Mines Repository (Colorado School of Mines)
Not a member yet
    21416 research outputs found

    Dolomite

    No full text
    Photographed by Ron Wolf.Aggregate of vitreous pale tan dolomite crystals

    Horn coral – Lophophyllidium sp.

    No full text
    Photographed by Ron Wolf.Fossil horn coral (rugosa) showing rough wrinkled exterior

    Sphalerite, galena and quartz

    No full text
    Photographed by Ron Wolf.Green grey sphalerite with grey metallic galena and white glassy quartz

    Tetrahedrite

    No full text
    Photographed by Ron Wolf.Black tetrahedrite with fine yellow coating

    Microbially induced calcium carbonate-based cementation of fractured sandstone

    No full text
    Includes bibliographical references.2024 Fall.Microbially induced calcium carbonate precipitation (MICP) is an emerging ground improvement technology that has the potential to meet the growing demand for grout due to increasing construction activities and to reduce the negative impact of these activities on the environment. However, some of the challenges of this technique include the heterogeneous distribution of the precipitated calcium carbonate and clogging near the injection source, especially due to the difficulties associated with monitoring subsurface bio-treatment. The stability and success of underground projects require an understanding of the mechanical behavior of the grouted fractures, as defects in the grout impact the stability of underground projects and may cause mechanical failure of the grouted rock system. Deficiencies in the grouted rock system may also affect the hydraulic properties of the grouted rock by allowing water to ingress. Therefore, understanding the mechanical and hydraulic behavior of bio-grouted fractured rock is crucial for assessing the potential of MICP as a ground improvement in underground engineering applications. This Ph.D. dissertation describes an extensive experimental program that synthesized different strategies of injecting microorganisms into fractured rock; investigated the effect of different inoculation and incubation conditions on grouting prefabricated fractures; and monitored the bio-cementation process and evaluated the bio-cementation distribution at the pore scale spatiotemporally and non-destructively using nuclear magnetic resonance (NMR). The experimental program also included digital imaging correlation (DIC) technique and computed tomography (μ-CT) imaging to (1) elucidate the failure mechanism of the bio-grouted system under different loading conditions, considering the anisotropic influence of the grouted fracture orientation, and (2) investigate the effects of the bio-grout content on the mechanical and hydraulic properties of the grouted system. A substantial improvement in anti-seepage of fractured rock was achieved due to the homogeneous distribution of calcium carbonate precipitation along the fracture rather than clogging near the injection source. Furthermore, the results revealed that the bio-grout can transfer both tensile and shear stresses while maintaining a strong interfacial bond with the original rock. However, some fracture orientations may not be favorable for the MICP-based grout. Since the reinforcement effect of the bio-grout can be enhanced by increasing the CaCO3 concentration, using a high CaCO3 concentration or using a combination of multiple ground improvement methods may be necessary to reinforce fractures with varied orientation and to ensure the stability of the underground structure. NMR was proven as a non-invasive method that can detect calcium carbonate precipitation, and therefore, has the potential to monitor the MICP process in situ. This study demonstrates some of the possibilities and limitations of MICP-based grout to advance the sustainability of underground engineering

    Mimetite

    No full text
    Photographed by Ron Wolf.Small glassy yellow spikes of mimetite on grey matrix

    Trilobite – Alokistocare subcoronatum

    No full text
    Photographed by Ron Wolf.Brown fossil trilobite on brown matrix

    Payne introduces a critical mineral markets primer

    No full text
    As the urgency for the US and OECD to develop critical minerals supply chains grows, the Payne Institute believes that a fundamental underpinning for that effort will be understanding and expanding market mechanisms that convene buyers and sellers and support mineral price discovery. To that end, we introduce a Critical Minerals Markets primer, a 60-slide PowerPoint document detailing the nature of critical minerals transactions and how such transactions may evolve given technology and market growth

    Wulfenite

    No full text
    Photographed by Ron Wolf.Resinous orange wulfenite on yellow matrix, Rowley mine, near Theba, Maricopa County, Arizona

    Report on Standard Gold Mines, Ltd.

    No full text
    Mine report no. 1996.Typescript (carbon copy).Includes maps, plans, and photographs.Summary and report to Directors of Standard Gold Mines Ltd. / William Sloan -- Copies of certificates of assay -- Report on the Standard Gold mine, Bridge River mining district / by Sydney H. Davis -- Preliminary notes on the Standard mine, Bridge River district, British Columbia / by C. E. Cairns

    4

    full texts

    21,416

    metadata records
    Updated in last 30 days.
    Mines Repository (Colorado School of Mines) is based in United States
    Access Repository Dashboard
    Do you manage Mines Repository (Colorado School of Mines)? Access insider analytics, issue reports and manage access to outputs from your repository in the CORE Repository Dashboard!