The Avalanche Review, VOL. 13, NO. 2, DECEMBER 1994
Copyright © All Rights Reserved; AAA
SIMPLE
SNOW STABILITY TESTS
by Bruce Tremper
Everyone who has
ever watched any of those old avalanche disaster movies knows that, if nothing
else, avalanches are mysterious and unpredictable. Don't they just come roaring
down out of the heavens when you talk too loud or shoot a gun? Isn't that how
they work?
But old myths seem
to last forever, and many of us avalanche professionals spend a great deal of
time trying to bring the public up to date on this matter. "It's not that avalanches
are mysterious," I'm always telling them, "It's just that they're invisible."
We, as avalanche
professionals, spend most of our careers never getting a good look at the one
important parameter-the buried weaklayer. Why? Because it's buried, of course.
We have invented all kinds of tricks to make the stability of the snow reveal
itself. Counting all the usual tests, the unusual ones, and their variations,
I have heard of 101 ways to test snow stability.
No, I won't list
101 of them here but just the few which fit my own special criteria. Because
of my job as a backcountry avalanche hazard forecaster, I have to travel light
and fast and dig lots of snowpits. First, it has to actually work. Second, it
has to be quick-three minutes maximum-because I hate getting cold feet. And
third, it must be very simple and lightweight. Here they are, listed in order
of how much time each takes.
SKI POLE TEST (1-5 SECONDS)
Simply push your
ski pole into the snow feeling the unseen layers below. Most avalanche professionals
do this hundreds of times per day. With hard snow, use the handle-end of the
ski pole.
Advantage:
·
You can do it hundreds of times per day.
· Works well
with depth hoar especially in shallow snowpacks.
· Works well
for density inversions within the new snow.
Disadvantage:
·
Doesn't work with surface hoar.
· Doesn't work
well for deeper weak-layers.
· People think
you have a nervous tick, always poking the snow.
HAND SHEAR TEST
(5-20 SECONDS)
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Saw out a small square
of snow with your mitten and pull on it. Also, a popular test with the
Japanese is to cut out a cylinder of snow, wrap your arms around it and
pull. Either way, it's a quick way to test how well the surface snow is
bonded to the underlying snow.
Advantage:
·
You can do dozens of tests in a day.
· Works
well with new-snow instabilities.
· Works
well with shallow weak-layers.
Disadvantage:
·
Only good for shallow weak-layers.
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STEPPING ABOVE
THE SKI TRACK (5-20 SECONDS)
When following a diagonal
or horizontal ski track, simply step above the trail and try and kick
some surface snow onto the trail below. Or, you can kick the snow at the
apex of each switchback.
Advantage:
·
Can perform dozens of tests per day.
Disadvantage:
·
Only works on shallow weak-layers.
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SKI CUTS (5-20 SECONDS)
Although some squeemish
types and lay people think ski cuts sound dangerous, they have been a standard
technique among ski patrollers and helicopter ski guides for decades. The idea
is that if you are going to trigger an avalanche, you want to do it on your
terms, and minimize the odds of getting caught. Instead of just jumping in and
skiing a slope, start at the top of the slope in a point of safety and pick
out another point of safety across and down the slope. Then keep your speed
up and cut across the avalanche starting zone, all the while weighting on your
skis and trying to start an avalanche. In theory, your momentum should carry
you off of the moving slab and into the island of safety if an avalanche breaks.
You should ski cut the slope several times as you descend and at each breakover
you encounter.
Experienced avalanche
professionals will do this instinctively on any slope they plan on descending.
When learning ski cut techniques, or on slopes with dangerous consequences of
a slide, always wear a belay rope.
Advantages:
·
Quick.
· Good for
soft new snow with shallow weak layers.
Disadvantages:
·
Almost totally ineffective on hard slabs or deep weak-layers.
· Dangerous
if done improperly or on nasty slidepaths without a belay rope.
TEST SLOPES:
(5 - 30 SECONDS)
This is my favorite
backcountry test. Find a small, steep slope where the consequences of a slide
are small, such as a road cut, the side of a big stump, a mine dump, or a small
breakover in the slope. Then simply jump on the slope to see how it responds.
You can find test slopes nearly anywhere. Experienced avalanche professionals
seldom pass test slopes by without jumping on them. Remember that even on small
slopes, it's possible to get buried. Always have your partner watch from a safe
spot.
Advantages:
·
Easy to interpret results.
· Safe.
· Quick.
Disadvantage:
·
Dangerous if done on slopes with dangerous consequences.
· Not a good
test of deep weak-layers, especially ones overlain by hard slabs because of
the compressive support from the bottom.
TILT BOARD (20-60
SECONDS)
This has long been
a standard test for new snow instability at study plots. Simply cut out a square
of new snow the same dimensions as the blade of your shovel. Slide the shovel
blade under the block and pick it up. Tilt the shovel blade on edge progressively
steeper and steeper while tapping lightly on the bottom of the shovel until
the snow fails. The steeper the tilt, the more stable the snow.
Advantage:
·
Quantifyable (you can put
a number on it)
· Works well
with new snow instabilities.
Disadvantage:
·
Doesn't work well for deeper
weak-layers.
CORNICE TESTS
(5 SEC. - 3
MINUTES)
Once again, squeemish folks or lay-people might think cornice tests are dangerous
but they have been standard techniques among ski patrollers, helicopter ski
guides and especially climbers for decades. Cornices are the bombs of the backcountry.
Simply find a cornice which weighs significantly more than a person and knock
it down the slope. A cornice the size of a refrigerator or a small car bouncing
down a slope provides an excellent statility test. The smaller the cornice,
the less effective the test. You can kick the cornice, shovel it or best of
all, saw it with one of those new snow saws which mounts on the end of a ski
pole. With larger cornices you can use a parachute cord with knots tied in it
every foot or so which act like teeth on a saw. Throw the cord over the cornice
or push it over the edge with an avalanche probe. You can saw off a fairly large
cornice in under 5 minutes. Best to work with small, fresh cornices and not
the large, old and hard ones. Always use a belay if the consequences of a slide
are high. Cornices have a nasty habit of breaking farther back than you think
they should. You can also trundle heavy rocks down the slope which work just
as well as cornices and they're safer. This is also a great way to create a
safe descent route during very unstable conditions. Make an avalanche and use
the slidepath to descend.
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Advantages:
·
Probably
the best test of a slope besides using bombs.
·
Easy to interpret.
Disadvantage:
·
Very dangerous
if done improperly.
·
Small cornices don't
stress the slope enough for a reliable test.
·
Cornices aren't always
available.
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SNOWPIT TESTS
Most of the time you can
gather an incredible amount of information about the snowpack without ever taking
out your shovel. But sometimes the only way to get good information about deeper
weak-layers is to do the time-honored snowpit. Contrary to popular belief, it
doesn't have to take a lot of time. I almost never spend more than 10 minutes
in a snowpit. Often you can dig the hole without even taking off your skis,
but it usually helps to at least take off the uphill ski. Also, the steeper
the slope and the softer the snow, the easier the shoveling. For almost all
of these snowpit tests you need to be on a slope of at least 30 degrees in steepness.
The optimum steepness is 38 degrees since that's the most dangerous slope steepness
for slab avalanches.
Where to dig a snowpit
is just as important as how to dig one. The trick is to dig one in a slope most
representative of the slope you are interested in but without puting yourself
in danger. Often you can find a small test slope which faces the same direction
and the same steepness. Or, you can sneak into the slope in question through
thick trees or on a shallow spur ridge. Work your way into it. If one snowpit
gives you a green light, then move onto more hazardous terrain. Never dive into
the middle of a dangerous avalanche path without first gathering lots of additional
data about the stability of the slope. One of the worst places to dig a snowpit
is along ridgelines where the wind has affected the snow. Although the crown
face may break right up to the ridge, the place where you will most likely trigger
the avalanche is 100 or more feet down off the ridge. Avoid thick trees because
conditions are often quite different than on open slopes. However many cagy
avalanche professional have developed the habit of digging their snowpit just
above a tree so they can grab it if the slope does slide. Better yet, tie a
belay rope onto that tree. 1 almost always carry a lightweight belay rope and
use it on regular basis. Most important, dig lots of snowpits in lots of different
areas because the snow can vary quite a bit from place to place. Look for the
pattern of instability.
The times listed
for these snowpit tests don't include the time of digging the hole. Most snowpits
in reasonably soft snow, with a good shovel and on a steep slope take only a
minute or two. For very hard snow it may take twice that time. So you can add
a couple minutes to the times listed for digging a hole. When doing these various
snowpit techniques, I'm assumuing that you're using a snow saw, which makes
all these test go much faster, but you can get by without one in a pinch.
COMPRESSION TEST
(10-30 SECONDS)
I love this test.
It's quick, easy to interpret and works for most kinds of weak layers. Start
by isolating a column about the same size as the blade of your shovel,
in other words, about one foot by one foot. Be sure to completely isolate the
column. Then take the blade of the shovel and lay it flat on top. Finally start
tapping progressively harder on the shovel blade until the column fails. Start
with taps by articulating from your wrist, then by articulating from your elbow,
then from your shoulder using the full weight of your arm. In this way, the
test is quantifiable. In other words it doesn't depend on feel or the opinion
of the tester, but it has a reproducible number which is the same for most people
and can easily be communicated to others. For instance, it failed on an easy
tap from the elbow, or it failed on a moderate tap from the elbow or perhaps
a hard tap from the shoulder. Since snow stability is dependent on the size
of the trigger required to make it fail, this test is especially easy to interpret.
VARIATIONS:
The Swiss have been
developing a similar test but-typical of the Swiss-they use a standardized flat
plate in lieu of the shovel blade, and in lieu of a hand, they drop a onekilogram
weight from progressively greater heights until the column fails.
Depending on your
point of view, Americans are either too smart or too lazy to carry all that
extra weight. So Ron Johnson of the Southwest Montana Avalanche Center has developed
what he calls the "stuffblock test." He caries an extra stuff sack which he
fills with snow and a small, lightweight scale to weigh the stuff sack. He then
drops the stuff sack onto the column from progressively greater heights until
it fails. In other words, it accomplishes the same quantifiable result as the
Swiss test but with appropriate technology and lighter weight.
The Bruce Tremper
sub-variation is to drop my pack onto the column. It's always about the same
weight, so it's quantifiable like the other methods.
Advantages:
· Quick.
· Easy to interpret.
· Quantifiable.
· Works for
any type of weak-layer, especially effective with faced snow.
· What more
could you ask for?
Disadvantages:
·
Small sample size. You need to do several tests for consistent results.
· Doesn't work
on flat slopes.
SHOVEL SHEAR TEST(10-30
SECONDS)
The good-old shovel
shear test has been taught in most every avalanche class since time imortal
but unfortunately, it is often the only test that it taught. Even the inventors
of the shovel shear test agree that it may be a good test for finding and identifyng
weak layers, but it's not a very good test for determining the stability of
the snowpack because of: (1) the small sample size, (2) difficulty in interpreting
the results and (3) the subjective nature of the test.
First, make vertical
cuts with the snow saw in the snowpit wall about the same width as your shovel.
Then cut behind the column with the snow saw-not the whole column (a common
mistake) but only about a foot or two down. Then, insert the shovel behind the
column and pull. Don't lever on the shovel, but pull straight out. Then cut
another foot or two down, and pull again, and so on until you reach the bottom
of the column. Pay attention only to the smooth, straight shears which pop out
easily, and rank the shears as easy, moderate, hard, and so on. Turn each block
upside down to see what weak-layer was involved.
The test is hard
to interpret because you are removing the overlying snow before you test each
layer. Therefore, you will naturally find that the deeper the weak-layer, the
stronger it tends to be because it must support the load of overlying snow.
It's difficult to take this factor into account. In my experience, most students
using this test tend to think
the snow is much
more unstable than it actually is. Finally, because of the small sample size,
you need to do many tests to get a true feel for the stability of the snow.
But the shovel shear
test is a great test for two things: first, testing the snow on a flat slope
where most other snowpit tests don't work. Second, it's the only way t know
to find and identify surface hoar-one of the main culprits in human triggered
avalanches especially by avalanche professionals. That's the only reason why
I continue to use the test.
Advantages:
·
Works on a flat slope.
· One of the
only tests which finds and identifies surface hoar.
Disadvantages:
·
Hard to interpret.
· Subjective.
· Small sample
size (must do many tests for consistent results).
· Snow seems
more unstable than it actually is.
SKI SHEAR TEST
(10-30 SECONDS)
This is basically
the same as the shovel shear but you completely isolate the column, then insert
a ski behind the column and pull on the ski. Doug Fesler and ]ill Fredston of
the Alaska Avalanche School feel it gives more consistent results. This test,
however, suffers from the afore mentioned disadvantages of the
o shovel shear test.
Advantages:
·
Works on a flat slope.
· Can identify
surface hoar.
Disadvantages:
·
Hard to interpret.
· Subjective.
· Small sample
size (must do many tests for consistent results).
LOADED COLUMN
(30-60 SECONDS)
This is mostly an
avalanche forecaster's snowpit test which can estimate how much additional snow
will make a slope avalanche. The test is also quantifiable (you can put a number
on it)
First on a slope
of at least 30 degrees, completly isolate a column, it doesn't matter how big.
Then cut blocks of snow the same size as the top of the column and carefully
stack them on top of the column until it fails. The test basically duplicates
what happens on a slope during a storm. The more stable the snowpack, the more
weight required to make it fail. By estimating the density of the added snow
it's quantifiable. The test doesn't suffer from any of the difficulties in interpretation
like the shovel shear test, but it does take more time.
Advantages:
·
Good forecasting tool-how
much snow will make it slide?
·
Easy to interpret.
·
Duplicates what happens
in during a storm (but faster).
·
Works best with faceted
snow.
·
Quantifiable.
Disadvantages:
·
Takes more time.
·
Small sample size (must
do many tests for consistent results).
·
Must estimate the density
of the snow blocks added.
BURP THE BABY
TEST (30-60 SEC.)
One of Doug Fesler's
favorite tests, especially for teaching students. Once again, completely isolate
a column. Then tip the column toward you, rest it against your shoulder and
pat the back of the column with your hand like burping a baby. The farther you
have to tip it over and the harder you have to tap it, the more stable the snow.
It's a great test for developing a feel for the snow but for the same reasons
it takes time to develop a feel for how to interpret the results. It's a good
teaching tool for students so they can develop a feel for the mechanics of how
snow fails.
Advantages:
·
Good teaching tool.
·
Works with any kind of
weak-layer including surface hoar.
·
Good way to develop a feel
for the snow.
Disadvantages
·
Takes experience to interpret
results.
·
Small sample size (must
do many tests for consistent results).
RUTSCHBLOCK TEST
(1-2 MINUTES)
The Rutschblock test
(shear block) and it's cousin the Rutschkiel test (pronounced Rootch-kyle) have
rapidly become the standard snowpit test of choice for avalanche professional
who do a lot of snowpits. The main advantage is that they work with a larger
sample size which tends to smooth out any local variations in the snow. Second,
the test is quantifiable and very easy to interpret. Finally, it duplicates
what happens when a person skis the slope.
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First, on a slope of
at least 30 degrees, isolate a block of snow about a ski length across,
and a ski pole length up the slope (2 meters wide by 1.5 meters upslope).
If you use a snow saw which mounts on the end of an avalanche probe ski
pole you can cut the block in under a minute. With two people working
together with snow saws the job takes about 30 seconds. You can also use
the tail of a
ski to saw out the
block but it takes longer. Finally, you can shovel out the block which
takes a very long time especially in hard snow. Some people insert two
probe poles at the upper corners and use a parachute cord to saw out the
block but that also takes quite a bit of time. But the best way is a snow
saw mounted on the end of a ski pole. It's very quick and lightweight
and you can saw cornices with it-definitely standard equipment for anyone
venturing into avalanche terrain.
Some people don't cut the back of the column but in my opinion that's
a dangerous mistake. You are then testing the strength of the slab along
with the strength of the weak-layer, like mixing apples and oranges. Keep
it simple. Slabs don't cause avalanches, weak-layers do. If you don't
cut the back of the column you can't call it a Rutschblock. Name the test
after yourself if you want, but don't call it a Rutschblock because the
results you report don't mean the same thing.
The Rutschkiel test
is exactly the same as the Rutschblock except it's a triangle of snow
(with the point uphill) instead of a square block. Again, you can cut
with the snow saw on the end of the ski pole or insert a probe pole at
the upper apex of the triangle and saw with a parachute cord.
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Next, simply step onto the
block with your skis or snowboard on and jump progressively harder until the
block fails. Most people rank the test on a scale of one through seven.
1 Fails while isolating
the block
2 Fails while stepping onto the block
3 Fails with an easy weighting of the skis
4 Fails with one easy jump
5 Fails with one hard jump
6 Fails with several hard jumps
7 Doesn't fail
Advantages:
·
Large sample size
makes test more reliable
·
Duplicates what happens with a skier on the slope
·
Easy to interpret
·
Quantifiable
Disadvantage:
·
Takes more time but with
the proper snow saw not much more time
SUMMARY OF STABILITY
TESTS
Best Snowpit
Tests for Deep Slab Instabilities (ranked in order of reliability)
1
Rutschblock
2 Rutschkiel
3 Compression Test
4 Loaded Column
5 Ski shear, burp the baby
6 Shovel shear
Best Active Tests for
Deep Slab Instability
1
Cornice test (as long as it's a large cornice)
No other active
tests are effective on deep
slab instability
Best Active Tests for New Snow Instabilities (ranked in order)
1 Cornice Test
2 Test slopes
3 Ski cuts
4 Tilt board
5 Hand shear
6 Ski pole test
The Avalanche Review, VOL. 13, NO. 2, DECEMBER 1994
Copyright © All Rights Reserved; AAA