Academic literature on the topic 'Arsenian pyrite'
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Journal articles on the topic "Arsenian pyrite"
Gopon, Phillip, James O. Douglas, Maria A. Auger, Lars Hansen, Jon Wade, Jean S. Cline, Laurence J. Robb, and Michael P. Moody. "A Nanoscale Investigation of Carlin-Type Gold Deposits: An Atom-Scale Elemental and Isotopic Perspective." Economic Geology 114, no. 6 (September 1, 2019): 1123–33. http://dx.doi.org/10.5382/econgeo.4676.
Full textFilimonova, Olga, Alexander Trigub, Maximilian Nickolsky, Elena Kovalchuk, Vera Abramova, Mauro Rovezzi, Elena Belogub, Ilya Vikentyev, and Boris Tagirov. "X-ray absorption spectroscopy study of the chemistry of «invisible» Au in arsenian pyrites." E3S Web of Conferences 98 (2019): 05007. http://dx.doi.org/10.1051/e3sconf/20199805007.
Full textFischer, Alicia, James Saunders, Sara Speetjens, Justin Marks, Jim Redwine, Stephanie R. Rogers, Ann S. Ojeda, Md Mahfujur Rahman, Zeki M. Billor, and Ming-Kuo Lee. "Long-Term Arsenic Sequestration in Biogenic Pyrite from Contaminated Groundwater: Insights from Field and Laboratory Studies." Minerals 11, no. 5 (May 19, 2021): 537. http://dx.doi.org/10.3390/min11050537.
Full textStefanova, Elitsa, Milen Kadiyski, Stoyan Georgiev, Atanas Hikov, Sylvina Georgieva, and Irena Peytcheva. "Optical cathodoluminescence petrography, combined with SEM and LA-ICP-MS analyses: a case study from the Elatsite porphyry Cu-Au deposit." Review of the Bulgarian Geological Society 83, no. 3 (December 2022): 117–20. http://dx.doi.org/10.52215/rev.bgs.2022.83.3.117.
Full textReich, Martin, Stephen E. Kesler, Satoshi Utsunomiya, Christopher S. Palenik, Stephen L. Chryssoulis, and Rodney C. Ewing. "Solubility of gold in arsenian pyrite." Geochimica et Cosmochimica Acta 69, no. 11 (June 2005): 2781–96. http://dx.doi.org/10.1016/j.gca.2005.01.011.
Full textStepanov, Aleksandr S., Ross R. Large, Ekaterina S. Kiseeva, Leonid V. Danyushevsky, Karsten Goemann, Sebastien Meffre, Irina Zhukova, and Ivan A. Belousov. "Phase relations of arsenian pyrite and arsenopyrite." Ore Geology Reviews 136 (September 2021): 104285. http://dx.doi.org/10.1016/j.oregeorev.2021.104285.
Full textVoudouris, Panagiotis, Marianna Kati, Andreas Magganas, Manuel Keith, Eugenia Valsami-Jones, Karsten Haase, Reiner Klemd, and Mark Nestmeyer. "Arsenian Pyrite and Cinnabar from Active Submarine Nearshore Vents, Paleochori Bay, Milos Island, Greece." Minerals 11, no. 1 (December 25, 2020): 14. http://dx.doi.org/10.3390/min11010014.
Full textCabri, Louis J., Stephen L. Chryssoulis, John L. Campbell, and William J. Teesdale. "Comparison of in-situ gold analyses in arsenian pyrite." Applied Geochemistry 6, no. 2 (January 1991): 225–30. http://dx.doi.org/10.1016/0883-2927(91)90032-k.
Full textQiu, Guohong, Tianyu Gao, Jun Hong, Yao Luo, Lihu Liu, Wenfeng Tan, and Fan Liu. "Mechanisms of interaction between arsenian pyrite and aqueous arsenite under anoxic and oxic conditions." Geochimica et Cosmochimica Acta 228 (May 2018): 205–19. http://dx.doi.org/10.1016/j.gca.2018.02.051.
Full textDeditius, A. P., S. Utsunomiya, R. C. Ewing, and S. E. Kesler. "Nanoscale "liquid" inclusions of As-Fe-S in arsenian pyrite." American Mineralogist 94, no. 2-3 (February 1, 2009): 391–94. http://dx.doi.org/10.2138/am.2009.3116.
Full textDissertations / Theses on the topic "Arsenian pyrite"
Daniel, Blakemore. "Insights into the History of Pyrite Mineralization at the Round Mountain Gold Mine, Nevada: A Detailed Microanalytical Study of the Type 2 Ore." Miami University / OhioLINK, 2020. http://rave.ohiolink.edu/etdc/view?acc_num=miami15962291791253.
Full textSong, Jin Kun. "Arsenic removal and stabilization by synthesized pyrite." [College Station, Tex. : Texas A&M University, 2008. http://hdl.handle.net/1969.1/ETD-TAMU-3141.
Full textKim, Eun Jung. "Macroscopic and spectroscopic investigation of interactions of arsenic with synthesized pyrite." [College Station, Tex. : Texas A&M University, 2008. http://hdl.handle.net/1969.1/ETD-TAMU-3138.
Full textYao, Xizhi. "Experimental studies on the formation of pyrite and marcasite and the mechanisms of arsenic incorporation." Thesis, Yao, Xizhi (2021) Experimental studies on the formation of pyrite and marcasite and the mechanisms of arsenic incorporation. PhD thesis, Murdoch University, 2021. https://researchrepository.murdoch.edu.au/id/eprint/61494/.
Full textWest, Nicole Renee. "Arsenic Release from Chlorine Promoted Oxidation of Pyrite in the St. Peter Sandstone Aquifer, Eastern Wisconsin." Thesis, Virginia Tech, 2008. http://hdl.handle.net/10919/32451.
Full textThin sections were made from aquifer material collected at Leonardâ s Michael quarry, located in Winnebago County, Wisconsin. Bulk arsenic content of this material was measured as 674 ppm. Quantitative EPMA analysis shows As zoning in pyrite grains with concentrations up to 1 wt. % As. After mineral characterization, the thin sections were exposed to solutions of 60 mg/L â free chlorine,â 1200 mg/L â free chlorine,â and nanopure water (control) at pH 7.0 and pH 8.5 for 24 hours. Thin sections were then analyzed to measure changes in the pyrite surfaces. For solution experiments, aquifer material was crushed to between 250 μm and 355 μm mesh sizes (S.A. ~ 50 cm2/g â 60 cm2/g, Foust et al. 1980) and reacted under the same conditions as the thin sections in a batch reactor. Solution samples were collected periodically during the 24 hour exposure and analyzed for arsenic, iron, and sulfate ion.
Pyrite oxidation is shown to dramatically increase with increasing chlorine concentrations as shown by measurements of released sulfate ion, used here as the reaction progress variable. EPMA maps also reveal complete oxidation of pyrite cements to Fe-oxyhydroxides at 1200 mg/L â free chlorineâ and pH 7.0. This behavior does not occur at lower concentrations or higher pH. Arsenic release to solution does not appear to be directly correlated to increasing chlorine concentrations, but is governed by Fe-oxyhydroxide nucleation, which inhibits the release of dissolved arsenic at higher concentrations of chlorine.
Master of Science
Lazareva, Olesya. "Detailed geochemical and mineralogical analyses of naturally occurring arsenic in the Hawthorn Group." [Tampa, Fla.] : University of South Florida, 2004. http://purl.fcla.edu/fcla/etd/SFE0000521.
Full textBennett, Andrew John. "Relationship between gold and arsenic in hydrothermal pyrite : experimental results and applications to submicroscopic gold in massive sulphide deposits." Thesis, University of Leeds, 2005. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.421978.
Full textJones, Gregg William. "Investigation of the Mechanisms for Mobilization of Arsenic in Two ASR Systems in Southwest Central Florida." Thesis, University of South Florida, 2015. http://pqdtopen.proquest.com/#viewpdf?dispub=3741476.
Full textAquifer storage and recovery (ASR) is a strategy in which water is injected into an aquifer when it is plentiful and pumped from the aquifer when water is scarce. An impediment to ASR in Florida is leaching of naturally-occurring arsenic from limestone of the Upper Floridan Aquifer System (UFAS) into stored water. The concentration of arsenic in surface water, which serves as the recharge water for many ASR systems, and native groundwater is usually much less than 3.0 µ/L. However, data from ASR wells in Florida show that arsenic in recovered water frequently exceeded the 10 µg/L maximum contaminant level (MCL) established by the Environmental Protection Agency and were as high as 130.0 µg/L. The cause of elevated arsenic concentrations is displacement of reduced native groundwater with oxygenated surface water that dissolves arsenic-bearing pyrite in limestone. Although arsenic can be removed from recovered water during final treatment, mobilization of arsenic in the aquifer at levels that exceed the MCL is problematic under federal regulations.
This dissertation investigated a number of aspects of the ASR/arsenic problem to provide additional insights into the mechanisms of arsenic mobilization and measures that could be taken to avoid or reduce the release of arsenic during ASR operations.
Chapter 2, involved development of a geochemical model to simulate an ASR system’s injection of oxygenated surface water into reduced groundwater to determine whether aquifer redox conditions could be altered to the degree of pyrite instability. Increasing amounts of injection water were added to the storage-zone in a series of steps and resulting reaction paths were plotted on pyrite stability diagrams. Unmixed storage-zone water in wells plotted within the pyrite stability field indicating that redox conditions were sufficiently reducing to allow for pyrite stability. Thus arsenic is immobilized in pyrite and its concentration in groundwater should be low. During simulation, as the injection/storage-zone water ratio increased, redox conditions became less reducing and pyrite became unstable. The result would be release of arsenic from limestone into storage-zone water.
Chapter 3 examined the importance of maintaining a substantial volume of stored water around an ASR well to prevent recovery of reduced native groundwater to the vicinity of the well. Depleting the stored water and recovering reduced native groundwater would result in dissolution of arsenic-bearing hydrous ferric oxide (HFO) and release of arsenic into water recovered from the ASR well. Injection/recovery volumes for each cycle for each well were tracked to determine if a substantial volume of stored water was maintained for each cycle or if it was depleted so that reduced native groundwater was brought back to the well. Each well was assigned to either the “storage zone maintained group” where a zone of stored water was established in early cycles and largely maintained through the period of investigation, or the “storage-zone depleted group” where a zone of stored water was either established in later cycles and/or was depleted during the period of investigation. Graphical and statistical analyses verified that maximum arsenic concentrations for storage-zone maintained wells were nearly always lower in each cycle and declined below the MCL after fewer cycles than those of storage-zone depleted wells.
Chapter 4 was a mineralogical investigation of cores located at 20 m (ASR core 1), 152 m (ASR core 2), and 452 m (ASR core 3) from operating ASR wells to determine where mobilized arsenic in limestone is precipitated during ASR. If arsenic is precipitated distally, reduced concentrations of elements in pyrite, (iron, sulfur, arsenic, etc.) would be expected in ASR core 1 relative to more distant cores and there would be noticeable changes in appearance of pyrite crystals due to enhanced oxidation. The results showed that mean concentrations of the elements were lowest in ASR core 2, which did not support distal precipitation. However, scanning electron microscopy identified well-defined pyrite framboids only in core 3 while framboids in ASR cores 1 and 2 were less clear and distinct, indicating pyrite oxidation in cores closest to ASR wells.
Statistical comparison of concentrations of iron, sulfur, and arsenic between the three ASR cores and 19 control cores not subject to ASR, showed that mean concentrations in ASR cores 1 and 2 were statistically similar to concentrations in control cores. This indicated that concentrations in ASR cores 1 and 2 had not been significantly reduced by ASR. The concentrations of elements were higher in ASR core 3 than in ASR cores 1 and 2 and control cores and statistically dissimilar to all but one control core. This indicated natural heterogeneity in core 3 rather than diminution of elements in ASR cores 1 and 2 due to ASR. The statistical analysis supported local precipitation. Once arsenic is mobilized from dissolved pyrite, it is rapidly complexed with precipitated HFO near the well. As long as all of the stored water is not removed during recovery so that reduced native groundwater is brought back to the well, HFO remains stable and complexed with arsenic. The concentration of elements would not have been lowest in ASR core 1 for this reason and because calculations showed that the mass of arsenic removed during recovery events prior to coring was minor compared to the total in limestone surrounding the well. The implications of this are that while large quantities of arsenic are present near the ASR well, only a small percentage may be available for dissolution. Most arsenic occurs with pyrite in limestone, which may insulate it from exposure to oxidized injection water. Water recovered from ASR wells may continue to have low concentrations of arsenic indefinitely because as limestone is dissolved, more pyrite becomes exposed and available for dissolution.
The primary contribution of this dissertation to understanding and overcoming the arsenic problem in ASR systems is the empirical data developed to support or challenge important ASR/arsenic hypotheses. These data were used to 1) establish that background concentrations of arsenic in groundwater of the Suwannee Limestone were less than 1µg/L, 2) demonstrate that redox conditions necessary for pyrite in limestone to become unstable and dissolve occur when oxygenated surface water is injected into the aquifer, 3) demonstrate that the concentration of pyrite in the Suwannee Limestone is spatially variable to a high degree, 4) support the hypothesis that following injection of oxygenated surface water, pyrite in limestone dissolves and releases arsenic into solution and HFO forms and complexes with the arsenic near the ASR well, 5) propose that only a small percentage of pyrite near an ASR well may be available for dissolution during each cycle because most occurs in the limestone matrix and is isolated from injection water, 6) propose that as a result of the previous conclusion, water recovered from ASR systems may continue to have low concentrations of arsenic indefinitely because as limestone that contains pyrite is dissolved with each cycle, additional pyrite is exposed and is available for dissolution, and 7) support the effectiveness of maintaining a zone of stored water in an ASR well as an effective means of minimizing arsenic in recovered water during ASR.
Phan, Thi Hai Van. "L'arsenic dans les écosystèmes du sud-est asiatique : Mekong Delta Vietnam." Thesis, Université Grenoble Alpes (ComUE), 2017. http://www.theses.fr/2017GREAU003/document.
Full textAquifer arsenic (As) contamination is occuring throughout deltaic areas of Southeast Asia, including the Mekong Delta, and affects the health of millions of people. As is highly sensitive to fluctuations of redox conditions which are generated by the alternating wet-dry cycles during the monsoonal seasons. A survey of geophysical and chemical characteristics of soil and groundwater in the An Phu district, located in the vicinity of the Mekong Delta in Vietnam, shows the occurrence high As aqueous concentration in this region. Chemical and geophysical data indicate a strong positive correlation between As concentrations in the anoxic groundwater and conductivity of soils. In addition, mechanisms of As release are shown to be associated with colloidal and iron (oxyhydr)oxides which undergo microbial mediated reductive dissolution under redox oscilatting conditions. The presence of sulfate microbial reduction potentially stabilizes As in the solid phase and diminish As in the aqueous phase through the adsorption/desorption of As onto iron (oxyhydr)oxides and/ or sulfides with formation of thiols complexes in solid phase. Because of the high pyrite content in sediment, pyrite oxidation may drop in pH values, leads to inhibition of sulfate reducing bacteria and reduces sequestration of dissolved As. Although the biogeochemical cycling of redox sensitive species such as As in dynamic systems is challenging, it has been possible to strengthen our collective understanding of such system
Dippold, Angela C. "Detailed Geochemical Investigation of the Mineralogic Associations of Arsenic and Antimony Within the Avon Park Formation, Central Florida: Implications for Aquifer Storage and Recovery." [Tampa, Fla] : University of South Florida, 2009. http://purl.fcla.edu/usf/dc/et/SFE0002992.
Full textBook chapters on the topic "Arsenian pyrite"
Wolthers, M., I. B. Butler, D. Rickard, and P. R. D. Mason. "Arsenic Uptake by Pyrite at Ambient Environmental Conditions: A Continuous-Flow Experiment." In ACS Symposium Series, 60–76. Washington, DC: American Chemical Society, 2005. http://dx.doi.org/10.1021/bk-2005-0915.ch005.
Full textCarbonell-Barrachina, Ángel A., Asunción Rocamora, Carmen García-Gomis, Francisco Martínez-Sánchez,, and Francisco Burló. "Arsenic and Zinc Biogeochemistry in Acidified Pyrite Mine Waste from the Aznalcóllar Environmental Disaster." In ACS Symposium Series, 181–99. Washington, DC: American Chemical Society, 2002. http://dx.doi.org/10.1021/bk-2003-0835.ch014.
Full textDave, Shailesh R., and K. H. Gupta. "Interactions of Acidithiobacillus ferrooxidans with Heavy Metals, Various Forms of Arsenic and Pyrite." In Advanced Materials Research, 423–26. Stafa: Trans Tech Publications Ltd., 2007. http://dx.doi.org/10.4028/0-87849-452-9.423.
Full textDobak, Paul J., François Robert, Shaun L. L. Barker, Jeremy R. Vaughan, and Douglas Eck. "Chapter 15: Goldstrike Gold System, North Carlin Trend, Nevada, USA." In Geology of the World’s Major Gold Deposits and Provinces, 313–34. Society of Economic Geologists, 2020. http://dx.doi.org/10.5382/sp.23.15.
Full textVaughan, Jeremy, Carl E. Nelson, Guillermo Garrido, Jose Polanco, Valery Garcia, and Arturo Macassi. "Chapter 20: The Pueblo Viejo Au-Ag-Cu-(Zn) Deposit, Dominican Republic." In Geology of the World’s Major Gold Deposits and Provinces, 415–30. Society of Economic Geologists, 2020. http://dx.doi.org/10.5382/sp.23.20.
Full textSimmons, Stuart F., Benjamin M. Tutolo, Shaun L. L. Barker, Richard J. Goldfarb, and François Robert. "Chapter 38: Hydrothermal Gold Deposition in Epithermal, Carlin, and Orogenic Deposits." In Geology of the World’s Major Gold Deposits and Provinces, 823–45. Society of Economic Geologists, 2020. http://dx.doi.org/10.5382/sp.23.38.
Full textRickard, David. "Hell and Black Smokers." In Pyrite. Oxford University Press, 2015. http://dx.doi.org/10.1093/oso/9780190203672.003.0009.
Full text"arsenical pyrites." In Dictionary Geotechnical Engineering/Wörterbuch GeoTechnik, 70. Berlin, Heidelberg: Springer Berlin Heidelberg, 2014. http://dx.doi.org/10.1007/978-3-642-41714-6_12723.
Full textMuntean, John L. "Chapter 36: Carlin-Type Gold Deposits in Nevada: Geologic Characteristics, Critical Processes, and Exploration." In Geology of the World’s Major Gold Deposits and Provinces, 775–95. Society of Economic Geologists, 2020. http://dx.doi.org/10.5382/sp.23.36.
Full textLeary, Stephen, Richard H. Sillitoe, Jorge Lema, Fernando Téliz, and Diego Mena. "Chapter 21: Geology of the Fruta del Norte Epithermal Gold-Silver Deposit, Ecuador." In Geology of the World’s Major Gold Deposits and Provinces, 431–50. Society of Economic Geologists, 2020. http://dx.doi.org/10.5382/sp.23.21.
Full textConference papers on the topic "Arsenian pyrite"
Frank, Mark R., Matthew Mann, and Robert J. Bodnar. "A POSSIBLE EXPLANATION FOR THE CORRELATION OF GOLD AND ARSENIC WITHIN PYRITE, ARSENIAN PYRITE, AND ARSENOPYRITE." In 52nd Annual North-Central GSA Section Meeting - 2018. Geological Society of America, 2018. http://dx.doi.org/10.1130/abs/2018nc-312643.
Full textHashimoto, Yohey. "Arsenic Sequestration by Pyrite Framboids." In Goldschmidt2020. Geochemical Society, 2020. http://dx.doi.org/10.46427/gold2020.971.
Full textWilson, Theodore Jeffrey, Eric Levitt, Shahrzad S. Ghandehari, Ming-Kuo Lee, James A. Saunders, Jim Redwine, Justin Marks, et al. "PYRITE BIOMINERALIZATION AND ARSENIC SEQUESTRATION AT A FLORIDA INDUSTRIAL SITE: IMAGING AND GEOCHEMICAL ANALYSIS." In GSA Annual Meeting in Seattle, Washington, USA - 2017. Geological Society of America, 2017. http://dx.doi.org/10.1130/abs/2017am-297861.
Full textZhang, He, Yuanfeng Cai, Gang Sha, Joël Brugger, Allan Pring, Pei Ni, Gujie Qian, Zhenjiao Luo, Yang Zhang, and Wei Tan. "Arsenic Influence on the Distribution and Modes of Occurrence of Gold during the Fluid-Pyrite Interaction: A Case Study of Pyrite from the Qiucun Gold Deposit, China." In Goldschmidt2020. Geochemical Society, 2020. http://dx.doi.org/10.46427/gold2020.3098.
Full textFischer, Alicia, Ming-Kuo Lee, James Saunders, Sara Gilley, Justin Marks, and Jim Redwine. "FIELD AND LABORATORY INVESTIGATIONS OF GROUNDWATER ARSENIC SEQUESTRATION IN BIOGENIC PYRITE AT AN INDUSTRIAL SITE IN FLORIDA." In GSA Annual Meeting in Phoenix, Arizona, USA - 2019. Geological Society of America, 2019. http://dx.doi.org/10.1130/abs/2019am-334367.
Full textFischer, Alicia, James Saunders, Sara Speetjens, Justin Marks, Jim Redwine, Stephanie Rogers, Ann Ojeda, and Ming-Kuo Lee. "FIELD AND LABORATORY INVESTIGATIONS OF GROUNDWATER ARSENIC SEQUESTRATION IN BIOGENIC PYRITE AT AN INDUSTRIAL SITE IN FLORIDA." In Southeastern Section-70th Annual Meeting-2021. Geological Society of America, 2021. http://dx.doi.org/10.1130/abs/2021se-362012.
Full textRahman, Md Mahfujur. "ARSENIC SEQUESTRATION IN NATURALLY OCCURRING BIOGENIC PYRITE IN THE HOLOCENE FLUVIAL AQUIFERS IN UPHAPEE WATERSHED, MACON COUNTY, ALABAMA." In GSA Connects 2021 in Portland, Oregon. Geological Society of America, 2021. http://dx.doi.org/10.1130/abs/2021am-371482.
Full textVietas, J., and G. Talaska. "220. Co-Exposure of Arsenite and Benzo(A)Pyrene: Effect of Glutathione on DNA Adduct Levels." In AIHce 2006. AIHA, 2006. http://dx.doi.org/10.3320/1.2758931.
Full textMeier, B., K. LaDow, B. Schumann, and G. Talaska. "27. Dose-Response of Low Dose Co-Exposures to Arsenic and Benzo[A]Pyrene in Mice." In AIHce 2004. AIHA, 2004. http://dx.doi.org/10.3320/1.2758334.
Full textRddad, Larbi. "ROLE OF EUXINIC CONDITIONS IN ADSORBING ARSENIC IN ORGANIC MATTER AND PYRITE PRESERVED IN THE LOCKATONG FORMATION OF NEWARK: IMPLICATION TO THE QUALITY OF GROUNDWATER." In 51st Annual Northeastern GSA Section Meeting. Geological Society of America, 2016. http://dx.doi.org/10.1130/abs/2016ne-272262.
Full textReports on the topic "Arsenian pyrite"
Kyllönen, Katriina, Karri Saarnio, Ulla Makkonen, and Heidi Hellén. Verification of the validity of air quality measurements related to the Directive 2004/107/EC in 2019-2020 (DIRME2019). Finnish Meteorological Institute, 2020. http://dx.doi.org/10.35614/isbn.9789523361256.
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