Calcretes aus jungpaläozoischen Bodenbildungen - ein möglicher Proxy für die CO₂-Konzentration der Paläoatmosphäre / Calcretes in Late Paleozoic soils - a possible proxy of CO₂-concentration in paleoatmosphere

Quast, Andres

29 January 2003

No description available.

550 Geowissenschaften

Mathematics and Computer Science

Calcretes

Kohlenstoff-Isotopie

Jungpaläozoikum

Paläoböden

pedogene Karbonate

atmospheric CO₂

calcretes

carbon isotope

Late Paleozoic

paleosols

pedogenic carbonates

38.32

38.41

VKB 330: Sedimentation

VJJ 100: Isotopengeochemie

Plate Tectonic Evolution and Mineral Resource Potential of the Lancang River Zone, Southwestern Yunnan, People's Republic of China / Plattentektonische und metallogenetische Entwicklung der Lancang River-Zone, Südwest-Yunnan, Volksrepublik China

Heppe, Klaus

09 June 2004

No description available.

550 Geowissenschaften

Mathematics and Computer Science

Yunnan

China

Yangtze-Plattform

Lancangjiang

Tethys

Paläozoikum

Mesozoikum

Geodynamik

Kontinentalrand

metallogenetische Entwicklung

Yunnan

China

Yangtze Platform

Lancangjiang

Tethys

Paleozoic

Mesozoic

geodynamics

continental margin analysis

mineral resource potential

38.36

38.50

VBT 000

VAE 100: Strukturgeologie {Geologie}

VQC 000: Lagerstättengenese

VQB 000: Wirtschaftsgeologie

VEL 100: China {Geologie}

VTL 100: China {Rohstoffgeologie}

オ-ストラリア東部のニュ-イングランド造山帯と日本の中・古生代造山帯の比較研究

Wilkins, C., DAVIES, P., Aitchison, J., 鈴木, 和博, 水谷, 伸治郎, 足立, 守, 小嶋, 智

03 1900

科学研究費補助金 研究種目:国際学術研究 課題番号:06045017 研究代表者:鈴木 和博 研究期間:1994-1995年度

Australia

New England orogen

Paleozoic

Radiolaria

ultramafic dike

オ-ストラリア

シドニ-盆地

テレ-ン解析

ニュ-イングランド

ニュ-イングランド造山帯

古生代

変動帯

大陸縁辺部

放散虫

研究史

超塩基性岩

超苦鉄質ダイク

The Mineralogical Composition of House Dust in Ontario, Canada

Woldemichael, Michael Haile

01 February 2012

Despite increasing concern about the presence of heavy metals, pesticides and other toxins in indoor environments, very little is known about the physical and chemical composition of ordinary household dust. This study represents the first systematic investigation of the mineralogical composition of indoor dust in residential housing in Canada. Specimens of dust were obtained from homes in six geographically separate cities in the Province of Ontario: two located on the metamorphic and igneous rocks of the Precambrian Canadian Shield (Thunder Bay and Sudbury), the other four located on Palaeozoic limestone and shale dominated bedrock (Barrie, Burlington, Cambridge, and Hamilton). Forty samples of household vacuum dust were obtained. The coarse fraction (80 – 300 µm) of this dust was subjected to flotation (using water) to separate the organic components (e.g. insect fragments, dander), natural and synthetic materials (e.g. fibres, plastics) from the mineral residue. The mineral fraction was then analyzed using quantitative point counting, polarizing light microscopy, powder X-ray diffraction and scanning electron microscopy methods. Despite the great distances between the sampling localities and the distinct differences in bedrock geology, the mineral fraction of dust from all six cities is remarkably similar and dominated by quartz and feldspar, followed by lithic fragments, calcite, and amphibole. Some evidence of the influence of local geology can nevertheless be found. For example, a relatively higher proportion of sulphide minerals is observed in the two cities on the Canadian Shield where these minerals are clearly more abundant in the bedrock. Specimens from Sudbury, Canada’s largest mining centre located atop a nickel-sulphide mineral deposit, showed the highest sulphide contents. Quartz is the dominant mineral in all cities. All quartz grains have internal strain features and fluid inclusions that are indicative of a metamorphic-igneous provenance. In all cities, sand is used on the streets as an abrasive for traction during the icy winter season. This sand is obtained in all cases from local glaciofluvial deposits that were ultimately derived principally from the rocks of the Canadian Shield in the last Pleistocene glaciations that affected all of Ontario. Thus, tracking in sand is the most plausible mechanism by which quartz was introduced into these homes since sampling was done, in all cases, in the winter season. The results indicate that glacial deposits dominate the mineral composition of indoor dust in Ontario cities and that nature of the bedrock immediately underlying the sampling sites is relatively of minor importance.

House dust

Feldspars

Lithic fragments

Carbonate minerals

Amphibole

Environmental health

Glacial deposits

Scanning electron microscopy

Polarized light microscopy

Canadian Shield

St. Lawrence Platform

Paleozoic

Precambrian

Medical Geology

Quartz in house dust

Sand in house dust

Minerals in house dust

Thunder Bay, Ontario

Sudbury, Ontario

Barrie, Ontario

Burlington, Ontario

Cambridge, Ontario

Hamilton,Ontario

The Mineralogical Composition of House Dust in Ontario, Canada

Woldemichael, Michael Haile

January 2012

Despite increasing concern about the presence of heavy metals, pesticides and other toxins in indoor environments, very little is known about the physical and chemical composition of ordinary household dust. This study represents the first systematic investigation of the mineralogical composition of indoor dust in residential housing in Canada. Specimens of dust were obtained from homes in six geographically separate cities in the Province of Ontario: two located on the metamorphic and igneous rocks of the Precambrian Canadian Shield (Thunder Bay and Sudbury), the other four located on Palaeozoic limestone and shale dominated bedrock (Barrie, Burlington, Cambridge, and Hamilton). Forty samples of household vacuum dust were obtained. The coarse fraction (80 – 300 µm) of this dust was subjected to flotation (using water) to separate the organic components (e.g. insect fragments, dander), natural and synthetic materials (e.g. fibres, plastics) from the mineral residue. The mineral fraction was then analyzed using quantitative point counting, polarizing light microscopy, powder X-ray diffraction and scanning electron microscopy methods. Despite the great distances between the sampling localities and the distinct differences in bedrock geology, the mineral fraction of dust from all six cities is remarkably similar and dominated by quartz and feldspar, followed by lithic fragments, calcite, and amphibole. Some evidence of the influence of local geology can nevertheless be found. For example, a relatively higher proportion of sulphide minerals is observed in the two cities on the Canadian Shield where these minerals are clearly more abundant in the bedrock. Specimens from Sudbury, Canada’s largest mining centre located atop a nickel-sulphide mineral deposit, showed the highest sulphide contents. Quartz is the dominant mineral in all cities. All quartz grains have internal strain features and fluid inclusions that are indicative of a metamorphic-igneous provenance. In all cities, sand is used on the streets as an abrasive for traction during the icy winter season. This sand is obtained in all cases from local glaciofluvial deposits that were ultimately derived principally from the rocks of the Canadian Shield in the last Pleistocene glaciations that affected all of Ontario. Thus, tracking in sand is the most plausible mechanism by which quartz was introduced into these homes since sampling was done, in all cases, in the winter season. The results indicate that glacial deposits dominate the mineral composition of indoor dust in Ontario cities and that nature of the bedrock immediately underlying the sampling sites is relatively of minor importance.

House dust

Feldspars

Lithic fragments

Carbonate minerals

Amphibole

Environmental health

Glacial deposits

Scanning electron microscopy

Polarized light microscopy

Canadian Shield

St. Lawrence Platform

Paleozoic

Precambrian

Medical Geology

Quartz in house dust

Sand in house dust

Minerals in house dust

Thunder Bay, Ontario

Sudbury, Ontario

Barrie, Ontario

Burlington, Ontario

Cambridge, Ontario

Hamilton,Ontario

DETRITAL RECORD OF PALEOZOIC AND MESOZOIC TECTONICS OF THE NORTHWESTERN CORDILLERAN MARGIN: A CENTRAL ALASKAN PERSPECTIVE

Lukas Geiger-Rigby McCreary (18824572)

14 June 2024

<p dir="ltr">The Intermontane terranes represent one of the largest composite accreted terranes that built the northern Cordillera. To better understand the interactions between the continental margin of Laurentia and the Intermontane terranes, this study analyzes twelve detrital zircon samples (n=3232) from a Neoproterozoic (?) to Cretaceous metasedimentary stratigraphic section exposed in central Alaska. Distinct detrital zircon populations have been identified and are interpreted to represent four stages in the geologic development of this part of western North America. Stage 1 extends from the Neoproterozoic (?) to the Early Paleozoic, and is characterized by Proterozoic and Archean detrital zircon populations that correlate with Laurentian sources of sediment. We interpret Stage 1 to represent deposition along the northwestern continental margin of Laurentia. Stage 2 extends from the Silurian (?) to the Devonian and is characterized by a dominant Devonian and Silurian detrital zircon population. We interpret Stage 2 to have been deposited in a backarc basin coeval with active volcanism as the Yukon-Tanana terrane was rifted away from the Laurentian continental margin as the Slide Mountain Ocean opened. Stage 3 extends from the Mississippian to the Jurassic and records a shift back to sediment sources with abundant Proterozoic and Archean zircon. We interpret this stage to represent deposition of Laurentian detritus along the eastern margin of the Slide Mountain Ocean basin. Stage 4 is represented by the Lower Cretaceous strata of the Manley basin that contain one major Late Triassic to Early Jurassic detrital zircon population. We interpret this population to be sourced from the syn-collisional and post-collisional Late Triassic to Early Jurassic plutons and related sedimentary basins of the Intermontane terranes that were exhumed and eroded during the closure of the Slide Mountain Ocean and the subsequent collision with the Laurentian continental margin. We interpret the Manley basin as a syn- to post-collisional extensional basin associated with regional detachment faults that formed because of crustal thickening in the collisional zone. From a regional perspective, an extensive clastic wedge prograded northward away from the zone of crustal thickening and can be identified in a series of Mesozoic sedimentary basins that are discontinuously exposed over 1500 km in southern Alaska. Results of our study better delineate the tectonic processes that set the framework for the construction of the Late Mesozoic and Cenozoic Cordilleran orogen.</p>

Sedimentology

Structural geology and tectonics

Alaska

Geology

Sedimentology

Stratigraphy

Tectonics

Clastic wedge

Paleogeography

Intermontane terranes

Yukon-Tanana terrane

Laurentia

Manley basin

Paleozoic

Devonian

Mississippian

Mesozoic

Cretaceous

Accretion tectonics

Backarc extension

Detrital zircon

Slide Mountain Ocean

Kahiltna Basin

Kuskokwim Basin

Wellesley Basin

Crustal thickening

Fairbanks Schist

Wickersham unit

Chatanika unit

Cascaden Ridge unit

Wolverine Quartzite

Wilber Creek unit

Stratigraphy and Sedimentology of the Bisbee Group in the Whetstone Mountains, Pima and Cochise Counties, Southeastern Arizona

Archibald, Lawrence Eben

January 1982

The Aptian-Santonian(?) Bisbee Group in the Whetstone Mountains comprises 2375 m of clastic sedimentary rocks and limestones. The basal Glance Conglomerate unconformably overlies the Pennsylvanian-Permian Naco Group. It consists of limestone conglomerates which were deposited in proximal alluvial fan environments. The superadjacent Willow Canyon Formation contains finer grained rocks which were deposited in the distal portions of alluvial fans. The lacustrine limestones in the Apache Canyon Formation interfinger with and overlie these alluvial fan facies. The overlying Shellenberger Canyon Formation is composed mostly of terrigenous rocks derived from westerly terranes. This formation contains thick sequences of fluvio-deltaic facies as well as a thin interval of estuarine deposits which mark a northwestern extension of the marine transgression in the Bisbee -Chihuahua Embayment. The youngest formation (Upper Cretaceous?) in the Bisbee Group, the Turney Ranch Formation, consists of interbedded sandstones and marls which were deposited by fluvial and marine(?) processes.

alluvial fans

Apache Canyon Formation

Aptian

Arizona

Basin and Range Province

Bisbee Group

Bisbee-Chihuahua Embayment

Carboniferous

Cochise County Arizona

Comanchean

Cretaceous

deltaic environment

depositional environment

environment

estuarine environment

fluvial environment

Glance Conglomerate

lithofacies

Lower Cretaceous

Mesozoic

Naco Group

North America

Paleozoic

Pennsylvanian

Permian

Pima County Arizona

Santonian

sedimentary rocks

sedimentation

Senonian

Shellenberger Canyon Formation

southeastern Arizona

stratigraphy

Turney Ranch Formation

unconformities

United States

Upper Cretaceous

Whetstone Mountains

Willow Canyon Formation

Geology, Stratigraphic.

Sediments (Geology)

Geology -- Arizona -- Pima County.

Geology -- Arizona -- Cochise County.