Shallow to Loamy, Calcareous 15-19 Inch Precipitation Zone Lost River Mountains

Description

The reference state consists of three dominant plant communities: The black sagebrush (Artemisia nova) dominated community, the the mixed early sagebrush (Artemisia arbuscula ssp. Longiloba) and black sagebrush dominated community, and a community where overstory shrub canopy dominance is usurped by bunchgrasses. The greatest difference between the three plant communities is composition and foliar cover of sagebrush (Artemisia) species, and may include mountain big sagebrush (Artemisia tridentata ssp. Vasayana). Mountain big sagebrush foliar cover increases on sites that are closer to the high end of the effective precipitation range (15 to 19 inches) and the calcium carbonate equivalency in the soil is lower, closer to minimum 15 percent concentrations outlined in the site concept.
Processes (both natural and anthropogenic) that result in state and community changes include fire, grazing, land use change, and occurrence of invasive species (Davies et al., 2011).

Characteristics and indicators

The shift between plant communities at this ecological site is generally driven by calcium carbonate concentration in soils, effective precipitation, and sagebrush killing disturbances or lack thereof. Historically, low to mixed severity fires occurred at relatively frequent fire return intervals of 10 to 25 years, limiting sagebrush canopy density and creating a mosaic of sagebrush stands and more open grasslands (Knick, Holmes, & Miller, 2005). Exclusion of fire (in conjunction with climate change) increases sagebrush canopy cover and can lead to more severe stand replacing fires, often times at more frequent intervals. These severe fires can drive shifts to grassland communities as well as create opportunities for invasive species establishment (Roadhouse, Irvine, & Bowerstock, 2020; Knick et al., 2005).

Improper grazing practices can also lead to an increase in sagebrush canopy cover and increased risk of severe, stand replacing fire occurrence. Removal of understory grasses can lessen the opportunities for low severity fires which leads to increased canopy densities and increases potential for severe fire disturbance events (Knick et al., 2005).

Resilience management

This site has moderate to high resilience as a result of the cryic soil temperature regime and xeric soil moisture regime. Resistance and resilience of a specific site has been attributed with abiotic conditions favorable to plant growth and reproduction (Maestas et al. 2016). Soils that fall within the cryic (cold) temperature regime and xeric (wet) moisture regime tend to have higher diversity and production, and are therefore more resilient, specifically in terms of resisting or recovering from invasion post disturbance (Maestas et al., 2016).

On the LRU scale, this site may also have increased resistance to invasion of annual grasses due to the calcium carbonate concentration found in the 10 to 25 centimeter range of the soil profile. Calcareous soils have shown to provide a deterrent to establishment of invasive grasses such as Bromus tectorum (Miller et al., 2006).

Submodel

Description

When a Shallow to Loamy, Calcareous ecological site enters the Grazing Resistant state, the primary shift occurs in the understory vegetation. Grazing pressure from livestock, native ungulates, or a combination of the two drives a shift from the cool-season bunch grasses present in the Reference State towards rhizomatous wheatgrasses, short-stature bunch grasses, and ground covering forbs. This state is generally a result of current or historic improper grazing practices that potentially included higher socking rates and repeated heavy grazing during the growing season.

Characteristics and indicators

In this state, total canopy cover and production values for mid to large sized bunchgrasses such as bluebunch wheatgrass will decrease. These understory grasses will be relegated to the protected areas under the sagebrush canopies where they are sheltered from grazing. As they are removed from the canopy gaps, they will be replaced with grazing resistant short-stature bunch grasses like Sandberg bluegrass (Poa secunda) and rhizomatous wheatgrasses such as thick spike wheatgrass (Elymus lanceolatus), Western wheatgrass (Pascopyrum smithii), and at the higher end of the precipitation range, slender wheatgrass (Elymus trachycaulus). Openings in the canopy gaps vacated by bunchgrasses also present opportunities for an increase in disturbance tolerant forbs such as Hood's phlox (Phlox hoodii), cushion phlox (Phlox pulvinata), vetch species (Vetch sp.) and Indian paintbrush species (Castilleja sp.). Opportunities for invasive annual grasses also increase as competition from native grasses is removed from the canopy gaps.
Depending on how well grazing resistant rhizomatous and bunchgrasses occupy the canopy gaps, an increase in bare ground cover usually occurs. This can lead to increased erosion and decreased infiltration, decreasing available moisture. Because of this, productivity and canopy cover will be lower than at the Reference State.

Resilience management

Resilience in this state is lower than in the Reference State, primarily due to the decrease in available moisture and the opportunity for invasive species recruitment. Ability to recover from disturbance in rangeland systems has shown to be related to local climatic conditions. As available moisture increases and temperature decreases, resilience to disturbance increases (Chambers, et al. 1014). At this ecological site, resilience of the black and little sagebrush dominated sites would tend to be lower than at the sites with mountain big sagebrush in the overstory canopy as this would indicate higher available moisture and lower average annual temperature.
Resilience to erosion and invasive species establishment would be dependent on how well rhizomatous grasses and forbs occupy the bare ground spaces left by the removal of bunchgrasses. Rhizomatous grasses are mat forming and if able to establish relatively quickly can aid in reducing erosion. Additionally, if native rhizomatous grasses and forbs are able to quickly establish, this decreases the ability of invasive annual grasses such as cheatgrass to occupy bare soil openings within the site.

Submodel

Description

The Disturbed state is a result of both natural and anthropogenic disturbance events that result in widespread sagebrush mortality. The primary natural disturbance resulting in sagebrush mortality at this ecological site is frequent or severe wildfire. Flooding, intense freeze events, and insect and disease can also occur. Because this LRU exists primarily on publicly managed lands (US Forest Service, Bureau of Land Management, and State), widespread anthropogenic disturbance events are infrequent. Examples of anthropogenic disturbance events include brush management through sagebrush mowing or removal treatments, chemical treatments, or improper grazing techniques that result in high intensity hoof disturbance.
A combination of natural and anthropogenic disturbance is possible and can result in increased severity of disturbance, decreased resilience, and greater difficulty returning to the Reference State. For example, improper grazing practices that result in chronic defoliation following a fire disturbance event can increase bare ground cover, increase erosion potential, and slow the reestablishment of grass species that preclude the return of overstory sagebrush canopy (Zlatnik, 1999).

Characteristics and indicators

The primary indicator of the Disturbed State is near to complete loss of overstory sagebrush species (black sagebrush, little sagebrush, and mountain big sagebrush). A shift towards an increase in native and non-native disturbance tolerant grasses and forbs is likely with removal of resource competition associated with sagebrush overstory. Additionally, canopy cover of disturbance tolerant shrubs such as yellow rabbitbrush (Chrysothamnus viscidiflorus) and rubber rabbitbrush (Ericameria nauseosa) may increase. Severe disturbance events also increase the opportunity for invasion of annual grasses and weeds such as cheatgrass (Bromus tectorum) and thistle species. Percent canopy cover of invasive species is dependent on distance of a seed source post disturbance. Initial cover of invasive species stays below 5 percent (Zlatnik, 1999).

Resilience management

Resilience in this state is moderate. Many of the post-disturbance grasses and shrubs that are common in this state establish quickly and reach a representative canopy within 10 years post-disturbance, and continue to increase until overstory canopy of sagebrush begins to return. However, local resilience in this state is highly dependent on current soil moisture availability, seed sources, timing and severity of the disturbance. In the instance of fire disturbance, bluebunch wheatgrass mortality can be significantly lower if the fire occurs in the spring as opposed to fall, and recovery can be impacted by quantity of immediate post-fire precipitation (Zlatnik, 1999).
More severe disturbances increase possibility of post-disturbance invasion. The greater the establishment of invasives, the lower the site resilience becomes.

Submodel