3.2. Field Findings
There was a significant slope location and seasonal effect (F
2,189 = 55.9,
p < 0.001 and F
2,189 = 5.9,
p = 0.003 respectively) on depth to water table across all sites. Toe slope locations had shallower water table levels than the other slope positions (
Figure 3a) and were most often above the 60 cm threshold used to identify wet locations in 2006 and 2007 combined. Summer rainfalls were higher in 2007 (309 mm) than in 2006 (154 mm), however water table trends were similar between years. As expected, spring months had shallower water table levels than the summer months (
Figure 3b).
The variability of Kfs values was high within and across sites, with coefficients of variation (CV’s) ranging between 62% and 161% (
Table 5). Kfs typically exhibits large spatial variability to which texture (e.g., highest Kfs in Belisle Creek–silty clay loam) and structure of soils is most directly related [
38,
39]. Average Kfs results were particularly high overall compared to K values published elsewhere [
33,
40] near the low end of saturated hydraulic range for coarse-textured soils [
39]. This can be attributed to an overestimation of the α*-parameter [
41]. Minimum K results appear more like actual values (
Table 5). The abundant presence of silt in the sand matrix may disperse and clog up the conductive pores upon wetting.
Table 5.
Comparison of saturated hydraulic conductivity (Ksat) between forested and clear-cut areas for the five selected sites. Kmean is geometric mean Kfs value, Kmax is maximum Kfs value, Kmin is minimum Kfs value, CV is coefficient of variation, and Db is soil bulk density.
Table 5.
Comparison of saturated hydraulic conductivity (Ksat) between forested and clear-cut areas for the five selected sites. Kmean is geometric mean Kfs value, Kmax is maximum Kfs value, Kmin is minimum Kfs value, CV is coefficient of variation, and Db is soil bulk density.
Site | Condition | N † | Kmean | Kmin | Kmax | CV | Db (0–5 cm) | Db (5–10 cm) |
---|
(mm h−1) | (%) | (Kg/m−3) | (Kg/m−3) |
---|
Belisle Creek | Forested | 26 | 508a ‡ | 133 | 2686 | 73 | 933a § | 1140a |
| Clearcut | 29 | 612a | 108 | 1840 | 79 | 972a | 1070a |
Targe Creek | Forested | 28 | 292a | 18 | 2804 | 159 | 990a | 1370a |
| Clearcut | 33 | 115b | 7 | 1580 | 134 | 1150b | 1380a |
53km Road | Forested | 10 | 158a | 22 | 652 | 104 | 1084a | 1311a |
| Clearcut | 25 | 144a | 4 | 806 | 161 | 1058a | 1315a |
Cobb Lake | Forested | 25 | 299a | 101 | 680 | 66 | 1071a | 1275a |
| Clearcut | 27 | 234a | 83 | 1148 | 75 | 1065a | 1138a |
Pitka Creek | Forested | 30 | 144a | 50 | 482 | 62 | 940a | 945a |
| Clearcut | 27 | 306a | 68 | 1440 | 68 | 960a | 980a |
Figure 3.
(a) Average water table depth at each slope location during 2006 and 2007 (least squares mean and 95% CI, n = 69) and (b) average seasonal water table depths at all locations for 2006 and 2007 (least square means and 95% CI, spring and summer n = 84, fall n = 39).
Figure 3.
(a) Average water table depth at each slope location during 2006 and 2007 (least squares mean and 95% CI, n = 69) and (b) average seasonal water table depths at all locations for 2006 and 2007 (least square means and 95% CI, spring and summer n = 84, fall n = 39).
There was no clear salvage logging effect on drainage patterns. Saturated soil infiltration did not show consistently lower values in cutblock areas (
Table 5), possibly due to careful logging practices and large sampling error. Where compaction was evident such as at Targe Creek (
i.e., lower Kfs and higher Db between 0 and 5 cm depth in the clear-cut) soil disturbance from harvesting led to poor drainage. Interestingly, the finer-texture soils at Belisle Creek had the highest rates of Kfs, which cannot be explained by texture alone since lower rates would have been expected (
Table 3). At this site, the surface horizon had a loose crumb structure, which provided a very porous medium.
Some differences in volumetric soil moisture were observed at the qualitative assessment sites across years, treatments, slope locations, and seasons (
Figure 4). Not all differences were statistically significant. Although there appears to be differences between treatments, it is not statistically significant (F
1,186 = 3.86,
p = 0.05). There were differences in seasons and locations (F
2,186 = 11.14,
p < 0.001
, F
1,186= 952.05,
p < 0.001, respectively) with both the spring season and toe location having higher soil moisture than other seasons or slope positions. There was also a significant difference between years, with 2007 having generally higher soil moisture than 2006. This was expected because 2007 received more rainfall than 2006.
Figure 4.
Average soil moisture conditions across (a) years; (b) seasons; (c) locations; and (d) treatments (Least squares means and 95% CI, n = 96). Line at 30% soil moistures identifies wet soil threshold.
Figure 4.
Average soil moisture conditions across (a) years; (b) seasons; (c) locations; and (d) treatments (Least squares means and 95% CI, n = 96). Line at 30% soil moistures identifies wet soil threshold.
3.3. Post-Hoc Model Evaluation
The principal components analysis of the water table and average volumetric soil moisture content identified two groups of indicators that explained 90% and 80% of field data variability, respectively (
Table 6). The general linear model (GLM) for water table and soil moisture data respectively refined this list of indicators, identifying lodgepole pine content, understory, drainage density, sensitive soils, and the topographic index as the most significant indicators. Although each GLM analysis provided an equation to predict specific values for water table or soil moisture, these formulae are not presented here because water table elevations and soil moisture cannot be predicted at the watershed scale. Instead, the equations were used to develop a new hazard prediction formula based upon the coefficient’s scale and sign (
i.e., positively or negatively correlated to depth to water table or soil moisture) for each indicator. Hazard rankings were considered correct when high hazard sites were wet in both the forest and cutblock locations, moderate sites could be wet in the cutblock due to the loss in transpiration, and low sites were dry in both locations.
Table 6.
Hazard indicators that were most effective at explaining data variability as identified by the principal components analysis. Note the same indicators were identified for both measurements.
Table 6.
Hazard indicators that were most effective at explaining data variability as identified by the principal components analysis. Note the same indicators were identified for both measurements.
Measurement | Component | Indicator |
---|
Water Table Depth | 1 | Drainage Density |
Sensitive Soils |
Understory |
Watershed Length:Width |
2 | Topographic index |
Lodgepole Pine Cover |
Soil Moisture | 1 | Sensitive Soil |
Topographic Index |
Relief Ratio |
Drainage Density |
2 | Lodgepole Pine Cover |
In keeping with the
a priori grouping of indicators, two groups were chosen for the
post-hoc formula, namely the potential for increased delivery of precipitation to the forest soil and the retention of precipitation reaching the soil surface. The
post-hoc hazard formula is:
where:
- -
Lodgepole Pine: <30% cover (0.1), 30%–50% (0.3), 51%–70% (0.7), and >71% (1.0);
- -
Understory: SBSdk (0.10), SBSdw3 (0.25), SBSdw2 (0.5), SBSmc3 (0.75), SBSmc2/ESSFmv1 (1.0) (SBSdk—Sub-boreal spruce dry cool, SBSdw3/2—Sub-boreal spruce dry warm, SBSmc3/2—Sub-boreal spruce moist cold, ESSFmv1—Engelmann spruce sub-alpine fire moist very cold);
- -
Drainage Density: <1 km/km2 (0.1), 1–2 km/km2 (0.25), 2–3 km/km2 (0.5), 3–4 km/km2 (0.75), >4 km/km2 (1.0);
- -
Sensitive Soils: 0% of watershed area with fine soils (1.0), 0–10% (0.75), 10%-20% (0.5), 20%–30% (0.75), >30% (0.1).
- -
Topographic Index—dimensionless value, calculated range here is between 5 and 14 with increasing values representing a decrease in watershed slope for a given size watershed.
This formula is more hydrologically relevant than that presented for the
a priori approach because it emphasizes watershed characteristics that have direct influence on net precipitation and its retention such as understory, soil type, and the relative slope of the watershed. For example, understory can lower the increase in net precipitation and also transpire [
14,
19], areas with less sensitive soils may have better drainage than those with sensitive soils, and the area based slope of the watershed indicates retention time of water on the soil surface [
22].
Scores generated by the
post-hoc formula were then ranked from one to 100 with ties receiving the same rank (
i.e., 50, 51, 51, 52 were ranked 50, 51.5, 51.5, 53). High hazard sites were those with the upper 25th percentile of ranked scores (
i.e., 1–25), moderate hazard watersheds were the middle 50% (26–74), and the low hazard watersheds were the lower 25th percentile of scores (75–100). In contrast to the
a priori approach, the
post-hoc assessment correctly identified all sites (
Table 7).
High hazard watersheds had significantly shallower depth to water table at the summit across years (
Figure 5, F
2,57 = 5.61,
p = 0.006). Harvesting effects on water table depth were not detectable as dead and dying pine stands had low transpiration due to dead pine trees as well as increased water delivery to soil more comparable to cutblock areas than to non-infested stands at toe and summit locations. High hazard sites had shallow water tables that were on average 25 cm closer to the soil surface than moderate and low hazard sites (
Figure 5). Mid-slope water table was not affected by risk, season or treatment because midslope drainage is mostly controlled by gravity.
Figure 5.
Average depth to water table at the summit slope location for each hazard class (error bars represent 95% CI, high n = 24, moderate n = 20, low n = 25).
Figure 5.
Average depth to water table at the summit slope location for each hazard class (error bars represent 95% CI, high n = 24, moderate n = 20, low n = 25).
All toe slope sites were wet regardless of site condition and hazard. Toe slopes had shallower water table levels in spring compared to summer whereas water table levels were the same across seasons for mid-slope and summit positions. The deepest water table was recorded in the fall suggesting effects of spring runoff on toe-slope receiving areas diminished during the summer until fall precipitation replenishes the soil moisture (
Figure 6).
Table 7.
Watershed hazard prediction for a priori and post-hoc assessment, field data verification summary for volumetric soil moisture and water table elevation along with comments on whether the prediction was correct, over- or underestimated. Table values identify whether the average condition was wet or dry during the summer months of 2007, the wettest summer during the sample period. Post-hoc hazard prediction and hazard scores for 2007 are not included for those watersheds used to generate the post-hoc model.
Table 7.
Watershed hazard prediction for a priori and post-hoc assessment, field data verification summary for volumetric soil moisture and water table elevation along with comments on whether the prediction was correct, over- or underestimated. Table values identify whether the average condition was wet or dry during the summer months of 2007, the wettest summer during the sample period. Post-hoc hazard prediction and hazard scores for 2007 are not included for those watersheds used to generate the post-hoc model.
Watershed | a priori Hazard 2006
| Post-hoc Hazard 2007
| Volumetric Soil Moisture Content
Forest/Cutblock | Water Table Elevation
Forest/Cutblock | a priori Prediction
| Post-hoc Prediction
|
---|
Peta Creek | Low | Low | N/A | dry | Correct | Correct |
Angly Lake | Low | N/A * | N/A | dry | Correct | N/A |
10573 | Moderate | Low | dry/dry | N/A | Correct | Correct |
Pitka Creek | Low | Low | N/A | dry/dry | Correct | Correct |
Shaydee | Low | N/A | dry/dry | N/A | Correct | N/A |
10330 | Low | N/A | dry/dry | N/A | Correct | N/A |
10557 | High | N/A | dry/wet | N/A | Overestimate | N/A |
Crystal Lake | High | Moderate | N/A | dry | Overestimate | Correct |
Chowsunkut Lake | High | Moderate | N/A | dry/dry | Overestimate | Correct |
Belisle Creek | High | Moderate | N/A | dry/dry | Overestimate | Correct |
10485 | High | N/A | dry/dry | N/A | Overestimate | N/A |
10610 | Moderate | Moderate | dry/dry | N/A | Correct | Correct |
10411 | Moderate | N/A | wet/wet | N/A | Underestimate | N/A |
Targe Creek | Moderate | High | N/A | wet/wet | Underestimate | Correct |
Targe Creek-44 | Moderate | High | wet/wet | wet/wet | Underestimate | Correct |
10426 | High | N/A | dry/wet | N/A | Overestimate | N/A |
Cobb Lake | Low | High | N/A | wet/wet | Underestimate | Correct |
Figure 6.
Seasonal average depth to water table at toe slope locations (error bars represent 95% CI, n = 27 spring and summer n = 13 for fall).
Figure 6.
Seasonal average depth to water table at toe slope locations (error bars represent 95% CI, n = 27 spring and summer n = 13 for fall).
The analysis of ln-transformed Kfs from all sites indicated a statistically significant effect on watershed hazard (F
3,256 = 4.10,
p = 0.007) and site condition (F
5,254 = 3.71,
p = 0.003). Highest measured hydraulic conductivities were found in the high hazard forested sites. In contrast, moderate hazard clear-cut area had the lowest Kfs but soil disturbance was not observed. Great variability in Kfs in part due to very high spatial variability in soil properties may explain this result. Based on our sampling, harvesting did not lead to a significant reduction in Kfs across watershed hazard. There was faster surface drainage in the high hazard MPB areas than in the low hazard MPB areas. This indicates that differences in Kfs may not be explained by high water table levels, which are less likely to occur where surface drainage is fast. Hard almost cemented layers less than 60 cm deep were observed during soil pit excavation at some high and moderate hazard sites (e.g., Targe Creek, watersheds 10557 and 10426) that may impede drainage similar to that observed in Ortstein layers [
42]. Although not impervious to water, the naturally compacted layer has a slower percolation rate that may be inadequate to drain large quantities of water reaching the soil in stands with a dead pine overstory or large salvage harvested areas. Under these conditions, soil saturation persists longer after spring runoff and a large summer storm can quickly fill up available storage in the soil profile raising the water table quickly, which may impede forest management activities.
The influence of pre-existing conditions in the soil profile such as a moist and soft layer lying over a dry or hard subsurface layer can be exacerbated by compaction [
43] and may result in a higher hazard for salvage-logged areas. For example, there was a statistically significant relationship between site condition and Kfs (
p < 0.01) at Targe Creek (
Table 5). Compaction was evident in the clear-cut sampling areas and sample sites showed a significant increase in bulk density in the top 5 cm of soil following skidding (
Table 5). These compacted areas were characterized by a platy structure and loss of original structure [
44]. The reduction in large pore space in the clear-cut, which is responsible for most of the saturated flow, produced an average Kfs rate of 115 mm h
−1), which represented a reduction of 57% in Kfs from the MPB forest. Harvesting operations and subsequent soil compaction can decrease field saturated hydraulic conductivity [
45].