What are Salt Flats?
Salt flats are formed from dried up lakes. In this case,
the Bonneville Flats were formed from the Pleistocene era Bonneville lake (5).
The lakes in these regions have high salinity levels. The Salt Lake that is in
this region is the second lake with the highest salt levels (6). It is also the
only protected part of this region. The salinity levels of the lake are
decreasing drastically, as a result the Brine shrimp that are harvested are
also decreasing in numbers (6). This affects the farmers who sell the shrimp. A
high amount of soil salts affects the intake of precipitation by plants (4).
Therefore, it is very hard for certain plants to grow due to the high level of
soil salts. According to the article Soil
as a Factor Influencing Plant Distribution on Salt-Deserts of Utah, the
dominant types of plant in a Salt Desert region are shrub vegetations such as,
Artemisia and Atriplex (4). This type of biome is found in North Western Utah,
Colorado, and parts of the Middle East. Additionally, shrub vegetation is the
most common in salt deserts because of the sediment that exists in shallow
seas.
The Bonneville Salt Flats
The Bonneville Salt
Flats are now a popular tourist site. Long automobile records were set and are
still broken to this day. Additionally, tourists also like to partake on hikes,
trail walks, and picnic in the picnic areas. Not only is this region used for recreational
purposes, but it is also used by the Montello Salt Company. The company gathers
and processes common salt from this region. They process about two tons of salt
from this region. Currently, anyone is allowed to visit the Bonneville Salt
Flats. There are no regulations protecting the crust of the soil.
Human
Impacts
The current human impact on the Salt Lake desert is good,
for now. The USGS Global Climate Program in Utah is focusing on how human
activity and climate change affects the lake, vegetation, and land surface (7).
Utah in particular, is more susceptible to human and climate changes because it
is located on important climatic gradient. Utah is composed of Arid and
Semiarid region thus, making it susceptible to human activity and climate
changes. The study of this program is being done on the soil crust. The soil
crust is composed of different types of bacteria such as mosses, lichens, and “cyanobacteria”
(7). The soil crust is the key to soil stability, water infiltration, and soil
fertility. The sticky surfaces of soil crusts “glue together” thus, making
their surfaces larger and less susceptible to wind and water erosion (7). Soil
crusts also play a big role in water retention. The organisms in the soil
absorb water up to ten times their size and when the rain stops, they slowly
release the water into the ground (8). Additionally, the organisms in the soil
contribute nitrogen and organic matter to the ecosystems. Humans have had a
negative impact on the cyanobacteria in the soil. The cyanobacterial fibers do
not stand a chance against the hooves of cattle, the vehicles that drive off
road, nor the regular treading by humans. If damaged, the crusts could take up
to two hundred and fifty years to recover (8).
Possible
Solutions
The USGS advises
staying on designated roads when biking as well as driving. They also advise to
stay on slickrock whenever possible. People should not attempt to jump over
fences because they have been put there to prevent further damage (8). It is
also advised to camp only at designated camp sites, under trees, or on sandy
beaches. When hiking, it is advised to stay on the designated hiking trails.
What I think we should do is to raise awareness. Before this project, I did not
realize how important dirt was. I never knew that the organisms in dirt could
prevent erosion or soil sediments. I believe if there were programs in the K-12
schools that taught children about the important of soil, more people would
think twice before breaking rules. Also, I think that state parks that have
damaged soil should just close down until the soil has recovered. If we do not
follow these simple suggestions, we could have another dust bowl which would
mean a drastic decrease in our food supplies and not to mention the severe
health consequences.
Works
Cited
1.
Ingles,
Lloyd G. "The Desert Biome." The Desert Biome. University of
California Museum of Paleontology, 2004. Web. 03 Dec. 2012.
<http://www.ucmp.berkeley.edu/exhibits/biomes/deserts.php>.
2.
Przyborski,
Paul. "Desert : Mission: Biomes." Desert : Mission: Biomes. NASA EARTH
OBSERVATORY, n.d. Web. 03 Dec. 2012.
<http://earthobservatory.nasa.gov/Experiments/Biome/biodesert.php>.
3.
Boudreau,
Diane, Melissa McDaniel, Erin Sprout, and Andrew Turgeon. "Desert." National Geographic Education. Ed. Jeannie Evers and Kara West. National
Geographic, n.d. Web. 03 Dec. 2012.
<http://education.nationalgeographic.com/education/encyclopedia/desert/?ar_a=1>.
4.
West, N. E. Intermountain Salt-Desert Shrubland (n.d.): 375-97. JSTOR. JSTOR. Web. 3 Dec. 2012.
<http://www.gis.usu.edu/~doug/frws3800/readings/CH14.pdf>.
5.
Hallaran,
Kevin B. "Bonneville Salt Flats." Historytogo. Utah History To
Go, 2012. Web. 03 Dec. 2012. <http://historytogo.utah.gov/utah_chapters/the_land/bonnevillesaltflats.html>.
6.
Stephens,
Doyle W., and Joe Gardner. "Great Salt Lake, Utah." USGS Science for Changing. USGS, n.d. Web. 3 Dec. 2012.
<http://pubs.usgs.gov/wri/wri994189/PDF/WRI99-4189.pdf>.
7.
"Effects
of Causeway on the Great Salt Lake." Utah. USGS, n.d. Web. 3
Dec. 2012. <http://pubs.usgs.gov/fs/FS-046-99/pdf/fs-046-99.pdf>.
8.
Belnap,
Jayne. "Biological Soils Crusts: The Web of Life in the Desert." USGS Science for Changing the World. USGS, n.d. Web. 3
Dec. 2012. <http://fresc.usgs.gov/products/fs/fs-065-01.pdf>.
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