LAKE BONNEVILLE
Map of Lake Bonneville, by G.K. Gilbert
Great Salt Lake is the latest in a long succession of often more extensive
lakes that have occupied the basin of Great Salt Lake over the past several
million years. The sediments deposited in the lake and features formed by
the waters of these successive lakes provide impressive geologic evidence
about the past, and also provide sand and gravel for construction materials,
benches and flat spaces for urban development, and scenic horizontal "bathtub
rings" along the surrounding foothills. Lake Bonneville, the most recent
larger lake, formed the most striking of these beaches, deltas, spits, and
wave-cut cliffs that are as high as a thousand feet above the present Great
Salt Lake.
Because the basin of Great Salt Lake has no outlet, water leaves only through
evaporation. The temperature and the surface area of a closed-basin lake
primarily control the amount of water evaporated from the lake. When precipitation
is high, more water is added to the lake by direct precipitation on the
lake and from rivers and streams flowing into the lake than is evaporated
from the lake; the result is that the lake rises and expands across a larger
area of the basin. The surface area of the lake continues to increase until
the amount of water evaporated equals the total amount of water entering
the lake. During the last 10,000 years the level of Great Salt Lake has
gone through many cycles but the lake has not risen more than about twenty
feet higher than its average historic elevation of 4,202 feet above sea
level. When the climate of the region becomes dramatically cooler and wetter,
such as during ice ages, the lake in the Great Salt Lake basin rises to
much higher levels. One such rise occurred about 140,000 years ago when
the lake in the basin rose to an elevation about 700 feet above the current
level of Great Salt Lake, and again about 65,000 years ago when the lake
rose about half that high. The highest and most recent lake high lake cycle
began about 25,000 years and produced Lake Bonneville, a huge lake over
1,000 feet deep that extended over most of northwestern Utah and into Nevada
and Idaho.
Explorers as early as Captain J.C. Frémont in 1843 recognized shoreline
evidence that a succession of deep lakes had once existed in the Great Salt
Lake basin. However, G.K. Gilbert, first with the Wheeler Survey in the
1870s and later with the U.S. Geological Survey, was the first to study
these prehistoric lake features and describe the major features of Lake
Bonneville. He named the lake after Captain Bonneville, an earlier explorer
in the region to the north, but one who never visited Great Salt Lake.
Gilbert established that the lake, with a maximum depth of at least 1,000
feet, covered an area of about 20,000 square miles in what is now northwestern
Utah, northeastern Nevada, and southeastern Idaho. He determined that at
its highest level, which he named the Bonneville Shoreline, Lake Bonneville
overflowed the rim of the Great Basin near Red Rock Pass in southeastern
Idaho at an elevation of about 5,100 feet above sea level and spilled into
a tributary of the Snake River, eventually flowing into the Pacific Ocean.
He concluded that when these waters suddenly breached the relatively unconsolidated
sediments forming the pass, they quickly scoured a channel down to the bedrock
and released a catastrophic flood down the Snake River. This event, now
known as the Bonneville Flood, lowered the outlet elevation and reduced
the surface elevation of Lake Bonneville in a short time, probably less
than a year, to a more stable level at about 4,750 feet above sea level.
Gilbert named this post-flood level the Provo Shoreline.
Gilbert noted that the shorelines which formed when the lake was at the
Bonneville and Provo levels are now at considerably higher elevations in
the central part of the lake basin than they are around its edges. He correctly
concluded that the weight of the water in the deep lake had depressed the
earth's surface when the shorelines were formed. When the water was removed,
what geologists call "crustal rebound" elevated the shoreline
in the central part of the basin. Gilbert noted that an excess of evaporation
over inflow must have drawn the lake down from the Provo Shoreline. His
final report on Lake Bonneville was published in 1890 as U.S. Geological
Survey Monograph 1. For the next half century very little was added to the
understanding of the lake developed by Gilbert.
Since the 1940s, numerous studies using new topographic maps, aerial photographs,
new techniques for soil and lake-bed studies, and new techniques for dating
sediments and archaeological materials have contributed to a rapidly growing
body of information on Great Salt Lake and Lake Bonneville. These studies
have confirmed much of Gilbert's general history of Lake Bonneville. They
have also refined the chronology of major deep-lake events and are leading
to a better understanding of many of the lower lake stages that postdate
Lake Bonneville.
Lake Bonneville's birth and development were under way about 25,000 years
ago. The climate associated with the most recent major ice age filled the
lake to approximately 300 feet above the present Great Salt Lake elevation
at what is now known as the Stansbury Level. This lake covered approximately
9,300 square miles and its shorelines stand out clearly above the oil refineries
near the State Capitol, by the Kennecott Smelter, and immediately east of
Wendover.
The lake then resumed its rise until by about 15,000 years ago it reached
the lowest pass out of the Bonneville Basin and flowed into the Snake River
drainage.
This lake level, the Bonneville Level, was controlled by the height of the
pass near Red Rock Pass, at approximately a 5,090-foot elevation. The immense
lake, with a surface area of 19,800 square miles, left shorelines traces
for over 2,000 miles. Its relatively fresh waters supported a diverse biota
including many species of fish. This highest shoreline of Lake Bonneville
and its beaches now forms a high bench for residential developments of the
Wasatch Front communities. The steeper terrain above this shoreline generally
has not been developed. Virtually all of the Wasatch Front area that now
is home to most of the residents and industries of Utah was below the waters
of Lake Bonneville at this time.
The Bonneville Flood, which occurred about 15,000 years ago, dropped the
level of Lake Bonneville more than 300 feet to the Provo Level (4,740 feet
above sea level). The 14,400-square-mile lake remained at this level for
more than a thousand years, its level controlled by the spillover elevation
at Red Rock Pass. It also was relatively fresh. Prominent deltas at the
mouths of rivers entering the lake, and shoreline features such as spits,
lagoons, and wave-cut benches mark this level. The University of Utah, Brigham
Young University, Utah State University, and Weber State University campuses
all are located on the Provo Level of Lake Bonneville. Were the lake to
rise again in response to dramatically changed climate conditions, it could
go no higher than this level because it, too, would flow out of the Great
Basin into the Columbia River Basin at Red Rock Pass.
Approximately 12,000 years ago, the level of Lake Bonneville fell precipitously
due to changes in the Great Basin climate. The Gilbert Level Shoreline ended
about 10,000 years ago and left its mark about fifty feet above the present
level of Great Salt Lake. It marks the last gasp of the Bonneville Lake
cycle and the beginning of the story of Great Salt Lake.
Lake Bonneville is a very young geologic feature, with its age measured
in thousands of years rather than in millions or billions of years as are
most of the geologic features in Utah. But it is very important. Most of
the large deposits of sand and gravel mined along the Wasatch Front were
formed by Lake Bonneville. Features formed by the lake provide an excellent
laboratory to study how landforms develop beneath the surface of lakes and
along lakeshores. The deformation of the lake's shorelines provides important
information about the physical properties of the earth's crust. The lake's
features provide a striking example of how dramatically changes of climate
can affect the surface of the earth in only a few thousand years. The development
of another Lake Bonneville would flood most of the thickly populated area
of Utah. Fluctuations of Great Salt Lake, which are minor in comparison,
can be expected every hundred years or so and can alter the lake level by
a few feet to perhaps 4,219 feet above sea level. Yet even this would flood
billions of dollars of development along the Great Salt Lake's shoreline.
Genevieve Atwood
