, wet climate. This process results in surface waters with up to ca. 50 mg/L dissolved As. In reducing conditions, dissolved As concentrations are also controlled by the solubility of arsenolite producing As concentrations up to 330 mg/L.
Field based cathodic stripping voltammetry showed that the As[III]/As[V] redox couple, in particular the oxidation of As[III], has a major control on system pH and Eh. Site acidification is mainly caused by the oxidation of As[III], resulting in a close link between As[V] concentrations and pH. Similarly, a strong correlation between calculated (Nernstian) and measured (electrode) Eh was found in the surface environment, suggesting that the overall Eh of the system is, indeed, defined by the As[III]/As[V] redox couple.
Once the metalloid is mobilised from its original source, its mobility is controlled by at least one of the following attenuation processes: (a) precipitation of secondary metalloid minerals, (b) co-precipitation with - or adsorption to - iron oxyhydroxide (HFO), or (c) dilution with background waters. The precipitation of secondary minerals is most favoured in the case of As due to the relatively low solubility of iron arsenates, especially at low pH (~0.1 mg/L). Observations suggest that scorodite can be the precursor phase to more stable iron arsenates, such as kankite, zykaite, bukovskyite or pharmacosiderite and their stability is mainly controlled by pH, sulphur concentrations and moisture prevalence. Empirical evidence indicates that the sulphur-containing minerals zykaite and bukovskyite have a similar pH dependence to scorodite with solubilities slightly lower than scorodite and kankite. If dissolved As concentrations decline, iron arsenates potentially become unstable. Their dissolution maintains a pH between 2.5 and 3.5. This acidification process is pivotal with respect to As mobility, especially in the absence of other acidification processes, because iron arsenates are several orders of magnitude more soluble in circum-neutral pH regimes (~100 mg/L). From this, it becomes apparent that external pH modifications, for example as part of a remediation scheme, can significantly increase iron arsenate solubility and resultant As mobility. In contrast to As, the precipitation of secondary Sb and B minerals is limited by their high solubilities, which are several orders of magnitude higher than for iron arsenates. Thus, secondary Sb and B minerals are restricted to evaporative waters, from which they can easily re-mobilised during rain events.
Metalloid adsorption to HFO is mainly controlled or limited by the extent of HFO formation, which in turn is governed by the availability of Fe and prevailing Eh-pH conditions. Thus, mineralisation styles and associated geochemical gradients, in particular pyrite abundance, can control the amount of HFO and consequent metalloid attenuation, and these can vary even within the same goldfleld. Furthermore, it was found that there is a mineralogical gradation between ferrihydrite with varying amounts of adsorbed As, amorphous iron arsenates and crystalline iron arsenates, suggesting that the maturity of mine waste is an important factor in As mineralogy.
Once dissolved metalloids enter the hydrosphere, dilution is the main control on metalloid attenuation, which is especially pronounced at the inflow of tributaries. Dilution is, therefore, closely related to the size and frequency of these tributaries, which in turn are controlled by the regional topography and climate. Dilution is a considerably less effective attenuation mechanism and anomalous metalloid concentrations from mining related sites can persist for over 10 km downstream.
The complex and often inter-dependent controls on metalloid mobility mean that management decisions should carefully consider the specific site geochemistry to minimize economic, health and environmental risks that can not be afforded.
On a regional scale, background metalloid flux determines the downstream impact of an anomalous metalloid source upstream. For example, the Bullendale mine is located in a mountainous region, where rapidly eroding slopes expose fresh rock and limit the extent of soil cover and chemical weathering. Consequently, the background As flux is relatively low and As point sources, such as the Bullendale mine, present a significant contribution to the downstream As flux. In contrast, the bedrock at the Blackwater mine has undergone deep chemical weathering, resulting in an increased background mobilisation of As. Thus, the Prohibition mill site discharge, for example, contributes only about 10% to the downstream As flux. This information is relevant to site management decisions because the amount of natural background metalloid mobilisation determines whether site remediation will influence downstream metalloid chemistry on a regional scale.
|
148 |
Sedimentation and desiccation of gold minesWortmann, Heid. January 2007 (has links)
Thesis (MEng.(Geotechnical Engineering)(Civil and Biosystems Engineering)) -- University of Pretoria, 2007. / Thesis in English. Includes bibliographical references.
|
149 |
Chemical mineralogy of cobalt and gold in the Mt Isa block /Munro-Smith, Vera. January 1998 (has links)
Thesis (M. Sc.) (Hons.) -- University of Western Sydney, Nepean, 1998. / Thesis submitted for the degree of Master of Science (Honours) in the University of Western Sydney. Bibliography : p. 100-105.
|
150 |
Local participation in managing water quality problems from artisanal gold mining the Rio Gala Watershed, ecuador /Zhinin, Kristy Lynn. January 2008 (has links)
Thesis (M.A.)--Miami University, Dept. of Geography, 2008. / Title from first page of PDF document. Includes bibliographical references (p.95-104).
|
Page generated in 0.0703 seconds