Snow melts faster under trees than in open areas in mild climates
It’s a foggy fall morning, and University of Washington researcher Susan Dickerson-Lange pokes her index finger into the damp soil beneath a canopy of second-growth conifers. The tree cover is dense here, and little light seeps in among the understory of the Cedar River Municipal Watershed about 30 miles east of Seattle.
She digs a small hole in the leaf-litter soil, then pushes a thumb-sized device, called an iButton, about an inch beneath the surface. If all goes well, this tiny, battery-powered instrument will collect a temperature reading every hour for 11 months. Researchers hope this tool and a handful of other instruments will help them map winter temperatures throughout the watershed as they track snow accumulation and melt.
This fieldwork piggybacks on a recent finding by Jessica Lundquist, a UW associate professor of civil and environmental engineering, and her lab that shows that tree cover actually causes snow to melt more quickly on the western slopes of the Pacific Northwest’s Cascade Mountains and other warm, Mediterranean-type climates around the world. Alternatively, open, clear gaps in the forests tend to keep snow on the ground longer into the spring and summer. Lundquist and her colleagues published their findings online this fall in Water Resources Research.
Common sense says that the shade of a tree will help retain snow, and snow exposed to sunlight in open areas will melt. This typically is the case in regions where winter temperatures are below freezing, such as the Northeast, Midwest and most of central and eastern Canada. But in Mediterranean climates – where the average winter temperatures usually are above 30 degrees Fahrenheit – a different phenomenon occurs. Snow tends to melt under the tree canopy and stay more intact in open meadows or gaps in a forest.
This happens in part because trees in warmer, maritime forests radiate heat in the form of long-wave radiation to a greater degree than the sky does. Heat radiating from the trees contributes to snow melting under the canopy first.
“Trees melt our snow, but it lasts longer if you open up some gaps in the forest,” Lundquist said. “The hope is that this paper gives us more of a global framework for how we manage our forests to conserve snowpack.”
For the study, Lundquist examined relevant published research the world over that listed paired snow measurements in neighboring forested and open areas; then she plotted those locations and noted their average winter temperatures. Places with similar winter climates – parts of the Swiss Alps, western Oregon and Washington, and the Sierra Nevada range in California – all had similar outcomes: Snow lasted longer in open areas.
“It’s remarkable that, given all the disparities in these studies, it did sort out by climate,” Lundquist said.
Even in the rainy Pacific Northwest, we depend on yearly snowpack for drinking water and healthy river flows for fish, said Rolf Gersonde, who designs and implements forest restoration projects in the Cedar River Watershed. Reservoirs in the western Cascades hold approximately a year’s supply of water. That means when our snowpack is gone – usually by the summer solstice – our water supply depends on often meager summer rainfall to get us through until fall, he said. Snowpack is a key component of the Northwest’s reservoir storage system, so watershed managers care about how forest changes due to management decisions or natural disturbances may impact that melting timetable.
The UW’s research in the watershed has been a beneficial partnership, researchers say. The 90,000-acre watershed is owned by the City of Seattle and provides drinking water to 1.4 million people. The area now is closed to recreation and commercial logging, but more than 80 percent of the land was logged during the early 20th century, and a large swath of dense, second-growth trees grows there now. Watershed managers have tried thinning and cutting gaps in parts of the forest to encourage more tree and plant diversity – that then leads to more diverse animal habitat – offering the UW a variety of sites to monitor.
The UW researchers acknowledge that temperature is a very broad predictor of snowmelt behavior, yet they expect their theory to hold true as they look more closely at the relationship between climate and snowmelt throughout the Pacific Northwest. They are collaborating with researchers at Oregon State University and the University of Idaho, and are ramping up a citizen science project asking hikers and snowshoers to share snow observations.
“This is really just a start,” said Dickerson-Lange, a doctoral student in Lundquist’s lab who is coordinating the citizen-science observations. “The plan is to refine this model. With climate change, a cold forest now might behave more like a warm forest 100 years from now. We want to be able to plan ahead.”
Co-authors of the recent paper are Nicoleta Cristea of UW civil and environmental engineering and James Lutz of Utah State University.
Funding for the research is from the National Science Foundation.
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For more information, contact Lundquist at jdlund@uw.edu or 303-497-8257 and Dickerson-Lange at dickers@uw.edu or 253-225-9909. Lundquist is on sabbatical but is reachable by email or phone.
here is a video of the field work:
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Have read through all the comments and havent seen this, so I will stick in my twopenneth. From my experience, as a forester and woodsman, I would suggest that another reason for differences in snow pack duration is that open areas, whether fields or forest clearings, lose heat on clear nights and the soil / vegetation becomes colder. As this continues and successive frosts set in, the clear areas hold their snow longer as their is no warm layer trapped below the snowcover. In forests there is less heat loss through radiation and consequently the soil layer is warmer
(less cold). As the snow falls it has an insulative effect and stops the frost penetrating deeper in to the soil. This can easily be seen in those years where heavy frosts occur before significant snowfall. The snow falling on frozen ground will last much longer than early snow which falls on non frozen ground.
“The hope is that this paper gives us more of a global framework for how we manage our forests to conserve snowpack.”
Why? Longer ski season in the trees?
Save the water?
Build a dam……….
Can you imagine how excited these researchers will get when someone gives them their first umbrella and they make the groundbreaking discovery that it is drier under an umbrella in a rainstorm than in the open air around it?
I just hope whoever gives them it remembers to put a cork on the pointy end. Wouldn’t want the little darlings injuring themselves in their excitement.
All this waffle…………. as I have always maintained, “……… there are townie (read CITY ) boys ( aka scientists) and Country lads ……….. ” who is more likely to know what goes on a day-to-day basis in the Countryside. Ask a Townie where the Sun rises or sets and where the Moon is likely to be tonight, etc – Generally ” NO IDEA” – hardly even able to look in the rigfht direction for the midday Sun! Gety a GRIP, – ALL OF YOU ! never mind the data from xys in avc , etc – just lok at the FACTS – OPEN YOUR EYES.
Divide & Rule is what it’s all about; throw in some articles to distract attention , teach the children some songs, – King’s new clothes, springs to mind, for ” keep the women barefoot, pregnant & working” should now be changed to “keep the populace imobile, full of expectations & occupied” .ie glad to have a job to pay the taxes and keep their homes – ‘ nose to the grindstone’ stuff .. Och! I ‘ve got better things to do this EVENING than write write write… right ? BUT it seems no one else is saying it – OFTEN ENOUGH & to the RIght authorities ???
As a ski mountaineer, I can attest that this discovery is every bit as groundbreaking as the “discovery” of sun cups a few months back. In higher elevation windy areas there can actually be greater depth in forested areas, but there are still wells around the trees.
RE: gymnosperm says:
November 14, 2013 at 10:27 pm
“…In higher elevation windy areas there can actually be greater depth in forested areas, but there are still wells around the trees.”
I was thinking the same thing. A lot depends on the temperature when the snow is falling. Often our early snow is sticky, and a lot gets hung up in the branches of trees and melts or sublimates before it ever gets to the ground. However in early January when temperatures get bitter the snow becomes powdery and comes sifting through the branches. Robert Frost describes it like this:
The way a crow
Shook down on me
The dust of snow
From a hemlock tree
Has given my heart
A change of mood
And saved some part
Of a day I had rued.
Also that dust of snow drifts constantly across the pastures, hissing in the wind, but in the woods the wind slackens and the snow can build up. On north slopes you can have snow still laying in the deep shade of spruce and hemlocks even in May’s warmth, when things are already blooming on the south slopes.
However you do notice those “wells” around tree trunks, even in the shadiest groves. I had never thought much about what causes them.
I tend to do such thinking for free, but it sure would be nice to get payed for wondering. However I think I would insist the money come from some rich person who happens to like the way I wonder. I couldn’t stomach taking money from taxpayers who can’t afford it, or from irresponsibly printed money that taxes children who aren’t even born yet.
Snow does NOT melt faster under trees. Snow does NOT accumulate to the same depth nor the same density of the pack under trees as it does on open ground. When the air flow over an area is altered, the snow “drops out” of the air at the edges of the forest. Snow melts at the same rate everywhere when exposed to air temps above 32 degrees F, it simply never was as DEEP between the trees. Duh.