logging in or signing up 78 Justine Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 129 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: December 05, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: Geochemistry of Dust in the Proposed Nuclear Waste Repository at Yucca Mountain, Nevada 2004 Annual Meeting of the Geological Society of America Zell E. Peterman, Leonid A. Neymark, and James B. Paces U.S. Geological Survey, Denver CO November 7, 2004 Denver COYucca Mountain is a Ridge of Rhyolitic Tuff in Southern Nevada (Looking South): Yucca Mountain is a Ridge of Rhyolitic Tuff in Southern Nevada (Looking South)ESF Tunnel (Yellow), Cross Drift (Red), and Conceptual Emplacement Drifts (Blue): ESF Tunnel (Yellow), Cross Drift (Red), and Conceptual Emplacement Drifts (Blue)Construction of Underground Space Is a Dirty Business: Construction of Underground Space Is a Dirty Business Dust is the inevitable product of underground mining and construction Fine dust is a health hazard for workers in the underground and must be controlled thru- Ventilation Filtration Generation reduction by wetting at production sitesWhy is Dust Composition Important in a Nuclear Waste Repository? : Why is Dust Composition Important in a Nuclear Waste Repository? Dust will accumulate on waste canisters and drip shields during and after emplacement Dust salts may dissolve in water that drips on canisters or deliquesce in high humidity environments to form brine droplets or films These salts or saline waters may accelerate corrosion of the canistersSources of Underground Dust: Sources of Underground Dust Mining (TBM, Alpine miner, drill and blast, muck haulage) comminution of rock including fracture minerals, vapor-phase minerals, alteration minerals (clays and zeolites) Particulates from diesel exhaust Salts from evaporated water Construction water (tagged with LiBr) Pore water migrates to tunnel walls and evaporates leaving a salt halo Abraded rubber and fiber from conveyor beltsSources of Underground Dust (continued): Sources of Underground Dust (continued) Aerosols from lubricating oil, diesel oil, grease, hydraulic fluids, etc. Ferrous metals from variety of sources Concrete particles from emplacement and abrasion of inverts Salts from human effluents Dust from the surface transported into the Exploratory Studies Facility (ESF) on materials and by the supply air Dust Collection : Dust Collection Dust was vacuumed from the tunnel wall, trapped by a cyclone, and deposited in a 250 mL sample bottle attached to the cyclone Several square meters of surface were vacuumed to yield 200 to 400 grams of dustMethods: Methods Chemistry of bulk dust size fractions by standard rock analysis methods (XRF, ICPMS, gravimetric, titration, combustion) Chemistry of leachates by ion chromatography and ICPMS Mineralogy of soluble salt fraction Scanning electron microscope (SEM) XRD analyses of evaporated leachates Calculation of normative minerals using SALT NORM (Bodine and Jones, 1986)Slide10: Particle Size Distribution of ESF Dust (shown in mesh size)Major and Minor Elements in Dust Size Fractions Relative to Host Rock: Major and Minor Elements in Dust Size Fractions Relative to Host RockTrace Elements in Dust Size Fractions Relative to Host Rock: Trace Elements in Dust Size Fractions Relative to Host RockMajor and Trace Element Enrichments in Dust Relative to Rhyolite: Major and Trace Element Enrichments in Dust Relative to Rhyolite Major Elements FeO (introduced as metallic iron), CO2 (from calcite veins) , Organic C and Cl (neoprene abraded from conveyor belt etc.), and Cl (from water) Trace Elements Bi, Cd, Co, Cr, Mo, Ni, Sb, V, Zn (metallic elements associated with construction and materials introduced during construction)Soluble Fractions of Surface and Underground Dust: Soluble Fractions of Surface and Underground Dust Underground dust contains a small amount of soluble salts Dust in main tunnel contains 0.37±0.18 (1 σ) weight percent (n=66) Dust in cross drift contains 0.17±0.17 (1 σ) weight percent (n=18) Surface dust contains a much larger amount of soluble salts (Reheis, 2003) Atmospheric dust collected at and near Yucca Mountain contains 13.3±8.1 (1 σ) weight percent (n=51) Identification of Salt Minerals in Underground Dust: Identification of Salt Minerals in Underground Dust SEM examination for S and Cl in dust mounts halite, sylvite, gypsum, natroaulnite (also pyrite, molybdenite, native sulfur identified) No CaCl2 was identified XRD analyses of dried leachates halite, sylvite, calcite, gypsum, and bassanite (2CaSO4·H2O) salammoniac NH4Cl mascagnite (NH4)SO4 biphosphammite (NH4,K)H2PO4 weddellite CaC2O4•2H2O Identification of Salt Minerals in Underground Dust (cont’d): Identification of Salt Minerals in Underground Dust (cont’d) Estimation of soluble minerals from water leachates using SALT NORM (Bodine and Jones, 1986) Carbonates (calcite, dolomite, pirsonnite) Nitrates (niter, soda niter, ammonia niter) Sulfates (glauberite, aphthitalite, thenardite, anhydrite, syngenite, mascagnite) Chlorides (halite, sylvite, salammoniac) Fluorides (fluorite, villiaumite) Phosphates (fluorapatite, hydroxyapatite, wagnerite)Salt Minerals Expected from Atmospheric Dust Intrusion into Repository (Chemistry from NADP Red Rocks Site; Minerals from SALT NORM): Salt Minerals Expected from Atmospheric Dust Intrusion into Repository (Chemistry from NADP Red Rocks Site; Minerals from SALT NORM)Salt Minerals Expected from Atmospheric Dust Intrusion into Repository : Salt Minerals Expected from Atmospheric Dust Intrusion into Repository Nitrate-Chloride Ratios: Nitrate-Chloride Ratios Ratio of soluble nitrate-to-chloride is an important parameter for corrosion Critical weight ratio (NO3/Cl) is approximately 0.9 Soluble salts in dust typically have NO3/Cl ratios greater than 0.9 Pore waters typically have NO3/Cl ratios less than 0.9 Nitrate-to-Chloride Weight Ratios in Dust Salts and Pore water: Nitrate-to-Chloride Weight Ratios in Dust Salts and Pore waterConclusions: Conclusions Most of the underground dust is finely comminuted rhyolite Fine silicate particulates will neutralize acids formed in the near-field environment (D. Langmuir, 2004) Soluble salts are more relevant to corrosion issue Soluble salts average less than 1 percent of the underground dust Atmospheric dust contains much larger amounts of soluble salts (average=13.3 weight percent) Nitrate-chloride ratios of both underground and atmospheric dust are favorable (greater than 0.9) No CaCl2 was identified (none expected) You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
78 Justine Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 129 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: December 05, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Slide1: Geochemistry of Dust in the Proposed Nuclear Waste Repository at Yucca Mountain, Nevada 2004 Annual Meeting of the Geological Society of America Zell E. Peterman, Leonid A. Neymark, and James B. Paces U.S. Geological Survey, Denver CO November 7, 2004 Denver COYucca Mountain is a Ridge of Rhyolitic Tuff in Southern Nevada (Looking South): Yucca Mountain is a Ridge of Rhyolitic Tuff in Southern Nevada (Looking South)ESF Tunnel (Yellow), Cross Drift (Red), and Conceptual Emplacement Drifts (Blue): ESF Tunnel (Yellow), Cross Drift (Red), and Conceptual Emplacement Drifts (Blue)Construction of Underground Space Is a Dirty Business: Construction of Underground Space Is a Dirty Business Dust is the inevitable product of underground mining and construction Fine dust is a health hazard for workers in the underground and must be controlled thru- Ventilation Filtration Generation reduction by wetting at production sitesWhy is Dust Composition Important in a Nuclear Waste Repository? : Why is Dust Composition Important in a Nuclear Waste Repository? Dust will accumulate on waste canisters and drip shields during and after emplacement Dust salts may dissolve in water that drips on canisters or deliquesce in high humidity environments to form brine droplets or films These salts or saline waters may accelerate corrosion of the canistersSources of Underground Dust: Sources of Underground Dust Mining (TBM, Alpine miner, drill and blast, muck haulage) comminution of rock including fracture minerals, vapor-phase minerals, alteration minerals (clays and zeolites) Particulates from diesel exhaust Salts from evaporated water Construction water (tagged with LiBr) Pore water migrates to tunnel walls and evaporates leaving a salt halo Abraded rubber and fiber from conveyor beltsSources of Underground Dust (continued): Sources of Underground Dust (continued) Aerosols from lubricating oil, diesel oil, grease, hydraulic fluids, etc. Ferrous metals from variety of sources Concrete particles from emplacement and abrasion of inverts Salts from human effluents Dust from the surface transported into the Exploratory Studies Facility (ESF) on materials and by the supply air Dust Collection : Dust Collection Dust was vacuumed from the tunnel wall, trapped by a cyclone, and deposited in a 250 mL sample bottle attached to the cyclone Several square meters of surface were vacuumed to yield 200 to 400 grams of dustMethods: Methods Chemistry of bulk dust size fractions by standard rock analysis methods (XRF, ICPMS, gravimetric, titration, combustion) Chemistry of leachates by ion chromatography and ICPMS Mineralogy of soluble salt fraction Scanning electron microscope (SEM) XRD analyses of evaporated leachates Calculation of normative minerals using SALT NORM (Bodine and Jones, 1986)Slide10: Particle Size Distribution of ESF Dust (shown in mesh size)Major and Minor Elements in Dust Size Fractions Relative to Host Rock: Major and Minor Elements in Dust Size Fractions Relative to Host RockTrace Elements in Dust Size Fractions Relative to Host Rock: Trace Elements in Dust Size Fractions Relative to Host RockMajor and Trace Element Enrichments in Dust Relative to Rhyolite: Major and Trace Element Enrichments in Dust Relative to Rhyolite Major Elements FeO (introduced as metallic iron), CO2 (from calcite veins) , Organic C and Cl (neoprene abraded from conveyor belt etc.), and Cl (from water) Trace Elements Bi, Cd, Co, Cr, Mo, Ni, Sb, V, Zn (metallic elements associated with construction and materials introduced during construction)Soluble Fractions of Surface and Underground Dust: Soluble Fractions of Surface and Underground Dust Underground dust contains a small amount of soluble salts Dust in main tunnel contains 0.37±0.18 (1 σ) weight percent (n=66) Dust in cross drift contains 0.17±0.17 (1 σ) weight percent (n=18) Surface dust contains a much larger amount of soluble salts (Reheis, 2003) Atmospheric dust collected at and near Yucca Mountain contains 13.3±8.1 (1 σ) weight percent (n=51) Identification of Salt Minerals in Underground Dust: Identification of Salt Minerals in Underground Dust SEM examination for S and Cl in dust mounts halite, sylvite, gypsum, natroaulnite (also pyrite, molybdenite, native sulfur identified) No CaCl2 was identified XRD analyses of dried leachates halite, sylvite, calcite, gypsum, and bassanite (2CaSO4·H2O) salammoniac NH4Cl mascagnite (NH4)SO4 biphosphammite (NH4,K)H2PO4 weddellite CaC2O4•2H2O Identification of Salt Minerals in Underground Dust (cont’d): Identification of Salt Minerals in Underground Dust (cont’d) Estimation of soluble minerals from water leachates using SALT NORM (Bodine and Jones, 1986) Carbonates (calcite, dolomite, pirsonnite) Nitrates (niter, soda niter, ammonia niter) Sulfates (glauberite, aphthitalite, thenardite, anhydrite, syngenite, mascagnite) Chlorides (halite, sylvite, salammoniac) Fluorides (fluorite, villiaumite) Phosphates (fluorapatite, hydroxyapatite, wagnerite)Salt Minerals Expected from Atmospheric Dust Intrusion into Repository (Chemistry from NADP Red Rocks Site; Minerals from SALT NORM): Salt Minerals Expected from Atmospheric Dust Intrusion into Repository (Chemistry from NADP Red Rocks Site; Minerals from SALT NORM)Salt Minerals Expected from Atmospheric Dust Intrusion into Repository : Salt Minerals Expected from Atmospheric Dust Intrusion into Repository Nitrate-Chloride Ratios: Nitrate-Chloride Ratios Ratio of soluble nitrate-to-chloride is an important parameter for corrosion Critical weight ratio (NO3/Cl) is approximately 0.9 Soluble salts in dust typically have NO3/Cl ratios greater than 0.9 Pore waters typically have NO3/Cl ratios less than 0.9 Nitrate-to-Chloride Weight Ratios in Dust Salts and Pore water: Nitrate-to-Chloride Weight Ratios in Dust Salts and Pore waterConclusions: Conclusions Most of the underground dust is finely comminuted rhyolite Fine silicate particulates will neutralize acids formed in the near-field environment (D. Langmuir, 2004) Soluble salts are more relevant to corrosion issue Soluble salts average less than 1 percent of the underground dust Atmospheric dust contains much larger amounts of soluble salts (average=13.3 weight percent) Nitrate-chloride ratios of both underground and atmospheric dust are favorable (greater than 0.9) No CaCl2 was identified (none expected)