Physiographic features

This site typically occurs on ridges, knobs, summits, escarpments, and paleoterraces; it is commonly associated with areas of badlands. Typical parent materials are channery residuum weathered from porcelanite, loamy alluvium over limestone gravelly alluvium, gravelly alluvium (on paleoterraces), or soft, weathered sedimentary bedrock (typically siltstone or mudstone). Slopes range from 2 to 70 percent.

Table 2. Representative physiographic features

Climatic features

MLRA 58C is considered to have a continental climate with cold winters and hot summers, low humidity, light rainfall, and much sunshine. Extremes in temperature are common and characteristic of the MLRA. The continental climate is the result of the location of this MLRA in the geographic center of North America. There are few natural barriers on the northern Great Plains, so air masses move unobstructed across the plains and account for rapid changes in temperature.

Annual precipitation ranges from 14 to 17 inches per year. The normal average annual temperature is about 41° F. January is the coldest month with an average temperature of about 17° F. July is the warmest month with an average temperature of about 70° F. The range of normal average monthly temperatures between the coldest and warmest months is 53° F. This large temperature range attests to the continental nature of the MLRA 58C climate. Wind speeds average about 11 miles per hour, ranging from about 13 miles per hour during the spring to about 10 miles per hour during the summer. Daytime wind speeds are generally stronger than nighttime wind speeds, and occasional strong storms may bring brief periods of high winds with gusts to more than 50 miles per hour.

Growth of native cool-season plants begins in late March and continues to early to mid-July. Native warm- season plants begin growth in mid-May and continue to the end of August. Greening up of cool-season plants can occur in September and October when adequate soil moisture is present.

Table 3. Representative climatic features

Climate stations used

• (1) MEDORA 7 E [USW00094080], Fairfield, ND

• (2) WATFORD CITY 14S [USC00329246], Grassy Butte, ND

• (3) TROTTERS 3 SSE [USC00328812], Beach, ND

• (4) CARLYLE 13 NW [USC00241518], Wibaux, MT

• (5) AMIDON [USC00320209], Amidon, ND

Influencing water features

This site does not receive additional water as runoff from adjacent slopes; it is on a run-off landscape position. Neither does it receive additional water from a seasonal high-water table. Depth to the water table is deeper than 6 feet throughout the growing season. Surface infiltration and permeability below the surface layer are moderately rapid to very rapid. Water loss is through percolation below the root zone and evapotranspiration.

Soil features

Soils associated with Very Shallow ES are in the Entisol and Mollisol orders. The Entisols are classified further as Aridic Ustorthents. The Mollisols are classified further as Torriorthentic Haplustolls and Aridic Haplustolls. These soils were developed under prairie vegetation. Typically, they formed in residuum from porcelanite (scoria), sandy and gravelly alluvium, or loamy alluvium or limestone gravelly alluvium. Some areas of weathered soft, sedimentary bedrock (mudstone, siltstone, sandstone, or shale) may also occur.

The common feature of soils in this site is the very shallow depth to layers which affect root growth: porcelanite (e.g., locally known as scoria) within a depth of 20 inches; layers high in coarse sand and gravel (15 to 60 percent gravel) within a depth of 14 inches; very gravelly loam or very cobbly loam (limestone fragments) within a depth of 10 inches; or weathered, soft, sedimentary bedrock within a depth of 10 inches. These layers also impact the available water capacity, making the soils very droughty and limiting plant production. The soils are excessively drained or well drained. The surface layer is typically loam, channery loam, gravelly loam, or gravelly sandy loam; however coarser textures are allowed. Thickness of the surface layer is 7 inches or less; in some soils, a non-calcareous subsoil (Bw) occurs above the fragmented layers. Soils formed in weathered soft residuum are less than 10 inches to sedimentary bedrock; surface texture on these soils is commonly loam, silt loam, or silty clay loam.

Salinity and sodicity are none or very slight (E.C. <2 dS/m; SAR <2). Soil reaction is slightly acid to moderately alkaline (pH 6.1 to 8.4). Calcium carbonate content is none too low in the surface layer (CaCO3 <5%); it may increase to as much as 20% in the subsoil.

The soil surface on sandy and gravelly soils may be unstable but is usually intact. Porcelanite or other fractured bedrock layers affect root penetration. These soils are mainly susceptible to water erosion. The hazard of water erosion increases on slopes greater than about 15 percent. Very low available water capacity caused by the shallow rooting depth strongly influences the soil/water/pant relationship. Loss of the soil surface layer can result in a shift in species composition and/or production.

Major soil series correlated to the Very Shallow site are Kirby, Shibah, and Tinsley. In addition, a taxadjunct to Ringling (established for ustic moisture regime) is included.

Access Web Soil Survey (https://websoilsurvey.sc.egov.usda.gov/App/WebSoilSurvey.aspx) for specific local soils information.

Table 4. Representative soil features

Animal community

Wildlife Interpretations

Landscape:

The MLRA 58C landscape is characterized by moderately dissected rolling plains with areas of local Badlands, buttes, and isolated hills. MLRA 58C is considered to have a continental climate with cold winters and hot summers, low humidity, light rainfall, and much sunshine. Extremes in temperature are common and characteristic of the MLRA. This area supports natural mixed-grass prairie vegetation with prairie rose, leadplant, and patches of western snowberry interspersed throughout the area. Green ash, chokecherry, and buffaloberry occur in draws and narrow valleys, creating woody riparian corridors. Complex/intermingled ecological sites create diverse grass- and shrubland habitats interspersed with varying densities linear, slope, depressional, and in-stream wetlands associated with headwater streams and tributaries to the Missouri River. These habitats provide critical life-cycle components for many wildlife species.

Historic Communities/Conditions within MLRA 58C:

The northern mixed-grass prairie was a disturbance-driven ecosystem with fire, herbivory, and climate functioning as the primary ecological drivers (either singly or often in combination). Many species of grassland birds, small mammals, insects, reptiles, amphibians, and large herds of Audubon bighorn sheep, roaming bison, elk, and pronghorn were historically among the inhabitants adapted to this semi-arid region. Bighorn sheep have been re-introduced. Roaming herbivores, as well as several small mammal and insect species, were the primary consumers linking the grassland resources to large predators (such as the wolf, mountain lion, and grizzly bear) and smaller carnivores (such as the coyote, bobcat, red fox, and raptors). The black-tailed prairie dog was once abundant and provided ecological services by manipulating the plant and soil community providing habitat for the black-footed ferret, burrowing owl, ferruginous hawk, mountain plover, swift fox, small mammals, and amphibians and reptiles. Extirpated species include free-ranging American bison, Canada lynx, common raven, grizzly bear, gray wolf, black-footed ferret, mountain plover, and peregrine falcon (breeding). Extinct from the region is the Rocky Mountain locust.

Present Communities/Conditions within MLRA 58C:

Following European influence, domestic livestock grazing, elimination of fire, energy development, and other anthropogenic factors influenced plant community composition and abundance. Transportation corridors, energy development, and Rocky Mountain juniper and ponderosa pine encroachment are the main factors contributing to habitat fragmentation, reducing habitat quality for area-sensitive species. These influences fragmented the landscape, reduced or eliminated ecological drivers (fire), and introduced exotic plant species including smooth brome, crested wheatgrass, Kentucky bluegrass, and leafy spurge further impacting plant and animal communities. The loss of the bison, reduction of black-tailed prairie dogs, and fire, as primary ecological drivers, greatly influenced the character of the remaining native plant communities and the associated wildlife moving towards a less diverse and more homogeneous landscape, lacking diverse species composition and stature.

Extensive fragmentation by annual cropping has not occurred within the MLRA. Limited fragmentation from annual cropping or tame hay production has occurred within the Little Missouri River flood plain and the higher, flat plateaus. Fragmentation east and west of MLRA 58C has funneled many species into this area in search of expansive grasslands.

Some wildlife species in this area are: mule deer, white-tailed deer, elk, bighorn sheep, pronghorn, mountain lion, coyote, red fox, bobcat, prairie rattlesnake, American badger, raccoon, North American porcupine, beaver, striped skunk, American mink, white-tailed jackrabbit, black-tailed prairie dog, Eastern and Merriam’s wild turkey, golden eagle, ferruginous hawks, sharp-tailed grouse, greater sage-grouse, black-billed magpie, and numerous species of grassland-nesting birds and pollinating insects. The highest diversity of bats in North Dakota also occurs in this MLRA, where eleven species have been documented.

Presence of wildlife species is often determined by ecological site characteristics including grass and forb species, hydrology, aspect, and other associated ecological sites. Home ranges for most species are larger than one ecological site or are dependent on more than one ecological site for annual life requisites. Ecological sites offer different habitat elements as the annual life requisites change. Habitat improvement and creation must be conducted within the mobility limits of a known population for the species.

Insects play an important role providing ecological services for plant community development. Insects that are scavengers or aid in decomposition provide the food chain baseline sustaining the carnivorous insects feeding upon them. Many insects provide the ecological services necessary for pollination, keeping plant communities healthy and productive. Insects provide a protein food source for numerous species including grassland nesting birds and their young.

Species unique to the MLRA:

Mountain Lions: Mountain lions were relatively common in the Badlands but disappeared from the state by the early 20th Century. Sightings resumed in the 1950’s and have subsequently increased since that time. The species has recently taken up permanent residency within the region. Mountain lions occur in of the Little Missouri Badlands and woody habitat in MLRA 58C. Rugged terrain and forest provide excellent stalking cover to hunt large mammals and other prey. Mountain lions make use of caves for escape and loafing cover.

Bighorn sheep: Bighorn sheep make use of the rugged terrain, rocky outcrops, and high plateaus of MLRA 58C along the Little Missouri River. North Dakota bighorn sheep populations are almost exclusively within MLRA 58C. Bighorn sheep were once extirpated from North Dakota but were successfully reintroduced in the mid-twentieth century. They now occur in several distinct populations within MLRA 58C. Rocky Mountain juniper encroachment degrades the limited habitat for bighorn sheep. Managers should consider bighorn sheep association with domestic sheep, since transfer of pneumonia and other diseases is known to occur.

Golden eagle: The badlands within MLRA 58C are key areas for Golden eagle nesting. Adjacent grasslands, shrublands, and black-tailed prairie dog towns are used for hunting.

Bats: MLRA 58C provides life requisites for several bat species, in part due to presence of riparian forest, wooded draws, caves, and rocky outcrops. Hibernacula of six bat species have been found in MRLA 58C; however, additional work is needed to further understand utilization of hibernacula by bats during the winter months in North Dakota.

Short-horned lizard and sagebrush lizard: This MLRA provides preferred habitat for these two species. The short-horned lizard prefers semi-arid, shortgrass prairie in rough terrain, and is uncommon to locally abundant in MLRA 58C. The rare sagebrush lizard prefers sagebrush and rocky areas provided by this MLRA and adjacent MLRA 58D.

Greater sage-grouse and Brewer’s sparrow: The extreme southwest extension of MLRA 58C have ecological sites capable of producing sufficient big sage canopy cover to provide greater sage-grouse life requisites. MLRA 58C and 58D are the only MLRAs in North Dakota that support Wyoming big sage brush (big sage) production. Research data indicates greater sage-grouse prefer big sagebrush canopy cover for nesting at ≥8% with an average height of around 16 inches. The species prefers winter cover canopy that averages 15% with an average height of around 8 inches. Soil site potential, management, climate, and other factors all play a role in the amount, if any, of big sagebrush on an ecological site. Changes in big sage canopy cover occur slowly (30-50 years) unless the site is impacted by fire or cultivation. Big sage recovery after a burn can take 30 to 100 years. Greater sage- grouse and Brewer’s sparrow habitat and populations are reduced or eliminated when big sagebrush canopy is reduced to less than 8% for greater sage-grouse and 10% cover for Brewer’s sparrow. As conifer encroachment increases, greater sage-grouse lekking activity decreases. Once conifer encroachment exceeds 4% canopy cover, no leks remain.

Species of Concern within the MLRA:

Following is a list of species considered “species of conservation priority” in the North Dakota State Wildlife Action Plan (2015); “species of greatest conservation need” in the Montana State Wildlife Action Plan (2015); and species listed as “threatened, endangered, or petitioned” under the Endangered Species Act within MLRA 58C at the time this section was developed:

Invertebrates: Dakota skipper, monarch butterfly, regal fritillary, yellow-banded bumble bee, and western bumble bee.

Birds: American kestrel, Baird’s sparrow, bald eagle, black-billed cuckoo, bobolink, Brewer’s sparrow, burrowing owl, chestnut-collared longspur, common poorwill, eastern screech-owl ferruginous hawk, golden eagle, grasshopper sparrow, greater sage-grouse, lark bunting, loggerhead shrike, long-billed curlew, marbled godwit, McCown’s longspur, mountain plover, northern harrier, northern pintail, peregrine falcon (migration), prairie falcon, red knot (migration), red-headed woodpecker, sharp-tailed grouse, short-eared owl, Sprague’s pipit, Swainson’s hawk, upland sandpiper, western meadowlark, Wilson’s phalarope, whooping crane (migration), and willet.

Mammals: Big brown bat, black-footed ferret, black-tailed prairie dog, dwarf shrew, gray wolf, hispid pocket mouse, little brown bat, long-eared bat, long-legged bat, meadow jumping mouse, Merriam’s shrew, northern long-eared bat, porcupine, sagebrush vole, swift fox, Townsend’s big- eared bat, and western small-footed bat.

Amphibians and Reptiles: Common snapping turtle, Great Plains toad, greater short-horned lizard, milk snake, northern leopard frog, plains hognose snake, plains spadefoot, sagebrush lizard, smooth softshell, smooth green snake, and spiny softshell.

Fish and Mussels: Blue sucker, burbot, Flathead chub, northern redbelly dace, sickle-fin chub, pearl dace, shortnose gar, sturgeon chub, and sauger.

Grassland Management for Wildlife in the MLRA

Management activities within the community phase pathways impact wildlife. Community phase, transitional, and restoration pathways are keys to long-term management within each State and between States. Significant inputs must occur to cross the threshold between States (e.g., State 3.0 to 2.0) requiring substantial economic inputs and management (mechanical, reseeding, prescribed fire, woody vegetation removal, grazing intensity, etc.). Timing, intensity, and frequency of these inputs can have dramatic positive or negative effects on local wildlife species. Ranchers and other land managers must always consider the long-term beneficial effects of management on the habitat in comparison to potential short-term negative effects to individuals.

Ecological sites occur as intermingled complexes on the landscape with gradual or sometimes abrupt transitions. Rarely do ecological sites exist in large enough acreage to manage independently. Ecological sites, supporting a dominance of herbaceous vegetation (Loamy/Limy Residual), can be located adjacent to ecological sites that support medium to tall shrubs (Loamy Overflow). Conversely, ecological sites that are dominated by short to mid statured grasses (Claypan) can be adjacent to sites with bare soil only supporting minor amounts of short grasses and forbs (Thin Claypan).

Management of these complex ecological sites can provide a heterogeneous or a homogenous landscape. Grassland bird use declines as the plant community transitions to a homogenous state. Managers need to recognize ecological sites and the complexes they occur in to properly manage the landscape. A management regime for one ecological site may negatively impact an adjacent site (e.g., alteration of a grazing regime within a Flat Bottom Wooded Draw ecological site to encourage understory growth may encourage exotic, cool-season grasses to increase or dominate an adjacent ecological site).

Life requisites and habitat deficiencies are determined for targeted species. Deficiencies need to be addressed along community phase, transitional, and restoration pathways as presented in specific state and transition models. Ecological sites should be managed and restored within the capabilities of the site to provide sustainable habitat. Managers also need to consider habitat provided by adjacent/intermingled ecological sites for species with home ranges or life requisites that cannot be provided by one ecological site.

With populations of many grassland-nesting birds in decline, it is important to maintain these ecological sites in a 1.0 Reference State or the 2.0 Native/Invaded. Plant communities, optimal for a guild of grassland species, serve as a population source where the birth rate exceeds mortality. Species may use marginal plant communities; however, these sites may function as a population sink where mortality exceeds the birth rate.

Understanding preferred vegetative stature and sensitivity to woody encroachment is necessary to manage for the specific grassland species. Various grass heights may be used for breeding, nesting, foraging, or winter habitat. While most species use varying heights, many have a preferred vegetative stature height. Please reference the provisional ESD on the North Dakota eFOTG (linked below) for a chart that provides preferred vegetative stature heights and sensitivity to woody vegetation encroachment.
https://efotg.sc.egov.usda.gov/references/public/ND/58C_Very_Shallow_Narrative_Final_Ref_FSG.pdf

Very Shallow Wildlife Habitat Interpretation:

Very Shallow ecological sites support a wide variety of vegetative communities dependent upon the presence and density of conifers. The community phases can support grassland nesting birds ranging from mid- to short-statured herbaceous vegetation to woodland bird species. This ecological site can also support the unique ponderosa pine forest. In a similar fashion, mammal species can be diverse dependent on community phases. Very Shallow ecological sites are associated with Badland, Badland Fan, Limy Residual, Loamy, Sandy, Shallow Loamy, Steep-sided Wooded Draw and Thin Claypan ecological sites providing a mosaic of grassland and forest habitats.

1.0 Reference State

Community Phase 1.1 Little Bluestem-Needlegrasses/Sedges/Bare Ground:
This plant community offers quality wildlife habitat; every effort should be made to maintain this ecological site within this community phase. This phase retains high functionality through continued maintenance, including prescribed grazing with adequate recovery period as well as prescribed fire. Predominance of grass species in this community favors grazers and mixed-feeders (animals selecting grasses as well as forbs and shrubs).
The structural diversity provides habitat for a wide array of migratory and resident birds.

Invertebrates: Insects play a role in maintaining the forb community and provide a forage base for grassland birds, reptiles, and rodents. Ecological services, historically provided by bison, are simulated by domestic livestock. These services include putting plant material and dung in contact with mineral soil to be used by low trophic level consumers (such as invertebrate decomposers, scavengers, shredders, predators, herbivores, dung beetles, and fungal-feeders).

Dakota skippers may use this site due to presence of host plants, such as little bluestem, and nectar sources such as black samson echinacea (Echinacea angustifolia). Regal fritillary habitat is limited since prairie violets typically do not occupy the site. Monarch butterfly may use flowering forbs on this site; however, few milkweed species are found on this site to support breeding. Bumblebees and other native bees utilize forbs as a nectar source and bare ground for nesting sites in bunchgrasses. Prescribed grazing with adequate recovery periods (as well as prescribed fire) to maintain the 1.1 phase has little effect on nests of ground-dwelling insects.

Birds: This plant community provides quality nesting, foraging, and escape habitats favored by short- to midgrass-nesting birds. The low, scattered shrubs present in the plant community phase should not impact woody vegetation-sensitive bird species. Grassland birds that prefer mid-grass stature will use this site. In years with reduced precipitation or drought, nesting recruitment may be compromised. This plant community provides suitable areas for sharp-tailed grouse nesting and brood-rearing habitat; however, depending on slope steepness, use could be limited. Limited stature and diverse prey populations provide good hunting opportunities for grassland raptors.

Mammals: The diversity of grasses and forbs provide high nutrition levels for small and large herbivores including voles, mice, rodents, jackrabbits, pronghorn, elk, and deer (white-tailed and mule). Short- to moderate-statured provides suitable food and thermal, protective, and escape cover for small herbivores such as the hispid pocket mouse.

Amphibians and Reptiles: This ecological site and associated plant communities provides habitat for smooth green snakes. This ecological site provides limited habitat for the northern leopard frog and Great Plains toad due to its location on hilltops and ridges. The site supports limited amounts of sliver sagebrush. The site does contain rocky and/or sandy soils; both the sagebrush lizard and short-horned lizard may use this ecological site. This ecological site provides limited habitat for the plains hog-nosed snake (prefer sandy soils) and plains spadefoot (prefer gravelly or sandy soils).

Fish and Mussels: This ecological site is not directly associated with streams, rivers, or water bodies. Associated ecological sites, such as Loamy Overflow, can receive run-on hydrology from Very Shallow sites. Management on these interconnected sites will have limited, secondary effects on aquatic species.

Community Phase 1.2 Sedges/Forbs/Bare Ground: Long-term drought, with or without heavy grazing, and long-term grazing will switch this plant community from mid-structure bunchgrasses to short-statured sedges, bare ground, and forbs.

Invertebrates: Long-term, heavy grazing may negatively impact ground-nesting sites for bumble bees, other native bees, and other ground-nesting insects due to timing of forb flowering or increased soil compaction.

Birds: This plant community provides nesting, foraging, and escape habitats favored by shortgrass-nesting birds. A shift to shorter plant stature along Community Phase Pathway 1.1A benefits McCown’s longspur, chestnut-collared longspur, and horned lark. Species that prefer midgrass stature will be generally successful with normal to above normal precipitation and a change in management along the 1.2A Community Phase Pathway. In years with reduced precipitation or heavy grazing, nesting recruitment may be compromised for midgrass-nesting species. Short-statured cover limits hunting opportunities for grassland raptors.

Mammals: The transition to short-statured vegetation reduces suitable food, thermal, protective, and escape cover for small and large herbivores.

Amphibians and Reptiles: Provides similar life requisites as Community Phase 1.1.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

Community Phase 1.3 Little Bluestem-Needlegrasses/Sedges/Creeping Juniper:
A decrease in fire frequency along with the recruitment of conifers (i.e., creeping juniper) creates a mosaic of grasses and creeping juniper. Areas dominated by creeping juniper may have scattered grasses growing with creeping juniper clumps. This plant community can occur in a mosaic with Community Phase 1.1, creating a patchwork landscape.

Invertebrates: Dependent upon the density of creeping juniper this plant community provides similar life requisites as Community Phase 1.1. However, the increase in creeping juniper reduces little bluestem host plant for Dakota skipper and nectar sources for pollinator species.

Birds: Dependent upon the density of creeping juniper this plant community provides similar life requisites as Community Phase 1.1. As the density of creping juniper increases, habitat for all grassland nesting bird decreases.

Mammals: Dependent upon the density of creeping juniper this plant community provides similar life requisites as Community Phase 1.1. As the density of creeping juniper increases, habitat for all mammals decreases.

Amphibians/Reptiles: Creeping juniper reduces open space between grass and forbs species needed in most amphibians and reptile species.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

Community Phase 1.4 Juniper and/or Ponderosa Pine (~5 canopy cover)/Little Bluestem- Needlegrasses/Sedges:
A decrease in fire frequency along with the recruitment of conifers (e.g., ponderosa pine, Rocky Mountain juniper, common juniper, creeping juniper) creates a mosaic of grasses and conifers. This plant community can occur in a mosaic with Community Phase 1.1, creating a patchwork landscape.

Invertebrates: The introduction of wind-pollinated conifer species reduces the overall plant diversity and nectar and pollen availability for pollinators.

Birds: The introduction of conifer trees will negatively impact grassland nesting birds that do not tolerate woody vegetation. The density of trees will not be sufficient to provide habitat for forest species. This plant community phase will be attractive to habitat generalist bird species. The presence of woody plant species may increase predation by mammals and avian predators and brood parasitism by brown-headed cowbirds.

Mammals: Density of the conifer tree canopy will determine thermal, shelter, and escape cover for small and large herbivores. Increase in trees favors white-tailed deer while reducing habitat for pronghorn.

Amphibians and Reptiles: Increase in conifer tree canopy may negatively impact amphibians and reptiles, dependent upon the density of the tree canopy. Amphibians and reptiles in MLRA 58C are dependent on full sunshine. An increase in shade will negatively impact their habitats.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

2.0 Native Invaded State

Community Phase 2.1 Little Bluestem-Needlegrasses/Sedges/Bare Ground:
This plant community develops through Transition Pathway T1A due to changes in management and the presence of exotic, cool-season grasses. The threshold between States 1.0 and 2.0 is crossed when Kentucky bluegrass, crested wheatgrass, smooth brome, annual bromes, or other exotic species become established. This plant community phase has a very similar appearance and function to the Reference State of Community 1.1, except it has a minor amount of cool-season exotic grasses and forbs. This phase functions at a high level for native wildlife; therefore, managers should consider the 2.0 community phase pathways to avoid transitioning to State 3.0. Shrub species tend to be short-statured.

Invertebrates: Provides similar life requisites as Community Phase 1.1.

Birds: Provides similar life requisites as Community Phase 1.1.

Mammals: Provides similar life requisites as Community Phase 1.1.

Amphibians and Reptiles: Provides similar life requisites as Community Phase 1.1.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

Community Phase 2.2 Sedges/Forbs/Bare Ground: Heavy season-long grazing, with or without drought, along Community Phase Pathway 2.1A leads to loss of little bluestem and increases in sedges, forbs, and bare ground, and shorter-statured grasses (such as blue grama) and sedges. Dominated by shorter- stature grasses, the diversity of this plant community is reduced. Prescribed grazing with adequate recovery periods along Community Phase Pathway 2.2A is an efficient, effective method to regain the cool-season grass and forb diversity components in Community Phase 2.1.

Invertebrates: The reduction in plant diversity and increase intensity of grazing reduces nectar and pollen limit foraging and nesting sites for all pollinators. Continuous, heavy season-long grazing or heavy seasonal grazing may reduce ground-nesting site availability.

Birds: Continuous, heavy season-long grazing or heavy seasonal grazing will reduce nesting sites, forage (invertebrates), and cover. A reduced forb component may limit foraging opportunities. The stature is generally short which favors short-grass nesting birds. Limited stature and diverse prey populations provide good hunting opportunities for grassland raptors.

Mammals: Suitable food, thermal, protective, and escape cover (reduction in litter) for most mammals become limited. The loss of diversity of grasses and forbs reduces nutrition levels for small and large herbivores including voles, mice, rodents, jackrabbits, pronghorn, and deer.

Amphibians and Reptiles: Provides similar life requisites as Community Phase 1.1.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

Community Phase 2.3 Little Bluestem-Needlegrasses/Sedges/Creeping Juniper:
This community phase results from long-term absence of fire and recruitment of conifers, mainly creeping juniper. The community phase is similar to 1.3, but with the invasion of exotic cool-season grasses.

Invertebrates: Provides similar life requisites as Community Phase 1.3.

Birds: Provides similar life requisites as Community Phase 1.3.

Mammals: Provides similar life requisites as Community Phase 1.3.

Amphibians/Reptiles: Provides similar life requisites as Community Phase 1.3.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

Community Phase 2.4 Juniper and/or Ponderosa Pine/Shrubs/Little Bluestem-Needlegrasses/Sedges:
This Community Phase results from long-term absence of fire and recruitment of conifers, mainly Rocky Mountain juniper and/or ponderosa pine. The community phase is similar to 1.4 but with the invasion of exotic cool-season grasses.

Invertebrates: Provides similar life requisites as Community Phase 1.4.

Birds: Provides similar life requisites as Community Phase 1.4.

Mammals: Provides similar life requisites as Community Phase 1.4.

Amphibians/Reptiles: Provides similar life requisites as Community Phase 1.4

Fish and Mussels: Provides similar life requisites as Community Phase 1.4.

3.0 Invaded State

Community Phase 3.1 Exotic Cool-Season Grasses/Forbs/Shrubs:
Community Phase Pathway T2A is characterized by non-use or low intensity (<20% utilization) grazing and elimination of fire when exotic cool-season grasses are present (as in Community Phase 2.0). This plant community phase is characterized by a dominance (>30%) of exotic cool-season grasses (such as Kentucky bluegrass, crested wheatgrass, annual bromes, and smooth brome). Restoration Pathway R3A requires remnant amounts of native warm-season grasses (e.g., little bluestem), cool-season grasses (e.g., needlegrasses), and native forbs.

Invertebrates: Exotic grasses result from non-use or low intensity (<20% utilization) grazing and limits use by beneficial insects provided in States 1.0 and 2.0. The lack of nectar-producing plants limits forage opportunities for bumblebees, regal fritillary, monarch butterfly, and other pollinating species.

Birds: The homogeneous community phase, dominated by exotic plant species, provides limited habitat and life requisites for most obligate grassland-nesting birds. Lack of plant diversity and stature, limits use by many grassland-nesting birds. Short-statured cover limits hunting opportunities for grassland raptors.

Mammals: The transition to short-statured vegetation reduces suitable food, thermal, protective, and escape cover for small and large herbivores.

Amphibians and Reptiles: Provides similar life requisites as Community Phase 1.1.

Fish and Mussels: Provides similar life requisites as Community Phase 1.1.

4.0 Conifer Invaded State

Plant Community Phase 4.1 Juniper and/or Ponderosa Pine: Resulting from Transitional Pathway T2B, elimination of fire is the major contributor to this state crossing the threshold from an herbaceous plant community to a community completely dominated by Rocky Mountain juniper and/or ponderosa pine. Shallow Loamy sites did not historically support a Rocky Mountain juniper and/or ponderosa pine plant community. This state is dependent upon seed dispersal by birds and mammals from nearby sites. Dense conifers lead to changes in soil chemistry and a change in the associated herbaceous plant community. A detritus layer of pine needles and juniper needles-leaves, shade, shallow root system, and interception of precipitation with a possible soil chemistry change (decrease in pH) reduces or eliminates an herbaceous or forb understory.

Invertebrates: Conifers are wind-pollinated and thus do not benefit pollinating insects. The loss of a forb component limits insect populations.

Birds: Juniper and pine occur along a continuum. Light infiltration may continue to support some grassland and open-area species tolerant of woody invasion (e.g., lark sparrow, vesper sparrow). Bird species intolerant of woody vegetation is eliminated. Species associated with woodlands and woodland edges will increase. The presence of woody plant species may increase predation by mammals and avian predators and brood parasitism by brown-headed cowbirds. Nearly all grassland-nesting bird species are negatively affected by State 4.0.

Mammals: Nearly all bat species in North Dakota use State 4.0 for roost sites if mature trees with loose bark are available. Nearby community phases supporting insects provide foraging opportunities. This phase provides significant thermal, escape and loafing habitat for elk and deer. Pronghorn use is basically eliminated.

Amphibians/Reptiles: State 4.0 will not support most of the amphibians and reptiles expected to be present in State 1.0, 2.0 and 3.0. Community Phase 4.1 may support some frog species and sagebrush lizards when adjacent to sites supporting sagebrush habitats.

5.0 Go-Back State

Community Phase 5.1 Annual/Pioneer Perennial/Exotics:
This plant community is the result of severe soil disturbance (such as cropping, recreational activity, or concentrated livestock activity for a prolonged period). Following cessation of disturbances, the resulting plant community is dominated by early pioneer annual and perennial plant species. Plant species composition and production are highly variable. Weedy plants can provide pollen sources along with spring and summer cover for many mammals and birds, and their young.

Successful restoration of native species along Transition Pathway R5A results in a native grass and forb community in State 2.0. Failed restoration to native species through Restoration Pathway R5B results in Invaded State 3.0. Wildlife species response will be dependent upon plant community composition, vegetative stature, patch size, and management activities (such as prescribed grazing, burning, range planting, haying, or noxious weed control).

Grazing Interpretations

This site is well adapted to managed grazing by domestic livestock. The predominance of herbaceous plants across all plant community phases best lends these sites to grazing by cattle, but other domestic grazers with differing diet preferences may also be a consideration depending upon management objectives. Often, the current plant community does not match any particular plant community (as described in the ecological site description). Because of this, a resource inventory is necessary to document plant composition and production. Proper interpretation of this inventory data will permit the establishment of a safe, initial stocking rate for the type and class of animals and level of grazing management. More accurate stocking rate estimates should eventually be calculated using actual stocking rate information and monitoring data.

NRCS defines prescribed grazing as “managing the harvest of vegetation with grazing and/or browsing animals with the intent to achieve specific ecological, economic, and management objectives”. As used in this site description, the term ‘prescribed grazing’ is intended to include multiple grazing management systems (e.g., rotational grazing, twice-over grazing, conservation grazing, targeted grazing, etc.) provided that, whatever management system is implemented, it meets the intent of prescribed grazing definition.

The basic grazing prescription addresses balancing forage demand (quality and quantity) with available forage, varying grazing and deferment periods from year-to-year, matching recovery/deferment periods to growing conditions when pastures are grazed more than once in a growing season, implementation of a contingency (e.g., drought) plan, and a monitoring plan. When the management goal is to facilitate change from one plant community phase or state to another, then the prescription needs to be designed to shift the competitive advantage to favor the native grass and forb species.

Grazing levels are noted within the plant community narratives and pathways in reference to grazing management on adjacent sites. “Degree of utilization” is defined as the proportion of the current years forage production that is consumed and/or destroyed by grazing animals (may refer to a single plant species or a portion or all the vegetation). “Grazing utilization” is classified as slight, moderate, full, close, and severe (see the following table for description of each grazing use category). The following utilization levels are also described in the Ranchers Guide to Grassland Management IV. Utilization levels are determined by using the landscape appearance method as outlined in the Interagency Technical Reference “Utilization Studies and Residual Measurements” 1734-3.

Utilization Level:
Slight (Light) 0-20% Appears practically undisturbed when viewed obliquely. Only choice areas and forage utilized.

Moderate 20-40% Almost all of accessible range shows grazing. Little or no use of poor forage. Little evidence of trailing to grazing.

Full 40-60% All fully accessible areas are grazed. The major sites have key forage species properly utilized (about half taken, half left). Points of concentration with overuse limited to 5 to 10 percent of accessible area.

Close (Heavy) 60-80% All accessible range plainly shows use and major sections closely cropped. Livestock forced to use less desirable forage, considering seasonal preference.

Severe > 80% Key forage species completely used. Low-value forages are dominant.

Hydrological functions

Available water is the principal factor limiting forage production on this site. This site is dominated by soils in hydrologic group A; however, some soils are in group B. Infiltration varies from medium to very rapid; runoff potential varies from low to high depending on surface texture, slope percent, slope shape, and ground cover. In many cases, areas with greater than 75% ground cover have the greatest potential for high infiltration and lower runoff. An example of an exception would be where shortgrasses form a strong sod and dominate the site. Dominance by blue grama and/or sedge will result in reduced infiltration and increased runoff. Areas where ground cover is less than 50% have the greatest potential to have reduced infiltration and higher runoff (refer to Section 4, NRCS National Engineering Handbook for runoff quantities and hydrologic curves).

Recreational uses

The largest acreage of public land available for recreation in the MLRA is owned and managed by the United States Forest Service (USFS) within the Little Missouri National Grasslands in North Dakota (525,211 acres). These areas are available for hunting, fishing, hiking, camping, horse and bike riding, nature viewing, etc. In addition, the Bureau of Land Management (BLM) manages 30,895 acres in North Dakota and Montana with the same recreational opportunities as the USFS lands. North Dakota and Montana Department of Trust Lands (80,220 acres) provide hunting, bird watching, hiking, and other outdoor recreation opportunities. North Dakota Wildlife Management Areas (3,447 acres) of land managed by the states for wildlife habitat in MLRA 58C.

MLRA 58C is home to the North and South Units of Theodore Roosevelt National Park. The Park encompasses approximately 70,000 acres and welcomes approximately 900,000 visitors annually. 29,920 acres of the park is designated Wilderness Area. The south unit of the park has a 48-mile scenic drive while the north unit has a 28-mile scenic drive. The Badland and associated ecological sites provide the main scenery attraction.

Bird watching: Public and private grasslands within MLRA 58C provide essential habitat for prairie-dependent bird species (such as Sprague's pipits, western meadowlark, and Baird's sparrow) along with some of the larger, showy members of the upland prairie including marbled godwits, upland sandpipers, and willets. The abundance of publicly owned lands (such as Theodore Roosevelt National Park, USFS, North Dakota Department of Trust Lands, BLM, etc.) provide excellent birding opportunities. MLRA 58C is in the Central Flyway.

Hunting/Fishing: MLRA 58C is a fall destination for upland game bird hunters, especially sharp-tailed grouse. This MLRA also provides excellent white-tailed deer, mule deer, pronghorn, elk, coyote, and mountain lion hunting opportunities along with the only bighorn sheep hunting units in the North Dakota. The North Dakota Game and Fish Department manages three man-made fishing lakes within the MLRA. Available species include rainbow and brown trout, bluegill, and largemouth and smallmouth bass.

Camping: Many camping opportunities exist in the MLRA. Modern and primitive camping is available at the Theodore Roosevelt National Park, Sully’s Creek State Park, Little Missouri State Park, Buffalo Gap Campground, BLM land, and the Dakota Prairie National Grasslands. The Sully’s Creek and Little Missouri State Parks are designated horse parks.

Hiking/Biking: Over 150 miles of the May-Daah-Hey Trail provide some of the best single-track trails in the world for biking, hiking, or horseback riding. The International Mountain Biking Association (IMBA) has designated the hiking, biking, and horseback riding trail as EPIC - meaning it’s one of the top mountain biking trails in the United States. The trail has nine fenced campgrounds, each accessible by gravel surfaced roads; they include camping spurs, potable water, hitching rails, picnic tables, fire rings, and accessible toilets. They are spaced about every 20 miles along the trail. The North and South Units of the Theodore Roosevelt National Park provide 38.9 and 49.6 miles, respectively, of hiking trails for walkers, bikers, or horseback riders. The Little Missouri State Park has 45 miles of trails that run through the North Dakota Badlands.

Canoeing: Traversing 274 miles through MLRA 58C, the Little Missouri River provides early spring canoeing and kayaking. The Little Missouri River is the only designated State Scenic River in the MLRA. The river passes through Sully Creek State Park, the Little Missouri National Grassland, and Theodore Roosevelt National Park.

Wood products

Rocky Mountain juniper may be used for fence posts, wood mulch, rails and similar wood products while ponderosa pine may be used for building materials.

Other products

Seed harvest of native plant species can provide additional income on this site.

Other information

Site Development and Testing Plan
Currently included in this site are soils in Shallow Clayey, Shallow Loamy, and Shallow Sandy ecological sites; however, the depth to soft sedimentary bedrock is less than 10 inches (shallower than the minimum depth to a restrictive layer for those sites). No soil series have been established for these included soils. Some investigation of these soils and the associated plant communities is recommended.

This ESD is the best available knowledge. The site concept and species composition table have been used in the field and tested for more than five years. It is expected that as additional information becomes available revisions may be required.

Inventory data references

Information presented here has been derived from NRCS and other federal/state agency clipping and inventory data. Also, field knowledge of range-trained personnel was used. All descriptions were peer reviewed and/or field-tested by various private, state, and federal agency specialists.

Other references

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Contributors

ND NRCS: David Dewald, Alan Gulsvig, Mark Hayek, Jeanne Heilig, John Kempenich, Chuck Lura, Jeff Printz, and Steve Sieler.

Approval

Suzanne Mayne-Kinney, 4/21/2025

Acknowledgments

NRCS would like to acknowledge the United State Forest Service (USFS) and National Park Service (NPS) for access to USFS and NPS properties and technical assistance in ESD development. USFS: Jack Dahl, Nickole Dahl, Chad Prosser, Jack Butler; NPS: Chad Sexton.