Podcast: Wild About Utah

Wild About Utah is a Utah Public Radio production featuring contributors who share a love of nature, preservation and education. Contributors include Bridgerland Audubon Society, Utah Public Radio, Stokes Nature Center, the Edith Bowen Laboratory School (EBLS) at USU and many other nature-related individuals and institutions. See WildAboutUtah.org for a list of authors, voices and contributors.

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Sleeping Winter Away

Yellow-bellied marmots,
one of Utah’s true hibernators
Photo courtesy Utah Division of Wildlife Resources,
Copyright Lynn Chamberlain

As Utah’s blanket of snow grows thicker and cold temperatures set in, some of our furred friends quietly retire for the winter. Gone are the marmots that basked on sunny slopes, the bears that browsed in the forests, and the bats that winged silently overhead.

Animals have a number of different strategies to help them survive in winter. Some, such as hummingbirds, migrate to a more temperate climate. Some have special adaptations that allow them to withstand cold temperatures such as mink, which grow wonderfully thick winter coats. And some, such as marmots, bears, and bats, simply find a cozy place to sleep away the winter.

The general term for this period of inactivity is “dormancy,” which includes more specific terms such as “hibernation” and “torpor.” During this time, an animal’s heart rate, breathing rate and metabolism slows down considerably. Contrary to popular belief, most of the mammals that hole up for the winter do not actually hibernate. The term hibernation applies to only a small portion of our Utah mammals – a few species of bats and some rodents like the marmot. True hibernation means that an animal’s metabolism turns off to the point that its body temperature nearly matches that of the environment around it. And in winter, this means that body temperatures can drop to nearly freezing. Hibernating animals become unresponsive to environmental stimuli such as loud noises and being touched, and it takes hours and lots of energy for them to finally awaken.

A black bear,
which survives winter
in a state called torpor
Photo courtesy Utah Division of Wildlife Resources,
Copyright Lynn Chamberlain

In contrast, consider the bear, which does not technically hibernate, but instead enters a state called torpor or ‘winter lethargy’. A bear’s body temperature does decrease during this time but never approaches freezing. Bears also remain semi-active occasionally moving about in their dens, or even giving birth and tending to their newborns. Other animals that become largely inactive in winter but do not fully hibernate include skunks, raccoons, and opossums. These animals can respond very well to environmental stimuli and can resume their full abilities in less than a minute if disturbed – something to keep in mind in case you stumble across a bear’s den this winter.

Thanks to the Rocky Mountain Power Foundation for supporting research and development of this Wild About Utah topic. For the Stokes Nature Center and Wild About Utah, this is Andrea Liberatore.

Credits:

Photos: Courtesy Utah Division of Wildlife Resources and Copyright Lynn Chamberlain, photographer

Text: Andrea Liberatore, Stokes Nature Center

Additional Reading:

Encyclopædia Britannica. 2010. “Dormancy.” Encyclopædia Britannica Online. https://www.britannica.com/EBchecked/topic/169514/dormancy (Accessed Nov. 20, 2010)

New Jersey Division of Fish and Wildlife. 2010. Black Bear Biology and Behavior. https://www.state.nj.us/dep/fgw/bearfacts_biology.htm (Accessed Nov. 20, 2010)

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Gall Insects

Rabbit Brush Galls
made by a tephritid fly Aciurina trixa
Image courtesy and Copyright Jim Cane
Fly identification courtesy Gary Dodson

Does Utah have more Gauls than Caesar conquered? Certainly not Gaulish peoples of the ancient Roman Empire, but yes, galls of the vegetal kind we have aplenty. Galls are small protuberant growths on plants that are induced hormonally by insects, nematodes, and microbes. For its resident juvenile insect, the gall is a sort of edible fortress.

Some plant galls made by insects persist into winter, when they are more apparent to the naturalist’s eye. Looking at just rabbitbrush, you can find a menagerie of galls shaped like peas, pineapples and spindles that were formed from leaves, buds and stems. No growing tissue is immune to galling. The morphology of a gall is often diagnostic for the species of juvenile insect within. Gall-making insects are all tiny and include gall midges and tephritid flies, cynipid gall wasps, various nondescript moths, and any number of aphids and their kin.

One aphid causes the unsightly brown galls on branch tips of blue spruce, a bane to homeowners. Another aphid forms the pea-shaped galls that swell leaf petioles of aspens and cottonwoods. On sagebrush can be found a leaf gall whose soft surface surpasses that of a puppy’s ear. Oaks and willows host a remarkable diversity of galls. One oak gall was formerly used for tanning leather and making inks because it is rich in tannic acids. The Hessian fly is of grave agricultural importance today because its stem galls weaken wheat stems, causing them to lodge over.

Tephritid fly Aciurina bigeloviae
galls on Rabbitbrush
Image courtesy and Copyright Jim Cane
Fly identification courtesy Gary Dodson

But these are exceptions; most galls are of little or no ecological or economic importance. For that reason, most galling insects remain understudied by all but a handful of passionate specialists. Finding plant galls is easy, and once you begin to notice them, you will find it hard to stop. There is no guide to Utah’s plant galls, but we list several starting references for you on our web site.

This is Linda Kervin for Bridgerland Audubon Society.

Credits:

Theme: Courtesy & Copyright Don Anderson as performed by Leaping Lulu
Photos: Courtesy and Copyright Jim Cane
Text: Jim Cane, Bridgerland Audubon Society
Voice: Linda Kervin, Bridgerland Audubon Society

Additional Reading:

Sagebrush Gall made by the fly Rhopalomyia pomum, https://bugguide.net/node/view/200946
Robert P. Wawrzynski, Jeffrey D. Hahn, and Mark E. Ascerno, Insect and Mite Galls, WW-01009 2005,
University of Minnesota Extension, https://www.extension.umn.edu/distribution/horticulture/dg1009.html

Willow Cone Gall Midge
Image Courtesy and Copyright Jim Cane

Field Guide to Plant Galls of California and Other Western States by Ron Russo
ISBN: 978-0-520-24886-1 https://www.amazon.com/California-Western-States-Natural-History/dp/0520248864
Gall, Wikipedia, Wikimedia Foundation, Inc., https://en.wikipedia.org/wiki/Gall (Accessed Dec 2010)
Gagné R (1989) The plant-feeding gall midges of North America. Cornell University Press, Ithaca
https://www.amazon.com/Plant-Feeding-Midges-North-America-Comstock/dp/0801419182

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The Brine Shrimp of Great Salt Lake

Brine shrimp life cycle, Courtesy University of Utah<br/>Genetic Science Learning Center https://learn.genetics.utah.edu/content/gsl/foodweb/brine_shrimp/index.html
Brine shrimp lifecycle
Courtesy University of Utah
Genetic Science Learning Center

Hi, this is Mark Larese-Casanova from the Utah Master Naturalist Program at Utah State University Extension.

I can still remember the colorful advertisements for Sea Monkeys in the back of comics books that I read as a child. For just $1.75, I could have a “bowl full of happiness!” It wasn’t until I visited Great Salt Lake thirty years later that I realized what sea monkeys really were. They certainly weren’t tiny, web-footed humans, and they definitely didn’t have little crown-like antennae. But, it was exciting to think that we have an enormous Sea Monkey aquarium right here in Utah.

Sea Monkeys are actually brine shrimp of the genus Artemia, and Great Salt Lake is full of the species Artemia franciscana. These tiny crustaceans, along with the brine fly’s aquatic larvae, are the foundation of the Great Salt Lake Ecosystem. Millions of birds visit Great Salt Lake each year to feed on brine shrimp during migration or while nesting.

Brine shrimp nauplii from the Great Salt Lake, Courtesy USGS see https://ut.water.usgs.gov/shrimp/
Brine shrimp nauplii
from the Great Salt Lake
Courtesy USGS

Not much can live in Great Salt Lake, with its salt concentrations as high as 25%. But by adapting to these conditions, brine shrimp avoid many predators and have little competition for the abundant algae and bacteria that grow there.

Beginning in late winter or early spring, as the water temperature increases and there is an influx of fresh water to the lake, brine shrimp hatch from cysts, which are hard-shelled dormant eggs. The brine shrimp larva, also called a nauplius, survives on a yolk sack for the first 12 hours, but then feeds on algae as it grows into an adult.

Some species of Artemia have only females, but the Great Salt Lake population has both males and females. The male can be distinguished by his ‘grasper’ antennae, which almost look like a giant handlebar moustache, and the female can often be seen with two small, orange or pink egg sacs at the base of her tail. When conditions in the lake are good, such as with high oxygen and relatively low salt concentrations, female brine shrimp will give birth to live nauplii. But, if salt concentrations increase due to drought in summer, or when water temperature drops in late fall, females switch to making more cysts to ensure the survival of future generations. As winter passes, and spring starts to make an appearance, the life cycle of the brine shrimp starts all over again.

To learn more about brine shrimp, be sure the visit the Great Salt Lake Institute’s web site at greatsaltlakeinstitute.org. I encourage you to visit Antelope Island State Park where you can catch brine shrimp from the marina on the north end of the island. All you need is a bucket… and a little sense of adventure.

Credits:

Photos: Courtesy USGS https://ut.water.usgs.gov/shrimp/
Brine Shrimp Lifecycle, Courtesy University of Utah Genetic Science Learning Center
Theme: Courtesy & Copyright Don Anderson Leaping Lulu
Text & Voice: Mark Larese-Casanova

Additional Reading:

USGS, Utah Water Science Center, Brine Shrimp and Ecology of Great Salt Lake. (Courtesy Internet Archive Wayback Machine, Apr 15, 2008) https://wildaboututah.org/wp-content/uploads/080415-Wayback-USGS-Brine-Shrimp-and-Ecology-of-Great-Salt-Lake.pdf Formerly: https://ut.water.usgs.gov/greatsaltlake/shrimp/

Brine Shrimp, Genetic Science Learning Center, University of Utah, https://learn.genetics.utah.edu/content/gsl/foodweb/brine_shrimp/

Salt Lake Brine Shrimp, https://saltlakebrineshrimp.com/harvest/

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Colorado vs. Utah Snow

Utah snow in author's backyard: relatively light and dry--and definitely deep, Photo Copyright 2010 Holly Strand
Utah snow in author’s backyard:
relatively light and dry
–and definitely deep.
Copyright © 2010 Holly Strand

Hi I’m Holly Strand.

Growing up in Colorado, it never crossed my mind that the snow might be better somewhere else. I believed that my state was the center of the universe– at least as far as snow and skiing were concerned. A couple of decades passed and now I am a Utah resident. I couldn’t help but notice that snow quality here is well beyond satisfactory. And many Utah license plates claim the Greatest Snow on Earth. So, I wondered… Who has better snow? Colorado or Utah?

People usually assume that “great snow” means voluminous and powdery. So let’s compare the 2 states using measures of snow depth for volume and measures of water content for powder.

As far as snow depth, Alta takes the cake and wins mega points for Utah. According to data collected by ski area avalanche professionals, Alta’s average annual snowfall from Nov 1-Apr 30 is 530 inches. That’s 44 feet of snow ! A few other Utah resorts,–plus Colorado’s Wolf Creek Pass–come next with 400 + inches. After that, you get several 300+ inches resorts in both states. More in Colorado, but that’s just because there are more resorts in general. Colorado also has a bunch of areas with 200+ inches. But the point is that a handful of super-snowy resorts lead the pack and most of them are in Utah.

Next I located National Weather Service data for the average water content of freshly fallen snow. The lower the value, the drier the snow. It turns out that the mean water content of new snow decreases as you move eastward from the Pacific Coast to the Rockies. You get values around 12 % water content for the Sierras. This is the infamous Sierra Cement. Intermountain (including the Wasatch Mountains) values hover around 8.5%. The mean water content value for Central Rocky Mountain stations was close to 7%. So in general, Colorado has less watery snow. Of course there are localized anomalies in each state. But overall, Colorado appears to edge out Utah for light, dry, and fluffy snow.

So who has the best snow overall? Well, I guess I still haven’t solved that issue. Best to discuss it further after an exhilarating day on the slopes. Let us know what you think: Send us an email at wildaboututah@gmail.org

For data sources and archives of past Wild About Utah episodes visit www.wildaboututah.org

For Wild About Utah, I’m Holly Strand.

Credits:

Photos: Courtesy and Copyright 2010 Holly Strand

Text: Holly Strand

Sources & Additional Reading:

Armstrong, R.L. and B.R. Armstrong. 1987. Snow and avalancheclimates of the western United States: a comparison of maritime, intermountain and continental conditions. IAHS Publ. 162
(Symposium at Davos 1986 – Avalanche Formation, Movement and Effects), 281–294

Baxter, M.A., C.E. Graves, and J.T. Moore, 2005: A Climatology of Snow to Liquid Ratio for the Contiguous United States, Weather and Forecasting, 20, 729-744.

Crocker, Tony. BESTSNOW.NET – an independent statistical analysis of snow characteristics (based on data collected by ski area avalanche professionals) at major North American ski resorts. https://webpages.charter.net/tcrocker818/ [accessed December 14, 2010]

Steenburgh, W. J., and T. I. Alcott, 2008. Secrets of the “Greatest Snow on Earth.” Bull. Amer. Meteor. Soc., 89, 1285-1293.