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NARROW
GeoRef Subject
-
all geography including DSDP/ODP Sites and Legs
-
Africa
-
East Africa
-
Sudan (1)
-
Tanzania (1)
-
Uganda (1)
-
-
East African Lakes
-
Lake Albert (1)
-
-
Namib Desert (1)
-
Nile River (1)
-
North Africa
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
High Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
High Atlas (1)
-
-
-
-
Southern Africa
-
Namibia (1)
-
Orange River (1)
-
South Africa
-
Cape fold belt (1)
-
-
-
-
Alexander Island (1)
-
Antarctica
-
Transantarctic Mountains (1)
-
-
Arctic region (2)
-
Asia
-
Altai Mountains
-
Gorny Altai (3)
-
-
Altai Russian Federation
-
Gorny Altai (3)
-
-
Arabian Peninsula
-
Arabian Shield (2)
-
-
Brahmaputra River (2)
-
Far East
-
China
-
Huang He (3)
-
Loess Plateau (1)
-
Qinghai China (2)
-
Xizang China (1)
-
-
Japan
-
Honshu
-
Fukushima Japan (1)
-
Shimane Japan
-
Shinji Lake (2)
-
-
-
-
-
Himalayas (2)
-
Indian Peninsula
-
India
-
Yamuna River (1)
-
-
Jammu and Kashmir
-
Ladakh (1)
-
-
-
Indus River (1)
-
Irkutsk Basin (1)
-
Irkutsk Russian Federation (1)
-
Middle East
-
Israel
-
Negev (1)
-
-
-
Siberia (1)
-
Siberian Platform (1)
-
Tibetan Plateau (2)
-
-
Atlantic Ocean
-
North Atlantic
-
Caribbean Sea (1)
-
Gulf of Mexico
-
Orca Basin (1)
-
-
-
-
Australasia
-
Australia
-
Queensland Australia
-
Burdekin Delta (1)
-
-
-
New Zealand
-
Lake Taupo (1)
-
Waikato Basin (1)
-
-
-
Black Sea region (2)
-
Cache Creek (1)
-
Canada
-
Eastern Canada
-
Maritime Provinces
-
Nova Scotia
-
Cumberland County Nova Scotia
-
Joggins Fossil Cliffs (1)
-
-
Minas Basin (1)
-
-
-
Ontario
-
Thunder Bay District Ontario
-
Lake Nipigon (1)
-
-
-
Quebec
-
Saguenay Fjord (1)
-
Saguenay Valley (1)
-
Saint Lawrence Estuary (1)
-
-
-
Western Canada
-
Alberta
-
Fort McMurray Alberta (1)
-
-
British Columbia
-
Mount Meager (1)
-
Vancouver British Columbia (1)
-
-
Manitoba (1)
-
Northwest Territories (1)
-
-
-
Caribbean region
-
West Indies
-
Antilles
-
Lesser Antilles
-
Barbados (1)
-
-
-
-
-
Cascade Range (1)
-
Cascadia subduction zone (1)
-
Caspian Sea (2)
-
Central America
-
Panama (1)
-
-
Central Basin (1)
-
Channeled Scabland (11)
-
Clark Fork (1)
-
Coast Mountains (1)
-
Colorado River (1)
-
Columbia River (8)
-
Columbia River basin (1)
-
Commonwealth of Independent States
-
Russian Federation
-
Altai Russian Federation
-
Gorny Altai (3)
-
-
Irkutsk Basin (1)
-
Irkutsk Russian Federation (1)
-
Siberian Platform (1)
-
-
-
Copper River basin (1)
-
Cumberland Basin (1)
-
Europe
-
Alps
-
Eastern Alps
-
Northern Limestone Alps (1)
-
-
Limestone Alps
-
Northern Limestone Alps (1)
-
-
Western Alps
-
Dauphine Alps
-
Vercors (1)
-
-
-
-
Central Europe
-
Austria
-
Salzkammergut (1)
-
Upper Austria (1)
-
-
Northern Limestone Alps (1)
-
-
Southern Europe
-
Iberian Peninsula
-
Spain
-
Aragon Spain
-
Saragossa Spain (1)
-
-
Castilla-La Mancha Spain
-
Cuenca Spain (1)
-
-
Ebro River (1)
-
-
-
Italy
-
Apennines
-
Southern Apennines (1)
-
-
Umbria Italy
-
Perugia Italy
-
Gubbio Italy (1)
-
-
-
-
-
Western Europe
-
France
-
Dauphine Alps
-
Vercors (1)
-
-
Isere France (1)
-
-
United Kingdom
-
Great Britain
-
England
-
Cumbria England (1)
-
-
Scotland
-
Moray Firth (1)
-
-
-
Isle of Man (1)
-
-
-
-
Grand Canyon (1)
-
Green River basin (1)
-
Lake District (1)
-
Lake Victoria (1)
-
Mediterranean region (1)
-
Mediterranean Sea
-
East Mediterranean
-
Black Sea (2)
-
-
-
Mexico
-
Guerrero Mexico (1)
-
Sierra Madre del Sur (1)
-
Valley of Mexico (1)
-
-
North America
-
Appalachians
-
Blue Ridge Province (1)
-
Central Appalachians (1)
-
Northern Appalachians (1)
-
Piedmont (1)
-
-
Great Lakes
-
Lake Michigan (1)
-
-
Gulf Coastal Plain (2)
-
Okanagan Valley (2)
-
Rocky Mountains
-
U. S. Rocky Mountains
-
Uinta Mountains (2)
-
-
-
-
North Island (1)
-
Northern Hemisphere (1)
-
Pacific Ocean
-
East Pacific
-
Northeast Pacific
-
Escanaba Trough (1)
-
-
-
North Pacific
-
Northeast Pacific
-
Escanaba Trough (1)
-
-
Northwest Pacific
-
East China Sea (1)
-
-
-
West Pacific
-
Northwest Pacific
-
East China Sea (1)
-
-
-
-
Pasco Basin (2)
-
Peace River (1)
-
polar regions (1)
-
Red River (1)
-
Rio Grande (1)
-
San Juan Basin (1)
-
San Luis Valley (1)
-
Sand Wash Basin (1)
-
Santa Barbara Basin (1)
-
Shackleton Glacier (1)
-
Snake River (1)
-
South America
-
Argentina
-
Neuquen Basin (1)
-
-
Colombia
-
Magdalena Valley (1)
-
-
-
Southern Hemisphere (1)
-
United States
-
Alaska
-
Matanuska Glacier (1)
-
Matanuska Valley (1)
-
Susitna River (1)
-
-
Arizona
-
Coconino County Arizona (1)
-
-
Atlantic Coastal Plain (1)
-
California
-
Salton Trough (1)
-
Southern California (1)
-
-
Colorado
-
Alamosa County Colorado (1)
-
Conejos County Colorado (1)
-
Piceance Basin (1)
-
Rangely Anticline (1)
-
Rio Blanco County Colorado (1)
-
Rio Grande County Colorado (1)
-
Saguache County Colorado (1)
-
-
Colorado Plateau (4)
-
Columbia Plateau (7)
-
Georgia
-
Thomas County Georgia (1)
-
-
Idaho
-
Snake River plain (2)
-
-
Maryland (1)
-
Mississippi
-
Grenada County Mississippi (1)
-
-
Mississippi Embayment (1)
-
Montana
-
Missoula County Montana (1)
-
-
New England (1)
-
New Mexico
-
San Juan County New Mexico (1)
-
-
New York (1)
-
Ohio
-
Athens County Ohio
-
Athens Ohio (1)
-
-
-
Oklahoma
-
Cimarron County Oklahoma (1)
-
Oklahoma Panhandle (1)
-
-
Oregon
-
Gilliam County Oregon (1)
-
Hood River County Oregon (1)
-
Tillamook County Oregon (1)
-
-
Pennsylvania (1)
-
Susquehanna River (1)
-
Tennessee (1)
-
U. S. Rocky Mountains
-
Uinta Mountains (2)
-
-
Uinta Basin (2)
-
Utah
-
Carbon County Utah (1)
-
Daggett County Utah (1)
-
Duchesne County Utah (2)
-
Emery County Utah (1)
-
Garfield County Utah (1)
-
Kane County Utah (1)
-
Summit County Utah (2)
-
Wasatch Plateau (1)
-
Zion National Park (1)
-
-
Vermont
-
Lamoille County Vermont (1)
-
-
Virgin River valley (1)
-
Washakie Basin (1)
-
Washington
-
Benton County Washington (2)
-
Franklin County Washington (1)
-
Grant County Washington (1)
-
Grays Harbor County Washington (2)
-
Pacific County Washington (1)
-
Spokane County Washington
-
Spokane Washington (1)
-
-
Walla Walla County Washington (2)
-
Yakima County Washington (2)
-
-
Western U.S. (1)
-
Wyoming
-
Great Divide Basin (1)
-
Hanna Basin (1)
-
-
-
Wind River basin (1)
-
-
commodities
-
metal ores (1)
-
petroleum (1)
-
-
elements, isotopes
-
carbon
-
C-13/C-12 (2)
-
C-14 (16)
-
organic carbon (1)
-
-
halogens
-
chlorine
-
Cl-36 (1)
-
-
-
isotope ratios (7)
-
isotopes
-
radioactive isotopes
-
Be-10 (1)
-
C-14 (16)
-
Cl-36 (1)
-
U-238/U-234 (2)
-
-
stable isotopes
-
C-13/C-12 (2)
-
He-3 (2)
-
He-4 (1)
-
Nd-144/Nd-143 (1)
-
Ne-21 (1)
-
Ne-22/Ne-20 (1)
-
O-18/O-16 (2)
-
Sr-87/Sr-86 (1)
-
-
-
metals
-
actinides
-
uranium
-
U-238/U-234 (2)
-
-
-
alkaline earth metals
-
beryllium
-
Be-10 (1)
-
-
strontium
-
Sr-87/Sr-86 (1)
-
-
-
hafnium (1)
-
rare earths
-
neodymium
-
Nd-144/Nd-143 (1)
-
-
-
-
nitrogen (1)
-
noble gases
-
helium
-
He-3 (2)
-
He-4 (1)
-
-
neon
-
Ne-21 (1)
-
Ne-22/Ne-20 (1)
-
-
-
oxygen
-
O-18/O-16 (2)
-
-
sulfur (1)
-
-
fossils
-
burrows (4)
-
Chordata
-
Vertebrata
-
Tetrapoda
-
Reptilia
-
Diapsida
-
Archosauria
-
dinosaurs (1)
-
-
-
-
-
-
-
ichnofossils
-
Thalassinoides (1)
-
-
Invertebrata
-
Mollusca (1)
-
Protista
-
Foraminifera (3)
-
Radiolaria (1)
-
-
-
microfossils (6)
-
palynomorphs
-
miospores
-
pollen (2)
-
-
-
Plantae
-
algae
-
Chlorophyta
-
Botryococcus (1)
-
-
diatoms (1)
-
-
Spermatophyta
-
Angiospermae
-
Dicotyledoneae
-
Dryas (1)
-
Quercus (1)
-
-
-
Gymnospermae
-
Coniferales (1)
-
-
-
-
-
geochronology methods
-
(U-Th)/He (1)
-
Ar/Ar (1)
-
exposure age (3)
-
Nd/Nd (1)
-
optically stimulated luminescence (6)
-
paleomagnetism (4)
-
Re/Os (1)
-
tephrochronology (1)
-
Th/U (3)
-
tree rings (2)
-
U/Pb (4)
-
-
geologic age
-
Anthropocene (1)
-
Cenozoic
-
Bronze Age (2)
-
Chalcolithic (1)
-
Iron Age (1)
-
Quaternary
-
Cordilleran ice sheet (3)
-
Holocene
-
lower Holocene (3)
-
Medieval Warm Period (1)
-
Middle Ages (1)
-
middle Holocene (2)
-
Neoglacial (2)
-
upper Holocene (19)
-
-
Pleistocene
-
Lake Agassiz (3)
-
Lake Missoula (14)
-
lower Pleistocene
-
Olduvai Subchron (1)
-
-
Matuyama Chron (1)
-
middle Pleistocene (1)
-
upper Pleistocene
-
Eemian (1)
-
Ipswichian (1)
-
Weichselian (1)
-
Wisconsinan
-
upper Wisconsinan (7)
-
-
-
-
upper Quaternary (3)
-
-
Tertiary
-
Neogene
-
Miocene
-
Columbia River Basalt Group (2)
-
lower Miocene (2)
-
-
Pliocene (4)
-
-
Paleogene
-
Duchesne River Formation (1)
-
Eocene
-
Colton Formation (1)
-
middle Eocene
-
Claiborne Group (1)
-
Tallahatta Formation (1)
-
-
-
Oligocene
-
upper Oligocene (1)
-
-
Paleocene
-
Nacimiento Formation (1)
-
-
Wasatch Formation (1)
-
-
-
upper Cenozoic (1)
-
-
Lake Bonneville (1)
-
Laurentide ice sheet (1)
-
Mesozoic
-
Cretaceous
-
Lower Cretaceous
-
Albian
-
lower Albian (1)
-
-
Aptian (1)
-
Barremian (1)
-
McMurray Formation (1)
-
Urgonian (1)
-
-
Mancos Shale (1)
-
Middle Cretaceous (1)
-
Upper Cretaceous
-
Blackhawk Formation (1)
-
Campanian (1)
-
-
-
Jurassic
-
Middle Jurassic
-
Callovian (1)
-
-
Upper Jurassic
-
Brushy Basin Member (1)
-
Morrison Formation (1)
-
Oxfordian
-
middle Oxfordian (1)
-
-
-
-
Triassic
-
Fremouw Formation (1)
-
Upper Triassic (1)
-
-
-
MIS 2 (1)
-
MIS 5 (1)
-
MIS 6 (1)
-
Paleozoic
-
Cambrian (1)
-
Carboniferous
-
Lower Carboniferous (1)
-
Mississippian
-
Windsor Group (1)
-
-
Pennsylvanian
-
Joggins Formation (1)
-
-
-
Ordovician
-
Lower Ordovician
-
Manx Group (1)
-
-
Upper Ordovician (1)
-
-
-
Phanerozoic (1)
-
Precambrian
-
Archean (1)
-
Uinta Mountain Group (1)
-
upper Precambrian
-
Proterozoic
-
Mesoproterozoic (1)
-
-
-
-
-
igneous rocks
-
igneous rocks
-
granophyre (1)
-
volcanic rocks
-
glasses
-
obsidian (1)
-
-
pyroclastics
-
ignimbrite (1)
-
-
-
-
-
metamorphic rocks
-
turbidite (2)
-
-
minerals
-
carbonates (2)
-
oxides
-
hematite (1)
-
-
silicates
-
orthosilicates
-
nesosilicates
-
zircon group
-
zircon (4)
-
-
-
-
sheet silicates
-
clay minerals (1)
-
mica group (1)
-
palygorskite (1)
-
-
-
-
Primary terms
-
absolute age (23)
-
Africa
-
East Africa
-
Sudan (1)
-
Tanzania (1)
-
Uganda (1)
-
-
East African Lakes
-
Lake Albert (1)
-
-
Namib Desert (1)
-
Nile River (1)
-
North Africa
-
Atlas Mountains
-
Moroccan Atlas Mountains
-
High Atlas (1)
-
-
-
Morocco
-
Moroccan Atlas Mountains
-
High Atlas (1)
-
-
-
-
Southern Africa
-
Namibia (1)
-
Orange River (1)
-
South Africa
-
Cape fold belt (1)
-
-
-
-
Antarctica
-
Transantarctic Mountains (1)
-
-
Arctic region (2)
-
Asia
-
Altai Mountains
-
Gorny Altai (3)
-
-
Altai Russian Federation
-
Gorny Altai (3)
-
-
Arabian Peninsula
-
Arabian Shield (2)
-
-
Brahmaputra River (2)
-
Far East
-
China
-
Huang He (3)
-
Loess Plateau (1)
-
Qinghai China (2)
-
Xizang China (1)
-
-
Japan
-
Honshu
-
Fukushima Japan (1)
-
Shimane Japan
-
Shinji Lake (2)
-
-
-
-
-
Himalayas (2)
-
Indian Peninsula
-
India
-
Yamuna River (1)
-
-
Jammu and Kashmir
-
Ladakh (1)
-
-
-
Indus River (1)
-
Irkutsk Basin (1)
-
Irkutsk Russian Federation (1)
-
Middle East
-
Israel
-
Negev (1)
-
-
-
Siberia (1)
-
Siberian Platform (1)
-
Tibetan Plateau (2)
-
-
Atlantic Ocean
-
North Atlantic
-
Caribbean Sea (1)
-
Gulf of Mexico
-
Orca Basin (1)
-
-
-
-
Australasia
-
Australia
-
Queensland Australia
-
Burdekin Delta (1)
-
-
-
New Zealand
-
Lake Taupo (1)
-
Waikato Basin (1)
-
-
-
Canada
-
Eastern Canada
-
Maritime Provinces
-
Nova Scotia
-
Cumberland County Nova Scotia
-
Joggins Fossil Cliffs (1)
-
-
Minas Basin (1)
-
-
-
Ontario
-
Thunder Bay District Ontario
-
Lake Nipigon (1)
-
-
-
Quebec
-
Saguenay Fjord (1)
-
Saguenay Valley (1)
-
Saint Lawrence Estuary (1)
-
-
-
Western Canada
-
Alberta
-
Fort McMurray Alberta (1)
-
-
British Columbia
-
Mount Meager (1)
-
Vancouver British Columbia (1)
-
-
Manitoba (1)
-
Northwest Territories (1)
-
-
-
carbon
-
C-13/C-12 (2)
-
C-14 (16)
-
organic carbon (1)
-
-
Caribbean region
-
West Indies
-
Antilles
-
Lesser Antilles
-
Barbados (1)
-
-
-
-
-
Caspian Sea (2)
-
Cenozoic
-
Bronze Age (2)
-
Chalcolithic (1)
-
Iron Age (1)
-
Quaternary
-
Cordilleran ice sheet (3)
-
Holocene
-
lower Holocene (3)
-
Medieval Warm Period (1)
-
Middle Ages (1)
-
middle Holocene (2)
-
Neoglacial (2)
-
upper Holocene (19)
-
-
Pleistocene
-
Lake Agassiz (3)
-
Lake Missoula (14)
-
lower Pleistocene
-
Olduvai Subchron (1)
-
-
Matuyama Chron (1)
-
middle Pleistocene (1)
-
upper Pleistocene
-
Eemian (1)
-
Ipswichian (1)
-
Weichselian (1)
-
Wisconsinan
-
upper Wisconsinan (7)
-
-
-
-
upper Quaternary (3)
-
-
Tertiary
-
Neogene
-
Miocene
-
Columbia River Basalt Group (2)
-
lower Miocene (2)
-
-
Pliocene (4)
-
-
Paleogene
-
Duchesne River Formation (1)
-
Eocene
-
Colton Formation (1)
-
middle Eocene
-
Claiborne Group (1)
-
Tallahatta Formation (1)
-
-
-
Oligocene
-
upper Oligocene (1)
-
-
Paleocene
-
Nacimiento Formation (1)
-
-
Wasatch Formation (1)
-
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Líl̓wat oral traditions of Qw̓elqw̓elústen (Mount Meager): Indigenous records of volcanic eruption, outburst flood, and landscape change in southwest British Columbia
Topographic Controls on the Duration of Sinkhole Flooding in Central Tennessee, USA
Coupled channel–floodplain dynamics and resulting stratigraphic architecture viewed through a mass-balance lens
Anatomy of a fluvial paleo-fan: sedimentological and architectural trends of the Paleocene–Eocene Wasatch–Colton System (western Uinta Basin, Utah, U.S.A.)
Rock surface luminescence dating of gravel determines the age of a glacial outburst megaflood, Glacial Lake Missoula, Montana, USA
Rapid megaflood-triggered base-level rise on Mars
The Carboniferous Langness Conglomerate Formation, Isle of Man; an alluvial fan rift-phase deposit
Sedimentological and Geochemical Analysis of the Eocene Tallahatta Formation in Northern Mississippi, USA
ABSTRACT The Bottaccione Gorge at Gubbio, in central Italy, has been an important source of information about Cretaceous and Paleogene Earth history. At the much younger end of the historical continuum, it is also important for understanding the early history of Gubbio itself, for which the only written, although somewhat ambiguous, evidence comes from the Tavole eugubine, the unique bronze tablets which are a kind of Rosetta Stone for the Umbrian language. The role of the Bottaccione Gorge is debated in the history of Gubbio. The road through the gorge, crossing the Monti di Gubbio, is an important element for explaining the location of the city. One of the first settlements (late Bronze Age) is recognized from archaeological evidence at the top of a morphological fault scarp on the slope of Monte Ingino. In the Iron Age, the city described in the Tavole eugubine developed, in which Okri (fortress), Tota (city), and three sacred gates are mentioned. The locations of Okri , Tota , and the gates are still under study. According to the most likely hypothesis, Tota would have developed in the plain, on the right bank of the Torrente Camignano, while the initial settlement would have been transformed into Okri , to which the sacred gates would belong. Another gate may have been placed at the entrance to the Bottaccione Gorge. When the Eugubini (the people of Gubbio) built the new, post-Roman Gubbio in the twelfth century, they still identified, as the most suitable place for a fortified city, the location above the scarp on the slope of Monte Ingino, and they built two new gates at its lateral ends. The city was likely equipped with a third gate that faced the Bottaccione Gorge. In the thirteenth century, the Bottaccione Aqueduct was built to bring water to the highest point of Gubbio. Thus, two waterways—one natural (Torrente Camignano) and the other artificial—still branch off from Bottaccione to reach Gubbio at two different points that determine the lowest and highest levels of the city.
ABSTRACT New findings about old puzzles occasion rethinking of the Grand Coulee, greatest of the scabland channels. Those puzzles begin with antecedents of current upper Grand Coulee. By a recent interpretation, the upper coulee exploited the former high-level valley of a preflood trunk stream that had drained to the southwest beside and across Coulee anticline or monocline. In any case, a constriction and sharp bend in nearby Columbia valley steered Missoula floods this direction. Completion of upper Grand Coulee by megaflood erosion captured flood drainage that would otherwise have continued to enlarge Moses Coulee. Upstream in the Sanpoil valley, deposits and shorelines of last-glacial Lake Columbia varied with the lake’s Grand Coulee outlet while also recording scores of Missoula floods. The Sanpoil evidence implies that upper Grand Coulee had approached its present intake depth early the last glaciation at latest, or more simply during a prior glaciation. An upper part of the Sanpoil section provides varve counts between the last tens of Missoula floods in a stratigraphic sequence that may now be linked to flood rhythmites of southern Washington by a set-S tephra from Mount St. Helens. On the floor of upper Grand Coulee itself, recently found striated rock and lodgement till confirm the long-held view, which Bretz and Flint had shared, that cutting of upper Grand Coulee preceded its last-glacial occupation by the Okanogan ice lobe. A dozen or more late Missoula floods registered as sand and silt in the lee of Steamboat Rock. Some of this field evidence about upper Grand Coulee may conflict with results of recent two-dimensional simulations for a maximum Lake Missoula. In these simulations only a barrier high above the present coulee intake enables floods to approach high-water marks near Wenatchee that predate stable blockage of Columbia valley by the Okanogan lobe. Above the walls of upper Grand Coulee, scabland limits provide high-water targets for two-dimensional simulations of watery floods. The recent models sharpen focus on water sources, prior coulee incision, and coulee’s occupation by the Okanogan ice lobe. Field reappraisal continues downstream from Grand Coulee on Ephrata fan. There, some of the floods exiting lower Grand Coulee had bulked up with fine sediment from glacial Lake Columbia, upper coulee till, and a lower coulee lake that the fan itself impounded. Floods thus of debris-flow consistency carried outsize boulders previously thought transported by watery floods. Below Ephrata fan, a backflooded reach of Columbia valley received Grand Coulee outflow of small, late Missoula floods. These late floods can—by varve counts in post-S-ash deposits of Sanpoil valley—be clocked now as a decade or less apart. Still farther downstream, Columbia River gorge choked the largest Missoula floods, passing peak discharge only one-third to one-half that released by the breached Lake Missoula ice dam.
ABSTRACT While drought represents a serious threat to the Pacific southwestern United States, floods represent an equally formidable threat. This risk is so significant that the U.S. Geological Survey created the ARkStorm Project. This project aims to prepare California for a future storm(s) on the scale of the disastrous A.D. 1861–1862 events. Unfortunately, our knowledge of premeasurement floods in the Pacific southwestern United States is sparse. To date, the best paleoflood record consists of flood layers in the Santa Barbara Basin, spanning the past 9000 calendar yr B.P. (cal yr B.P.). As an alternative to marine archives, the lakes of the Pacific southwestern United States represent untapped resources for possible premeasurement flood reconstructions. Here, we present evidence for a flood between ca. 4860 and 4820 cal yr B.P. using sediment from Lake Elsinore core LEGC03-4. Core LEGC03-4 is predominantly clayey silt with occasional sandy silt units of variable centimeter-scale thickness. Here, we focus on a specific core section between 350 and 315 cm, where an ~11-cm-thick “unusual” sediment unit (330–319 cm) is well preserved and complete. The core section was analyzed for a variety of physical and chemical properties, including magnetic susceptibility, loss-on-ignition (LOI) at 550 °C and 950 °C, grain size, C org :N total ratios, and δ 13 C (bulk organic matter) . The unit is characterized by an erosional basal contact and microflame structures. It is normally graded, with laminae occurring in the upper section of the unit. It contains predominantly terrestrial organic matter, and the upper boundary is gradational. It is coeval with the fourth highest sand peak in a previously dated central basin core. Consequently, it is our conclusion that the unusual sediment unit represents a turbidite associated with a large flood-producing precipitation event with a maximum limiting age between 4860 and 4820 cal yr B.P.
Emergence and Evolution of Barbados is a three-part analysis of the Quaternary geologic and geomorphologic evolution of the island of Barbados in the southeastern Caribbean. “Geology of Southeastern Barbados” assembles and integrates detailed observations into a complex 700 k.y. history of marine sculpting and riverine flooding processes. “Marine Terrace Evolution of Windward Barbados” revises the Quaternary stratigraphy of the island, describes the tectonics of emergence, and demonstrates that uplift rates vary by location. “Active Emergence, Chronology, and Limestone Facies in Southeastern Windward Barbados” is the first comprehensive study to integrate marine erosion and deposition with tectonic uplift rates. Major findings of this work are that Barbados’ Central Highlands are an erosional remnant, and that terraces originated principally by marine erosion rather than by reef construction.
Late Pleistocene–Holocene flood history, flood-sediment provenance and human imprints from the upper Indus River catchment, Ladakh Himalaya
Asian paleomonsoon variation linked to “tripolar” environmental changes
ABSTRACT Global warming and ice melting in the “tripolar” regions, namely, Antarctica, the Arctic, and the Tibetan Plateau, might lead to a reorganization of the global climate system. Understanding the dynamic links between the “tripolar” environments and the Earth climate system is crucial to improving our capability to project future climate variability. “Tripolar” changes have influenced the onset and evolution of the Asian paleomonsoon system through various atmospheric and/or oceanic mechanisms. Here, we summarize previously reported Asian paleomonsoon variations that can be linked to “tripolar” environmental changes, from tectonic to millennial time scales, and explore linkages between the “tripolar” regions and global climate changes.
Deglacial Kankakee Torrent, source to sink
ABSTRACT The last-glacial megaflood Kankakee Torrent streamlined hills and the remarkably straight backslope of the Kalamazoo moraine (Lake Michigan lobe of the Laurentide ice sheet) in southwestern Michigan. Flooding ensued as proglacial Lake Dowagiac overflowed across remnants of the Lake Michigan lobe at the position of the inner margin of the Kalamazoo moraine as glacial debris and ablating ice were pinned against Portage Prairie. Proglacial Lake Dowagiac developed in the Dowagiac River valley as the lobe retreated to form the Valparaiso moraine. A minimum age of the Kankakee Torrent (18.7 ± 0.6 k.y. B.P) is indicated by the weighted mean value of six optically stimulated luminescence ages determined from quartz sand in glaciofluvial sediment on the Kalamazoo moraine (Lake Michigan and Saginaw lobes). This value is consistent with tighter age control based on radiocarbon ages of tundra plants within silty sediment forming ice-walled lake plains and in a torrent-scoured lake basin (Oswego channel) in Illinois. Crosscutting relationships of well-dated moraines indicate the Kankakee Torrent occurred sometime between 19.7 and 18.9 calibrated (cal.) k.y. B.P. as it skirted the south margin of the Valparaiso Morainic System.
ABSTRACT In late Wisconsin time, the Purcell Trench lobe of the Cordilleran ice sheet dammed the Clark Fork of the Columbia River in western Montana, creating glacial Lake Missoula. During part of this epoch, the Okanogan lobe also dammed the Columbia River downstream, creating glacial Lake Columbia in northeast Washington. Repeated failure of the Purcell Trench ice dam released glacial Lake Missoula, causing dozens of catastrophic floods in eastern Washington that can be distinguished by the geologic record they left behind. These floods removed tens of meters of pale loess from dark basalt substrate, forming scars along flowpaths visible from space. Different positions of the Okanogan lobe are required for modeled Missoula floods to inundate the diverse channels that show field evidence for flooding, as shown by accurate dam-break flood modeling using a roughly 185 m digital terrain model of existing topography (with control points dynamically varied using automatic mesh refinement). The maximum extent of the Okanogan lobe, which blocked inundation of the upper Grand Coulee and the Columbia River valley, is required to flood all channels in the Telford scablands and to produce highest flood stages in Pasco Basin. Alternatively, the Columbia River valley must have been open and the upper Grand Coulee blocked to nearly match evidence for high water on Pangborn bar near Wenatchee, Washington, and to flood Quincy Basin from the west. Finally, if the Columbia River valley and upper Grand Coulee were both open, Quincy Basin would have flooded from the northeast. In all these scenarios, the discrepancy between modeled flood stages and field evidence for maximum flood stages increases in all channels downstream, from Spokane to Umatilla Basin. The pattern of discrepancies indicates that bulking of floods by loess increased flow volume across the scablands, but this alone does not explain low modeled flow stages along the Columbia River valley near Wenatchee. This latter discrepancy between modeled flood stages and field data requires either additional bulking of flow by sediment along the Columbia reach downstream of glacial Lake Columbia, or coincident dam failures of glacial Lake Columbia and glacial Lake Missoula.
ABSTRACT The Matanuska lowland north of Anchorage, Alaska, was episodically glaciated during the Pleistocene by the merged westward flow of the Matanuska and Knik glaciers. During the late Wisconsin glaciation, glacial Lake Atna filled the Copper River Basin, impounded by an ice dam blocking the Matanuska drainage divide at Tahneta Pass and the adjacent Squaw Creek headwaters and ice dams at other basin outlets, including the Susitna and Copper rivers. On the Matanuska lowland floor upvalley from the coalesced glacier’s late-Wisconsin terminus, a series of regularly spaced, symmetrical ridges with 0.9-km wavelengths and heights to 36 m are oriented normal to oblique to the valley and covered by smaller subparallel ridges with wavelengths typically ~80 m and amplitudes to 3 m. These and nearby drumlins, eskers, and moraines were previously interpreted to be glacial in origin. Borrow-pit exposures in the large ridges, however, show sorting and stratification, locally with foreset bedding. A decade ago we reinterpreted such observations as evidence of outburst flooding during glacial retreat, driven by water flushing from Lake Atna through breaches in the Tahneta Pass and Squaw Creek ice dam. In this view, the ridges once labeled Rogen and De Geer moraines were reinterpreted as two scales of fluvial dunes. New observations in the field and from meter-scale light detection and ranging (LiDAR) and interferometric synthetic aperture radar (IfSAR) digital elevation models, together with grain-size analyses and ground-penetrating radar profiles, provide further evidence that portions of the glacial landscape of the Matanuska lowlands were modified by megaflooding after the Last Glacial Maximum, and support the conclusion that the Knik Glacier was the last active glacier in the lowland.
Roads less travelled by—Pleistocene piracy in Washington’s northwestern Channeled Scabland
ABSTRACT The Pleistocene Okanogan lobe of Cordilleran ice in north-central Washington State dammed Columbia River to pond glacial Lake Columbia and divert the river south across one or another low spot along a 230-km-long drainage divide. When enormous Missoula floods from the east briefly engulfed the lake, water poured across a few such divide saddles. The grandest such spillway into the Channeled Scabland became upper Grand Coulee. By cutting headward to Columbia valley, upper Grand Coulee’s flood cataract opened a valve that then kept glacial Lake Columbia low and limited later floods into nearby Moses Coulee. Indeed few of the scores of last-glacial Missoula floods managed to reach it. Headward cutting of an inferred smaller cataract (Foster Coulee) had earlier lowered glacial Lake Columbia’s outlet. Such Scabland piracies explain a variety of field evidence assembled here: apparently successive outlets of glacial Lake Columbia, and certain megaflood features downcurrent to Wenatchee and Quincy basin. Ice-rafted erratics and the Pangborn bar of foreset gravel near Wenatchee record late Wisconsin flood(s) down Columbia valley as deep as 320 m. Fancher bar, 45 m higher than Pangborn bar, also has tall foreset beds—but its gravel is partly rotted and capped by thick calcrete, thus pre-Wisconsin age, perhaps greatly so. In western Quincy basin foreset beds of basaltic gravel dip east from Columbia valley into the basin—gravel also partly rotted and capped by thick calcrete, also pre-Wisconsin. Yet evidence of late Wisconsin eastward flow to Quincy basin is sparse. This sequence suggests that upper Grand Coulee had largely opened before down-Columbia megaflood(s) early in late Wisconsin time. A drift-obscured area of the Waterville Plateau near Badger Wells is the inconspicuous divide saddle between Columbia tributary Foster Creek drainage and Moses Coulee drainage. Before flood cataracts had opened upper Grand Coulee or Foster Coulee, and while Okanogan ice blocked the Columbia but not Foster Creek, glacial Lake Columbia (diverted Columbia River) drained over this saddle at about 654 m and down Moses Coulee. When glacial Lake Columbia stood at this high level so far west, Missoula floods swelling the lake could easily and deeply flood Moses Coulee. Once eastern Foster Coulee cataract had been cut through, and especially once upper Grand Coulee’s great cataract receded to Columbia valley, glacial Lake Columbia stood lower, and Moses Coulee became harder to flood. During the late Wisconsin (marine isotope stage [MIS] 2), only when Okanogan-lobe ice blocked the Columbia near Brewster to form a high lake could Missoula floodwater from glacial Lake Missoula rise enough to overflow into Moses Coulee—and then only in a few very largest Missoula floods. Moses Coulee’s main excavation must lie with pre-Wisconsin outburst floods (MIS 6 or much earlier)—before upper Grand Coulee’s cataract had receded to Columbia valley.