Introduction
Rain-on-snow is one of the major causes of winter snow avalanches in maritime climates and commonly triggers varying types of immediate and delayed avalanches (e.g. Reference Conway, Breyfogle and WilbourConway and others, 1989; Reference HeywoodHeywood, 1989; Reference Conway and RaymondConway and Raymond, 1993; Reference Osterhuber and KattelmannOsterhuber and Kattelmann, 1998; Reference FergusonFerguson, 2001). In the Pacific Northwest of North America, glide avalanches are commonly triggered by rain-on-snow events as liquid water penetrates the snowpack (Reference McClung, Walker and GolleyMcClung and others, 1994; Reference Clarke and McClungClarke and McClung, 1999). Due to evolving spatial distribution of liquid water in the snowpack, accurate forecasting is difficult. Although glide avalanches triggered by rain-on-snow events are well documented (e.g. Reference LackingerLackinger, 1987; Reference McClung, Walker and GolleyMcClung and others, 1994; Reference Clarke and McClungClarke and McClung, 1999), it is still uncertain how the timing of liquid water penetration into the snowpack triggers glide avalanches (Reference Colbeck and ChowColbeck, 1978, Reference Colbeck1979, Reference Colbeck1991; Reference KattelmannKattelmann, 1987). Changing climate has increased rain-on-snow events along the Cascade Mountain crest (Reference McCabe, Clark and HayMcCabe and others, 2007) and is one of the major causes of winter snow avalanches. The high rate of avalanche activity and repeatable glide events at Snoqualmie Pass, Washington, USA (Fig. 1), provides an exceptional opportunity to characterize glide avalanche processes.
Here we present results from an extreme rain-on-snow event that triggered a full-depth glide avalanche near Snoqualmie Pass (Fig. 1) and discuss the relations between the onset of rain-on-snow and full-release glide failure. Our goals are to characterize avalanche processes and weather variables that influence the onset and eventual release of glide avalanches.
Study Area
The study area, Rockface, is located 2.5 km north-northwest of Snoqualmie Pass, at 1055 m a.s.l. (Fig. 1) in the central Cascade Mountains. The area has a maritime snow climate that is characterized by heavy winter snows and mild temperatures (Reference Mock and BirkelandMock and Birkeland, 2000; Reference McClung and SchaererMcClung and Schaerer, 2006). Based on a 60 year average, the annual winter snowfall at nearby Snoqualmie Pass (921 m a.s.l.) is 11 m, with nearly 2500 mm of precipitation annually.
Rockface has a northeast aspect and an average slope of 35° (Fig. 2). The site is adjacent to the Alpental Ski Area, and the historic runout is capable of reaching beginner ski trails (Figs 1 and 2). Avalanche control on Rockface has been generally unsuccessful, similar to other glide avalanche slopes (Reference JonesJones, 2004).
Meteorological and snowpack observations
Meteorological and snowpack data come from the Washington State Department of Transportation (WSDOT) snow study site on Snoqualmie Pass (Fig. 1). Both manual and automated observations are gathered from this site. Manual observations occur once daily. These include new HN24 (new snow deposition over a 24 hour period) and total snow or HS (height of snowpack), snow density, snow water equivalent (SWE) and a snow stability profile. Instrumentation includes HN24 and HS measured with ultrasonic depth sensors, precipitation, air temperature, atmospheric pressure and relative humidity. Water outflow from the snowpack is measured with a lysimeter (e.g. Reference MartinecMartinec, 1987; Reference Carran, Hall, Kendall, Carran and ConwayCarran and others, 2001; Reference Conway and ElderConway, 2005). In addition, glide data were collected at the Rockface site (Stimberis and Rubin, 2005). In this paper, we concentrate on a 27 day period from 13 December 2008 to 8 January 2009 and focus on the 6–8 January 2009 rain-on-snow event.
Early-winter observations
The winter of 2008/09 began in earnest on 13 December 2008 when a storm deposited 57 cm of snow (47.8 mm snow water equivalent (SWE)) over a 36 hour period. This storm was followed in quick succession by additional storms of varying intensity including 63 cm of snow (45.9 mm SWE) during one 24 hour recording period. Over 460 cm of snow (465.2 mm SWE) were recorded over a 25 day period between 13 December 2008 and 6 January 2009 (Fig. 3).
Temperatures were below average for the region between 13 December 2008 and 6 January 2009, with sub-freezing temperatures and snowfall reported down to sea level. Temperatures at the WSDOT study plot dropped as low as −18°C during this period, though low temperatures averaged about −10°C. Two brief periods of rain were recorded, though the events were short-lived and did not penetrate the entire snowpack. Two thin crusts formed in the snowpack as a result of the brief rain events. Temperature gradients within the snowpack were ∼0.2°C m−1. Overall, the snow-pack was relatively cold and unconsolidated for a maritime region. Avalanches and avalanche control occurred throughout the early-winter period. The WSDOT performed 14 highway avalanche control operations during late December to early January.
January 2009 rain-on-snow event
By early January, weather forecasters at the US National Weather Service (NWS) identified a strong Pacific storm system forming in the subtropical regions. These systems, referred to as a ‘Pineapple Express’, can produce ample amounts of rain, high temperatures and flooding. By the evening of 4 January 2009 the storm system reached Washington State. The first 36 hours produced 53 cm of snow (74.6 mm SWE) (Fig. 3). By the morning of 6 January 2009, the warm front, combined with a strong jet stream, reached the region and snow turned to rain. A rain-on-snow event was unfolding and NWS forecasters were expecting a record-setting event.
Avalanche paths near Snoqualmie Pass produced minor avalanche activity at the onset of rain. The WSDOT study-plot snow lysimeter indicated that liquid water began to flow from the snowpack ∼3 hours after the onset of rain (Fig. 4). About 12 hours after the onset of rain, WSDOT avalanche forecasters assumed the snowpack was beginning to stabilize and no avalanche control was scheduled. Previous work suggests that avalanche release is rare after drainage through a snowpack has been established, even during continued rain (Reference Conway and RaymondConway and Raymond, 1993; Reference Conway and ElderConway, 2005).
At 2300 h Pacific Standard Time (PST), 15 hours after the rain began and nearly 12 hours after the lysimeter began recording water outflow from the snowpack, the first major avalanche initiated at 1035 m a.s.l. (Fig. 4) at Granite Mountain. This avalanche occurred after 91 mm of rain and 21 mm outflow from the snowpack. The avalanche path follows a stream bed and produced a massive flow of snow, ice, rock and trees that blocked the highway (730 m). The highway was closed to traffic, and over the next few hours massive amounts of water began to inundate the highway. An additional slush avalanche was reported around 0200 h PST on 7 January 2009, on the road to the Alpental Ski Area (Fig. 1).
At 0600 h PST on 7 January 2009, nearly 24 hours after the rain began, another substantial influx of snow, rocks, ice and trees covered the highway along a stream bed where avalanches have not been previously observed. Instruments at the WSDOT study plot had recorded 152 mm of rain and 43 mm of outflow by this time (Fig. 4). By 1100 h PST on 7 January 2009, a landslide released at the Hyak Ski Area (1035 m a.s.l.; Figs 2 and 4), destroying a house and the main chairlift (Fig. 5). About 185 mm of rain and 55 mm of outflow were recorded by the time the Hyak slide occurred. The Hyak event occurred 24 hours after the first outflow of water was recorded by the lysimeter. At 1500 h on 7 January 2009, a glide avalanche was recorded at Rockface after nearly 205 mm of rain and 60 mm of outflow (Fig. 4). By the time the storm ended, the January 2009 rain-on-snow event was classified as an extreme event, with a return period in excess of 100 years (personal communication from B. Bower, 2009).
Snow Glide
Air-temperature, precipitation, snowpack drainage and snow-depth data were collected in 15 min intervals at the WSDOT Snoqualmie Pass study plot (Fig. 1). Glide rates on Rockface were collected in 30 s intervals using a Celesco linear extension transducer (Stimberis and Rubin, 2005). Since visibility was generally poor and flooding damaged the road to the Alpental Ski Area (Fig. 1), no physical observations of Rockface were made during the rain-on-snow event.
During the rain-on-snow event, air temperature and rainfall at the Snoqualmie Pass study site were similar to temperatures and rainfall recorded at the Alpental instrument site (976 m a.s.l.). During the time of the Rockface glide event, air temperature remained several degrees above 0°C for >32 hours and received >60 mm of rainfall. Due to above-freezing temperatures and substantial rainfall, glide deformation was concentrated along the wetted snow/rock interface.
Glide response to a rain-on-snow event
Glide rates were minimal during the initial period of snowfall from 4 to 5 January 2009. Over a 19 hour period, 38 cm of snow fell (49 mm SWE) and <20 mm of glide/creep were recorded (Figs 4 and 6a). An additional 3.5 cm of snow (19 mm SWE) was recorded over the next 12 hours from 1200 to 2400 h PST on 5 January. The increasing density of the snow likely contributed to glide/creep acceleration as the Rockface glide sensor recorded an additional 300 mm of movement during that 12 hour period (Figs 4 and 6a). The HS experienced no net change during this period and temperatures averaged 0°C.
By 0800 h PST on 6 January, snow had changed to rain. An additional 110 mm of glide/creep occurred between 0000 and 0800 h PST on 6 January (Figs 4 and 6a). Precipitation rates increased rapidly as the warm front moved over the area. Rainfall became heavy, averaging 7 mm h−1 and peaking at 12.5 mm h−1 over the next 24 hours (0800 h PST on 6 January to 0800 h PST on 7 January). Air temperatures remained fairly consistent during the period, with a general warming trend after the onset of rain, reaching a maximum of 5°C. Glide/creep motion remained low and consistent during 6 January, averaging 6 mm h−1 with little variation in rate. The HS decreased ∼16 cm during the 8 hour period (∼20 mm h−1) prior to the onset of rain (Fig. 4). Glide increased by the end of 6 January and into the following day as glide rates accelerated and became increasingly erratic.
Precipitation rates of 7 mm h−1 on 7 January remained similar to the previous day, though there was a general decrease in intensity for a few hours prior to the glide avalanche. Outflow also decreased during this period. Air temperatures decreased to a minimum of 2.5°C and averaged ∼3.3°C prior to the avalanche (Fig. 4). An additional 40 cm of snow settlement at an average rate of 27 mm h−1 occurred on 7 January before the glide avalanche released. Between the onset of rain and the glide avalanche on Rockface, the WSDOT study plot recorded >200 mm of precipitation and 60 mm of outflow. The HS also decreased nearly 600 mm during that period. Over the 60 hour rain-on-snow event, the HS decreased >900 mm (Fig. 4).
Discussion
Rain-on-snow events occur most frequently during January in the Pacific Northwest (Reference McCabe, Clark and HayMcCabe and others, 2007) and are responsible for avalanche release, initially triggering avalanches within minutes of rainfall (Reference Conway and RaymondConway and Raymond, 1993). Continued rainfall may trigger deeper avalanches over an extended period (Reference Conway and ElderConway, 2005). During the January 2009 event, a glide avalanche occurred >32 hours after the onset of rain.
Based on variations in glide/creep rate and acceleration over a 16 hour period, we identified seven distinct glide sub-events (Fig. 6b). The first sub-event (sub-event A) is characterized by a constant glide rate of ∼28 mm h−1 and lasted nearly 5 hours. Sub-event A marks the first prolonged period of snow glide on Rockface since the onset of rain. Here the onset of glide correlates with the above-freezing temperatures and the presence of liquid water at the snow/ground interface (Fig. 6b).
Sub-event B marks the cessation of motion for ∼45 min (Fig. 6b). During this pause, 8.1 mm of rain and 2.5 mm of outflow were recorded. Snow settlement increased from 11 to 36 mm h−1 during sub-event B.
Sub-event C is distinguished by erratic or stick–slip motion for >4 hours (Fig. 6b). Precipitation and water outflow slowly declined during this sub-event (Fig. 2). Similar fluctuating glide motion was observed in the Swiss Alps (In der Gand and Zupaničič, 1966). Air temperature decreased by 1.6°C through the 4 hour period. The end of sub-event C marks the lowest air temperature recorded during the remaining rain-on-snow event.
Sub-event D is characterized by an increasing glide rate of ∼189 mm h−1 (Fig. 6b) and HS decreases ∼14 cm at a rate of 46 mm h−1. Air temperatures remain stable, averaging 3°C. Precipitation averages ∼5 mm h−1, beginning a relative lull before the next front reaches the area.
Similar temperature and precipitation trends continue into sub-event E. Glide rates substantially increase during this sub-event (Fig. 6b), with an average of nearly 190 mm h−1. Over 90 mm of glide occurs during one 7 min period, only to be followed by episodes of limited glide. Snow settlement rates substantially decreased in the final 30 min of sub-event E and closely correlate with a decline of glide rate.
Sub-event F, a 15 min period, is defined by no glide motion or snow settlement (Fig. 6b). Average precipitation values are similar to the previous sub-event, and air temperatures remain the same.
After the short pause of glide and snow settlement rates, sub-event G is defined by a rapid acceleration of glide rate over a 30 min period before glide avalanche failure (Fig. 6b). Snow settlement substantially increased during the latter part of sub-event G. Precipitation and outflow rates decrease to the lowest level during the 16 hour glide event.
In the aftermath of the Rockface avalanche, precipitation rates and air temperatures increased gradually over the next 12 hours. On 8 January, air temperatures began to decrease and after several more hours the precipitation rates began to decline. No additional avalanches were reported in the Snoqualmie Pass area following the Rockface avalanche.
Implications for Glide Failure
The delay between the onset of rain and the avalanche at Rockface is similar to previous reports of delayed avalanches (Reference Conway and ElderConway, 2005). At the time of the Rockface avalanche, rainfall was perhaps three to four times greater than outflow at the base of the snowpack (Fig. 4). Although glide deformation increases with lubrication along the snow/rock interface, water outflow from the snowpack does not always accurately forecast glide avalanches.
During periods of prolonged rain, delay between the onset of rain and failure might be longer than 32 hours. The weight of the additional water produced substantial gravitational loading of the snowpack. The delay between the onset of rain and failure is likely due to a combination of (1) the ground configuration of Rockface, (2) an increase of downslope stress due to additional loading from rain, and (3) the consolidation of the snowpack during the rain event. A rock dihedral intersects the smooth rock surface along the lower flank of the avalanche path (Fig. 2c). The snowpack upslope of the dihedral is often characterized by extensive buckling and bulging prior to glide avalanche release, indicating the dihedral provides sufficient buttressing to support the snowpack during the glide events that precede the glide avalanche release. Although our data show other short-period sub-events (e.g. sub-event E), rapid glide during sub-event G might represent a precursory event (Fig. 6b). Additional data are required before we can identify precursory short-period glide events.
The low air temperatures, averaging −10°C, prior to the rain-on-snow event produced a relatively unconsolidated snowpack that could readily anchor itself to the irregularities of the underlying rock. Subsequent snowpack settlement produced from creep driven by rising temperatures and rain results in a dense and cohesive snowpack. Applied stresses acting on the cohesive snowpack coupled with liquid water at the snow/ground interface will create a snow slab that will glide over bed surface irregularities. Thus, the combination of the bed surface and initial snowpack conditions exert fundamental control of avalanche timing during rain-onsnow events.
The interval between the onset of rain and failure raises important questions about the physical processes that control glide failure. In contrast to our understanding of non-Newtonian glacial dynamics where the Navier–Stokes equation describes the underlying physics, there is no general consensus about a correct model(s) that describes the motions of snow avalanches and snow glide (e.g. Reference McClungMcClung, 1981; Reference KambKamb, 1987).
The interval between the onset of rain and failure raises important questions about the physical processes that control glide failure. Based on our studies, we suggest that glide motion occurs in three stages: (1) initiation of glide/sliding on a small portion of the slip surface, (2) growth of the slip surface by overcoming frictional resistance along asperities and (3) sudden change from stick–slip mode to rapid failure. Sudden failure occurs when the accumulated stress is higher than friction resistance along the snow-slab/ground interface.
During the January 2009 rain-on-snow event, the base of the snowpack was at the melting point. This might have allowed water pressure to build up under the snowpack. Increased water pressure perhaps lifted the snowpack above the underlying rock surface. Friction at the lateral shear margins (e.g. dihedral that intersects Rockface; Fig. 2) and bedrock bumps or irregularities under the snow that act as sticky spots prevented the glide velocity from cascading out of control. In this context, cyclic stick–slip might result in significant wear along the asperities on the base of the snow surface. The asperities act like anchors that hold a ship in the water; static friction counteracts the downslope stress. Asperities at the base of the snowpack might include ice lenses or crusts that are spatially distributed along the base of the snowpack. If the basal water-pressure controls slip, perhaps cyclic stick–slip glide is correlated with marked time variations in basal water pressure or water-flow velocity fluctuations.
Since stabilization generally occurs after drainage through the snowpack is well established, it is not surprising that avalanches occurred after substantial outflow from the base of the snowpack.
Acknowledgements
Our study was supported by the Department of Transportation, Washington State, and Central Washington University. We thank the Alpental Pro Patrol and Summit at Snoqualmie for providing access and field assistance. We thank P. Winberry for helpful discussions. H. Conway and S. Conger provided thoughtful reviews and helpful comments that substantially improved the manuscript. This is EOS contribution No. 27.