The Mormon experience: the plains as Sinai, the Great Salt Lake as the Dead Sea, and the Great Basin as desert-cum-promised land

Shorelines and surficial deposits (including buried forest-floor mats and organic-rich wetland sediments) show that Great Salt Lake did not rise higher than modern lake levels during the earliest Holocene (11.5–10.2 cal ka BP; 10–9 14C ka BP). During that period, finely laminated, organic-rich muds (sapropel) containing brine-shrimp cysts and pellets and interbedded sodium-sulfate salts were deposited on the lake floor. Sapropel deposition was probably caused by stratification of the water column — a freshwater cap possibly was formed by groundwater, which had been stored in upland aquifers during the immediately preceding late-Pleistocene deep-lake cycle (Lake Bonneville), and was actively discharging on the basin floor. A climate characterized by low precipitation and runoff, combined with local areas of groundwater discharge in piedmont settings, could explain the apparent conflict between evidence for a shallow lake (a dry climate) and previously published interpretations for a moist climate in the Great Salt Lake basin of the eastern Great Basin.

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The Deep Creek Region, the Northwestern Frontier of the Pueblo Culture

American Antiquity ◽

10.2307/275344 ◽

1946 ◽

Vol 12 (2) ◽

pp. 117-121

Author(s):

Carling Malouf

Keyword(s):

Great Basin ◽

Salt Lake ◽

Great Salt Lake ◽

Small Streams

The Deep Creek region is a pleasant Great Basin valley bordering the southwest edge of the Great Salt Lake Desert—that is, it is pleasant in contrast to the 10,000 square miles of stark desert which bound it on three sides. The Deep Creek Mountains, which attain an elevation of 12,101 feet, separate the valley from the desert proper. Two small streams, Fifteen-Mile Creek and Spring Creek, have their sources in these mountains and join at Ibapah, Utah, to form Deep Creek itself.

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Multidecadal Drought Cycles in the Great Basin Recorded by the Great Salt Lake: Modulation from a Transition-Phase Teleconnection

Journal of Climate ◽

10.1175/2011jcli4225.1 ◽

2012 ◽

Vol 25 (5) ◽

pp. 1711-1721 ◽

Cited By ~ 21

Author(s):

Shih-Yu Wang ◽

Robert R. Gillies ◽

Thomas Reichler

Keyword(s):

Phase Shift ◽

Great Basin ◽

Salt Lake ◽

Wave Train ◽

Great Salt Lake ◽

Coupled Model ◽

Moisture Flux ◽

Gulf Of Alaska ◽

The North ◽

Circulation Anomalies

This study investigates the meteorological conditions associated with multidecadal drought cycles as revealed by lake level fluctuation of the Great Salt Lake (GSL). The analysis combined instrumental, proxy, and simulation datasets, including the Twentieth Century Reanalysis version 2, the North American Drought Atlas, and a 2000-yr control simulation of the GFDL Coupled Model, version 2.1 (CM2.1). Statistical evidence from the spectral coherence analysis points to a phase shift amounting to 6–9 yr between the wet–dry cycles in the Great Basin and the warm–cool phases of the interdecadal Pacific oscillation (IPO). Diagnoses of the sea surface temperature and atmospheric circulation anomalies attribute such a phase shift to a distinctive teleconnection wave train that develops during the transition points between the IPO’s warm and cool phases. This teleconnection wave train forms recurrent circulation anomalies centered over the southeastern Gulf of Alaska; this directs moisture flux across the Great Basin and subsequently drives wet–dry conditions over the Great Basin and the GSL watershed. The IPO life cycle therefore modulates local droughts–pluvials in a quarter-phase manner.

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A field trip to observe features of Lake Bonneville, mountain glaciation, and Great Salt Lake near Salt Lake City, Utah, USA

GSA in the Field in 2020 ◽

10.1130/2021.0060(03) ◽

2021 ◽

pp. 71-94

Author(s):

Charles G. (Jack) Oviatt ◽

Genevieve Atwood ◽

Benjamin J.C. Laabs ◽

Paul W. Jewell ◽

Harry M. Jol

Keyword(s):

Great Basin ◽

Salt Lake ◽

Great Salt Lake ◽

Salt Lake City ◽

Field Trip ◽

Lake Bonneville ◽

Salt Lake Valley ◽

Mountain Glaciers ◽

History Of ◽

Lake City

ABSTRACT On this field trip we visit three sites in the Salt Lake Valley, Utah, USA, where we examine the geomorphology of the Bonneville shoreline, the history of glaciation in the Wasatch Range, and shorezone geomorphology of Great Salt Lake. Stop 1 is at Steep Mountain bench, adjacent to Point of the Mountain in the Traverse Mountains, where the Bonneville shoreline is well developed and we can examine geomorphic evidence for the behavior of Lake Bonneville at its highest levels. At Stop 2 at the mouths of Little Cottonwood and Bells Canyons in the Wasatch Range, we examine geochronologic and geomorphic evidence for the interaction of mountain glaciers with Lake Bonneville. At the Great Salt Lake at Stop 3, we can examine modern processes and evidence of the Holocene history of the lake, and appreciate how Lake Bonneville and Great Salt Lake are two end members of a long-lived lacustrine system in one of the tectonically generated basins of the Great Basin.

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Age and Paleoclimatic Significance of the Stansbury Shoreline of Lake Bonneville, Northeastern Great Basin

Quaternary Research ◽

10.1016/0033-5894(90)90057-r ◽

1990 ◽

Vol 33 (3) ◽

pp. 291-305 ◽

Cited By ~ 35

Author(s):

Charles G. Oviatt ◽

Donald R. Currey ◽

David M. Miller

Keyword(s):

Great Basin ◽

Late Pleistocene ◽

Lake Level ◽

Drainage Basin ◽

Salt Lake ◽

Great Salt Lake ◽

Lake Bonneville ◽

Paleoclimatic Significance ◽

Continental Ice Sheets ◽

Barrier Beaches

AbstractThe Stansbury shoreline, one of the conspicuous late Pleistocene shorelines of Lake Bonneville, consists of tufa-cemented gravel and barrier beaches within a vertical zone of about 45 m, the lower limit of which is 70 m above the modern average level of Great Salt Lake. Stratigraphic evidence at a number of localities, including new evidence from Crater Island on the west side of the Great Salt Lake Desert, shows that the Stansbury shoreline formed during the transgressive phase of late Pleistocene Lake bonneville (sometime between about 22,000 and 20,000 yr B.P.). Tufa-cemented gravel and barrier beaches were deposited in the Stansbury shorezone during one or more fluctuations in water level with a maximum total amplitude of 45 m. We refer to the fluctuations as the Stansbury oscillation. The Stansbury oscillation cannot have been caused by basin-hypsometric factors, such as stabilization of lake level at an external overflow threshold or by expansion into an interior subbasin, or by changes in drainage basin size. Therefore, changes in climate must have caused the lake level to reverse its general rise, to drop about 45 m in altitude (reducing its surface area by about 18%, 5000 km2), and later to resume its rise. If the sizes of Great Basin lakes are controlled by the mean position of storm tracks and the jetstream, which as recently postulated may be controlled by the size of the continental ice sheets, the Stansbury oscillation may have been caused by a shift in the jetstream during a major interstade of the Laurentide ice sheet.

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