Journal of Arid Environments

Available online 5 May 2015

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Prescribed fire effects on resource selection by cattle in mesic sagebrush steppe. Part 2: Mid-summer grazing

• Patrick E. Clark^{a, ,} ,
• Jaechoul Lee^b,
• Kyungduk Ko^b,
• Ryan M. Nielson^c,
• Douglas E. Johnson^d,
• David C. Ganskopp^e,
• Fredrick B. Pierson^a,
• Stuart P. Hardegree^a

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doi:10.1016/j.jaridenv.2015.03.005

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Highlights

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Beef cows were tracked with GPS for 2 yrs prefire and up to 5 yrs postfire on sagebrush steppe.

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A resource selection function accurately predicted prefire and postfire cattle use.

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Elevation, slope, NDVI standard deviation, and distance to upland water sources were the primary drivers of prefire cattle use.

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Prefire cattle selectivity was neutral towards areas later burned.

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Cattle selected for burned areas during 3 of the 4 postfire years evaluated.

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Abstract

Prescribed fire can release herbaceous forages from woody plant competition thus promoting increased forage plant production, vigor, and accessibility. Prescribe fire also consumes standing litter thereby improving forage quality and palatability. Consequently, prescribed fire is commonly considered an effective tool for manipulating livestock distribution on rangelands. Efficacy of this tool on mesic sagebrush steppe, however, has received little research attention. Beginning in 2001, resource selection by beef cows under a mid-summer (July) grazing regime was evaluated using global positioning system (GPS) collars for 2 years prior to and for up to 5 years after a fall prescribed fire was conducted on mesic sagebrush steppe in the Owyhee Mountains of southwestern Idaho, USA. Cattle selected for burned areas during the first, second, and fifth postfire years. Cattle had exhibited neutral selectivity towards these areas, during one of the two prefire years. Burning in the uplands reduced cattle use of near-stream habitats but only during the second postfire year. Differences in phenological timing of grazing may account for differences in cattle response to burning noted between this study and one conducted nearby under a spring (May) grazing regime. This is a case study and caution should be taken in extrapolating these results.

Keywords

• Burning;
• GPS tracking;
• Livestock distribution;
• Modeling;
• Rangeland improvement;
• Riparian use

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1. Introduction

Fire plays an important ecological role as a disturbance agent which promotes successional cycling (Christensen, 1985, Keane et al., 2004 and Turner et al., 1997). Many woody plant species are killed or reduced by fire. Western juniper (Juniperus occidentalis Hook.) is one such species and fire serves to control the extent of this invasive native plant and its encroachment into sagebrush steppe rangelands ( Burkhardt and Tisdale, 1976 and Miller and Rose, 1999). Burning of shrubs and/or trees also releases associated herbaceous plants from woody competition ( Bates et al., 2011, Miller et al., 2000 and Wrobleski and Kauffman, 2003). Fire consumes standing litter accumulations in herbaceous plants, often without unduly compromising plant vigor ( Willms et al., 1980a). Removal of standing litter from forage species like bunchgrasses can increase nutritional quality and palatability to grazing wildlife and livestock ( Cook et al., 1994, Hobbs and Spowart, 1984, Willms et al., 1980a, Willms et al., 1980b, Willms et al., 1981 and Young and Miller, 1985). Exotic plant invasions, poorly-managed livestock grazing, and wildfire suppression, however, have drastically altered the historic fire regimes on many rangelands of the world ( Brooks et al., 2004 and D'Antonio and Vitousek, 1992). While some systems, like those converted to exotic annual grasslands, now have too much fire ( Brooks et al., 2004), others often have too little (e.g., higher-elevation, mesic sagebrush steppe; Miller and Rose, 1999). In the later case, in the absence of fire, fuels have accumulated to excessive and hazardous levels. Stands of shrubs and trees have become exceptionally dense and decadent. Competition from these woody plants and physical obstruction by their canopies have depressed the presence, vigor, and/or production of herbaceous forage plants and reduced forage accessibility to wildlife grazers and livestock ( Miller et al., 2000). Consequently, there is a critical need on many rangelands, where fire has been wrongly excluded, to re-establish an appropriate fire cycle. Hazardous fuel accumulations and proximity to human settlement, infrastructure, or valuable commodities (e.g., flammable crops or timber); however, commonly prohibit the use of “let-burn” wildfire management policies on these rangelands. Fortunately, it is often possible to use carefully-managed, prescribed fire as a safe and effective means of re-initiating and/or maintaining an appropriate fire cycle.

Prescribe fire can promote increased forage production, quality, and palatability while also opening up new foraging areas where wildlife and livestock grazing was previously excluded by dense shrub canopy (Cook et al., 1994, Davies et al., 2012, Hobbs and Spowart, 1984, Willms et al., 1980a, Willms et al., 1981 and Young and Miller, 1985). Research in a number of rangeland ecosystems; including montane and prairie grasslands, shrub steppe, and savanna, have demonstrated prescribed burns are highly attractive to grazing animals and, in some cases, can be used to manipulate animal distribution (Augustine et al., 2010, Bates et al., 2009, Hobbs and Spowart, 1984, Klop et al., 2007, Peek et al., 1979, Van Dyke and Darragh, 2007 and Vermeire et al., 2004). As such, it is reasonable to hypothesize prescribed burning could be used to manage cattle resource-selection patterns on sagebrush-steppe rangelands.

The sagebrush-steppe ecosystem occurs on about 44.4 million ha of western North America. A higher-elevation, more mesic portion of this ecosystem is dominated by mountain big sagebrush (Artemisia tridentata Nutt. ssp. vaseyanna Beetle), with antelope bitterbrush (Purshia tridentata [Pursh] DC) and/or mountain snowberry (Symphoricarpos oreophilus A. Gray) often occurring as co-dominants. The mesic sagebrush steppe represents a considerable proportion of the sagebrush-steppe ecosystem and is a principal habitat of many wildlife species, some of which are threatened or endangered (e.g., greater sage-grouse [Centrocercus urophasianus Bonaparte]. Mesic sagebrush steppe is also important livestock grazing land in several western regions. The ability of exotic annual grasses, such as cheatgrass (Bromus tectorum L.) and medusahead (Taeniatherum caput-medusae [L.] Nevski) to invade and, through repeated burning, convert sagebrush steppe into annual grassland is a considerable threat in the drier, lower-elevation portions of the sagebrush-steppe ecosystem ( Brooks et al., 2004; Chambers et al., 2007). Mesic sagebrush-steppe rangelands, however, are currently much less susceptible to exotic annual grass conversion. Mesic sagebrush steppe is susceptible, however, to invasion by native woody plants like western juniper ( Burkhardt and Tisdale, 1976, Miller and Rose, 1999 and Miller and Wigand, 1994). Long-term absence of fire can promote conversion from mesic sagebrush steppe to juniper woodland which can often have adverse consequences to rangeland hydrology, soil stability, wildlife habitat, and livestock grazing ( Noson et al., 2006, Pierson et al., 2010, Pierson et al., 2013 and Wall et al., 2001).

While prescribed fire is widely considered to be an effective tool for controlling western juniper encroachment in the mesic sagebrush steppe, claims about its efficacy for also managing livestock distribution have received comparatively little research attention. It has been found; however, under a spring (May) grazing regime, that fall prescribed fire in mesic sagebrush steppe can promote increased use of burned areas by cattle for up to 5 years postfire (Clark et al., 2014). The longevity of this cattle resource-selection response to fire is quite unprecedented even in other rangeland types. The phenological timing of grazing, however, may influence both, the efficacy of prescribed fire for manipulating cattle distribution and the longevity of this effect. In addition, site factors including slope, distance to water, and vegetation composition and structure affect cattle distribution and may interact with or cancel out fire-related effects (Bailey, 1995, Bailey, 2005, Cook, 1966, Ganskopp, 2001, Ganskopp and Vavra, 1987, Howery et al., 1996, Howery et al., 1998, Loza et al., 1992, Mueggler, 1965, Pinchak et al., 1991, Roath and Krueger, 1982 and Senft et al., 1985). As such, additional research was required to investigate the efficacy of fall prescribed fire for manipulating cattle resource-selection patterns under different site conditions and grazing regimes (e.g., mid-summer [July] grazing) than those used by Clark et al. (2014).

Objectives of this study were to: i) Evaluate whether fall prescribed fire affected cattle resource-selection patterns under a mid-summer (July) grazing regime; ii) if fire effects on cattle resource selection were detected, determine how long these effects persisted postfire; and iii) compare and contrast findings with those obtained by Clark et al. (2014). This study was conducted within the scope of a larger research project intended to evaluate spatiotemporal effects of prescribed fire on resource selection, activity budgets, and movement path characteristics of beef cattle in mesic sagebrush-steppe rangelands. A series of 3 papers was the intended product from this project with Clark et al. (2014) being the first paper in the series, the present paper on mid-summer resource selection as the second, and a third paper on cattle activity budget and movement path responses to prescribed fire is in preparation.

2. Methods

2.1. Study area

The study was conducted at the Breaks study area (176 ha), a fenced rangeland pasture within the Reynolds Creek Experimental Watershed (43° 6′ 29″ N, 116° 46′ 37″ W) located 80 km south of Boise in southwestern Idaho (Fig. 1). Climate is continental with maritime influences. Winters are cold and wet while summers are warm and dry. Long-term (1966–1975, 2002–2013) mean annual precipitation at the Breaks gauges (145) was 588 mm (NWRC, 2014) with typically about 1/3 of the precipitation occurring as snow (Hanson, 2001). Annual precipitation during the study (2001–2007) varied from a low of 421 mm in 2002, 463 mm in 2007, 542 mm in 2003, 543 mm in 2004, 655 mm in 2006, and a high of 773 mm in 2005. Precipitation data from the Breaks gauges was not available for 2001, but data from the nearby Tollgate gauges (116c) indicated precipitation in 2001 was below the long-term mean (1962–2013) for Tollgate (NWRC, 2014). The growing season is about 100 days in length but frost can occur during any month of the year. Long-term (1967–2010) mean daily maximum, minimum and mean air temperatures at the nearby Lower Sheep Creek weather station (127 × 07) were 12.7, 3.8, and 8.3 °C, respectively (Hanson et al., 2001 and NWRC, 2014). Mean daily air temperature varied during the study from a low of 8.3 °C in 2002, 8.6 °C in 2005, 8.7 °C in 2001, 8.8 °C in 2004 and 2006; 9.4 °C in 2003, and a high of 9.6 °C in 2007. Note that mean annual air temperatures for all study years, except 2002, were warmer than long-term mean.

Fig. 1. 

A map (left) illustrating the dominant prefire vegetation (6 types) which occurred at the Breaks prescribed fire study area (176 ha) in the Owyhee Mountains of southwestern Idaho. This map (left) also includes an overlay of elevation contours (5-m intervals) illustrating study area topography. A second map (right) displaying Normalized Difference Vegetation Index (NDVI) or vegetation greenness values throughout the study area. The map on the right also illustrates the distribution of fire severity (4 classes) which occurred as a result of the Breaks prescribed fire (34 ha) on 24 September 2002.

Figure options

Topography of the study area is an east-facing hillslope ranging from 1547 to 1761 m in elevation. Slope ranges from flat to very steep (107.5% or 47.1° maximum) with aspects in all four cardinal directions well represented. Soils are primarily derived from granitic parent materials and composed of a complex of Takeuchi (coarse, loamy, mixed, frigid Typic Haploxerolls) and Kanlee (fine, loamy, mixed, frigid Typic Argixerolls) soil series (Seyfried et al., 2001).

Three vegetation cover types; including mountain big sagebrush – mountain snowberry, antelope bitterbrush – mountain big sagebrush, and native bunchgrass types, dominate the study area as they do in the mid- and higher-elevation portions of the sagebrush steppe throughout much of the Intermountain West (Fig. 1). Besides the 2 dominant species, the mountain big sagebrush-mountain snowberry type includes western juniper, yellow rabbitbrush (Chrysothamnus viscidiflorus [Hook.] Nutt.), Saskatoon serviceberry (Amelanchier alnifolia [Nutt.] Nutt. ex M. Roem. alnifolia), bluebunch wheatgrass (Pseudoroegneria spicata   [Pursh] A. L$\ddot{\text{o}}$ ve), Sandberg bluegrass (Poa secunda J. Presl.), squirreltail (Elymus elymoides [Raf.] Swezey), Idaho fescue (Festuca idahoensis Elmer), basin wildrye (Leymus cinereus [Scribn. & Merr.] A. Love), mountain brome (Bromus marginatus Nees ex Steud.), tapertip hawksbeard (Crepis acuminata Nutt.) and western aster (Symphyotrichum ascendens [Lindl.] Nesom). Other components of the antelope bitterbrush-mountain big sagebrush type include western juniper, native bunchgrasses, and biscuitroots (Lomatium spp. Raf.). When contrasted, the mountain big sagebrush-mountain snowberry type generally had the more herbaceous cover, both in the interspaces and under the shrub canopy than the antelope bitterbrush-mountain big sagebrush type (Clark unpublished data). Bluebunch wheatgrass, Sandberg bluegrass, squirreltail, Idaho fescue, and needlegrasses (Achnatherum spp. Beauv.) dominate the native bunchgrass cover type. Cheatgrass has a minor to common presence in all three of these dominant vegetation types.

Cattle had access to two perennial streams, Reynolds Creek and Dobson Creek, while in the study area. The riparian zones of both streams were dominated by a black cottonwood (Populus balsamifera L. ssp. trichocarpa [Torr. & A. Gray ex Hook.] Brayshaw) overstory, a peachleaf willow (Salix amygdaloides Andersson), redosier dogwood (Cornus sericea L. ssp. sericea), and rose (Rosa woodsii Lindl.) shrub layer, and a sedge (Carex spp.) and Kentucky bluegrass (Poa pratensis L.) understory. Small, dry meadows typically less than 0.25 ha in size and dominated by Kentucky bluegrass and rushes (Junus spp.) where located on the stream terrace and in upland swales. Willow (Salix spp.), quaking aspen (Populus tremuloides Michx.), and black cottonwood occurred as occasional, small clumps or groves (0.001–1 ha) near upland surface-water sources and in other upland areas where the water table was shallow. Occasional, small groves (1–2 ha) of Douglas-fir trees (Pseudotsuga menziesii [Mirb.] Franco) occurred in the southern end of the study area where the elevation was highest.