TY - JOUR
T1 - Wildfire-resistant biological soil crusts and fire-induced loss of soil stability in Palouse prairies, USA
AU - Bowker, Matthew A.
AU - Belnap, Jayne
AU - Rosentreter, Roger
AU - Graham, Bernadette
N1 - Funding Information:
Valuable field assistance was provided by Kate Kurtz. Sasha Reed provided suggestions for improving pigment analyses. Soil samples were processed by Chelsey Heimes, Brandon Stevens, David Wirth, and Tamsin McCormick. We thank Whit Weatherford and Susan Geer of the U.S. Forest Service for providing logistical support and discussion. Julie Hilty and Paula Brooks initially proposed a study of BSCs and fire ecology in Hell’s Canyon. We would like to thank Boise State University Department of Biology for use of the lichen herbarium. Dr. Nancy C. Johnson and two anonymous reviewers improved an earlier version of this work. We thank the Idaho Bureau of Land Management and US Geological survey for financial support. This work was funded by the US Forest Service (USDA) under interagency agreement 00-IA-11061600-012. M.B. thanks the Merriam-Powell Center for Environmental Research for a fellowship award.
PY - 2004/5
Y1 - 2004/5
N2 - Frequent low-intensity fires are a natural component of the ecology of the Palouse prairies of northwestern North America. To study the effects of fire upon biological soil crusts (BSCs) occurring in these grasslands, we sampled three burned (in 2000) sites and three unburned sites in the Hell's Canyon area (OR, USA) ∼1 year post-fire. We measured vascular plant and BSC cover, soil microbe pigmentation, texture and chemistry, and soil surface physical properties (stability and rugosity). Festuca idahoensis was two times more abundant in unburned plots (P=0.0006), and vascular plant and litter cover were generally higher in unburned plots. At the community scale, there was no difference in the lichen and moss species composition, suggesting much less drastic effects of fire on BSCs than reported in other systems. Soil surface stability (measured using slake value) was significantly lower in burned sites than unburned sites (median value=5 versus 6, P=0.008), a result which is likely due to the greater density of lichens and mosses encountered in the unburned plots. Soil microbe pigmentation was lower in burned plots (P=0.03), suggesting that the biomass of photosynthetic microbes had decreased; however, the presence of intra- and extracellular pigments in burned soils indicates that microorganisms were not eradicated. Pigments most strongly associated with cyanobacteria were more abundant in unburned sites, suggesting that cyanobacteria may have been more strongly impacted by the fire than other BSC components. Composition of nutrients and surface rugosity did not differ significantly between treatments. We hypothesize that Palouse prairie soil crusts are relatively resistant to wildfire because of low fire intensity and their occupation of space away from the vascular plant fuel load.
AB - Frequent low-intensity fires are a natural component of the ecology of the Palouse prairies of northwestern North America. To study the effects of fire upon biological soil crusts (BSCs) occurring in these grasslands, we sampled three burned (in 2000) sites and three unburned sites in the Hell's Canyon area (OR, USA) ∼1 year post-fire. We measured vascular plant and BSC cover, soil microbe pigmentation, texture and chemistry, and soil surface physical properties (stability and rugosity). Festuca idahoensis was two times more abundant in unburned plots (P=0.0006), and vascular plant and litter cover were generally higher in unburned plots. At the community scale, there was no difference in the lichen and moss species composition, suggesting much less drastic effects of fire on BSCs than reported in other systems. Soil surface stability (measured using slake value) was significantly lower in burned sites than unburned sites (median value=5 versus 6, P=0.008), a result which is likely due to the greater density of lichens and mosses encountered in the unburned plots. Soil microbe pigmentation was lower in burned plots (P=0.03), suggesting that the biomass of photosynthetic microbes had decreased; however, the presence of intra- and extracellular pigments in burned soils indicates that microorganisms were not eradicated. Pigments most strongly associated with cyanobacteria were more abundant in unburned sites, suggesting that cyanobacteria may have been more strongly impacted by the fire than other BSC components. Composition of nutrients and surface rugosity did not differ significantly between treatments. We hypothesize that Palouse prairie soil crusts are relatively resistant to wildfire because of low fire intensity and their occupation of space away from the vascular plant fuel load.
KW - Biological soil crusts
KW - Fire ecology
KW - Grasslands
KW - Pigments
KW - Soil stability
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U2 - 10.1016/j.apsoil.2003.10.005
DO - 10.1016/j.apsoil.2003.10.005
M3 - Article
AN - SCOPUS:1842583011
SN - 0929-1393
VL - 26
SP - 41
EP - 52
JO - Applied Soil Ecology
JF - Applied Soil Ecology
IS - 1
ER -