Physiographic features

This site occurs within the floodplain adjacent to perennial streams and natural seeps. Slopes are nearly level to less than two percent.

Table 2. Representative physiographic features

Climatic features

The Central Rocky Mountain Valleys MLRA has a continental climate. Fifty to sixty percent of the annual long-term average total precipitation falls between May and August. Most of the precipitation in the winter is snow on frozen ground. Average precipitation for this MLRA is slightly more than 14 inches, and the frost-free period averages 52 days. Precipitation is highest in May and June, with winter and spring snowstorms contributing to the total. Some of Montana’s driest areas are located in sheltered mountain valleys due to the rain-shadow effect of being on the leeside of some mountain ranges.

Table 3. Representative climatic features

Climate stations used

• (1) HEBGEN DAM [USC00244038], West Yellowstone, MT

• (2) LAKEVIEW [USC00244820], Lima, MT

• (3) BOZEMAN GALLATIN FLD [USW00024132], Belgrade, MT

• (4) DEER LODGE 3 W [USC00242275], Deer Lodge, MT

• (5) DILLION U OF MONTANA WESTERN [USC00242409], Dillon, MT

• (6) GLEN 2 E [USC00243570], Dillon, MT

• (7) ENNIS [USC00242793], Ennis, MT

• (8) BOULDER [USC00241008], Boulder, MT

• (9) GARDINER [USC00243378], Gardiner, MT

• (10) TOWNSEND [USC00248324], Townsend, MT

• (11) TRIDENT [USC00248363], Three Forks, MT

• (12) TWIN BRIDGES [USC00248430], Sheridan, MT

• (13) WHITE SULPHUR SPRNGS 2 [USC00248930], White Sulphur Springs, MT

• (14) DILLON AP [USW00024138], Dillon, MT

• (15) HELENA RGNL AP [USW00024144], Helena, MT

• (16) DIVIDE [USC00242421], Wise River, MT

• (17) WISDOM [USC00249067], Wisdom, MT

• (18) JACKSON [USC00244447], Jackson, MT

• (19) LIVINGSTON MISSION FLD [USW00024150], Livingston, MT

• (20) LIVINGSTON 12 S [USC00245080], Livingston, MT

• (21) VIRGINIA CITY [USC00248597], Virginia City, MT

• (22) WEST YELLOWSTONE [USC00248857], West Yellowstone, MT

• (23) BIG SKY 2WNW [USC00240775], Gallatin Gateway, MT

• (24) WILSALL 8 ENE [USC00249023], Wilsall, MT

• (25) BUTTE BERT MOONEY AP [USW00024135], Butte, MT

Influencing water features

The Riparian Meadow (RM) ecological site is associated with perennial streams, rivers, and flowing springs. This site has a permanent water table between 12 and 24 inches below the soil surface. Seasonally significant subsurface water movement exists due to the site's location adjacent to active streams, creeks, and rivers. It is rarely to occasionally flooded from streambank overflow. Periods of inundation are very brief. Typically, flooding is associated with spring snowmelt from March to early June.

Wetland description

The Riparian Meadow ecological site is directly associated with multiple Rosgen Classified Streams. The primary Rosgen classification stream types include E3, E4, E5, and E6.

E-classified streams are low-gradient, meandering riffle-pool streams with a low width-to-depth ratio and little deposition. These systems are very efficient at moving sediment, stable, and well vegetated. They have a high meander-to-width ratio. These occur in broad valleys and meadows.

These wetlands typically support wet emergent vegetation but are not capable of supporting species such as cattails.

Soil features

The soils of this ecological site are alluvium of mixed origin with highly variable surface textures. These soils are hydric due to the permanent water table and flooding events. The water table is 12 to 24 inches below the soil surface. However, the coarse texture of the subsurface soil may not directly express traditional redoximorphic features associated with such sites. Soils tend to be deep or very deep. Surface textures tend to be loam, silt loam, very fine sandy loam, and fine sandy loam. As previously stated, subsurface horizons will often be coarse-grained, allowing for moderate to rapid permeability. These sites tend to be classified as poorly to very poorly drained due to the presence of a permanent water table, but water transmission will be moderate.

Common soil series in this ecological site include (but are not limited to) Beavrock, Dutchhollow, and Mooseflat.

Table 4. Representative soil features

Animal community

Livestock grazing is suitable on this site. This site has the potential to produce a large amount of high-quality forage but is sensitive to improper grazing management. Livestock will seek out this site throughout the year, especially in the summer, so careful management is necessary to maintain species composition and production. Management objectives should include maintenance or improvement of the vegetation community. Shorter grazing periods and adequate re-growth after grazing are recommended for plant recovery and to protect stream banks against high-flow events.

Management considerations could include: rotation grazing, rest, prescribed utilization levels, off-site water development, varying the season of use, developing riparian pastures, providing alternative forage sources (i.e., new seedings or special use pastures, brush management, prescribed burning, and using supplements as ways to attract livestock to other areas of a pasture), stocking rates, stock density, armored water gaps, using a different breed or class of livestock, culling animals that spend too much time in the riparian area, alternating pasture entry locations, and herding. Season-long use of this site can be detrimental and will alter the plant community over time. Because of the wet soils often associated with this ecological site, soil compaction, and streambank shearing can result from improper grazing.

The herbaceous component can be increased by providing rest on a regular basis, followed by late-season use the next year. This treatment helps restore the plant’s vigor and aids seed dispersal. Avoiding or limiting use during the hotter part of the year is also recommended. Recommended grazing periods for the hot season (generally July 1 through September 15) should be no more than 14 days without rest between grazing events. During other times of the grazing season, the recommended grazing period is up to 28 days.

Management strategies discussed above apply best to plant communities that are near or similar to their potential composition. When the dominant community is comprised of non-native grasses, additional rest often helps with the re-establishment of the native species. Often, extra rest will help restore some of the stability and natural hydrology of the site. Extra rest is intended to maintain more above ground production. This growth then helps trap sediment during flood or overflow events. Over time, the trapped sediment restores the stream banks and begins to restore or enlarge the riparian area. The stream’s cross section often becomes narrower and deeper as riparian areas are expanded. This often results in raising the water column or water table in the system. Restoring hydrology (i.e., making the site wet again) will cause a shift back to the native herbaceous component of the site.

In situations where the stream has been incised and there is minimal potential for restoring original hydrology, yet there is still a significant component of willows and other woody species that are desirable to maintain, rest needs to be included in the management plan to aid with the maintenance of the woody species and to establish several age classes. Without frequent flooding to provide habitat for new seedling establishment, these plants will depend on vegetative means for reproduction. Rest and deferment allow that to happen. The rest period needs to be long enough to allow the new sprouts to grow out of reach of the grazing or browsing animal. These areas can often be safely utilized at a time of year when the herbaceous component is lush. The stream’s cross section often changes as riparian areas are expanded. Consider techniques that help draw the animals out of these areas.

A site in communities in States 3, 4, or 5 will need rest annually until the site has stabilized and the plant community begins to move toward the Reference State. The rest treatment maintains more above-ground production, which in turn traps more sediment during overflow events. The additional sediment rebuilds banks and helps restore the riparian area to its potential extent. Often, a change in the stream’s width/depth ratio results in raising the water table. As the water table level rises, the plants will shift to primarily obligate species. The Reference State and Increaser State species on this ecological site are predominantly obligate or facultative-wet.

Drought management and monitoring plans should be included as part of a comprehensive plan provided to the land owner or decision-maker. Control of noxious and other undesirable weeds should also be a part of the plan. Management of this ecological site needs to be included as part of a plan for all grazing lands.

This ecological site provides important habitat for many wildlife species. It is an important source of forage for grazing animals (i.e., herbivores). The seeds produced by the sedges and other plants are an important source of food for waterfowl and other birds.

The type of wildlife is somewhat dependent on site factors such as the size of the stream and the surrounding area. It is critical habitat for ducks, geese, and other migratory waterfowl. The site will be used for resting during migration and for nesting and rearing if there is open water available for a long enough time period.

These sites often provide a critical source of protein during migration. If the stream this site is associated with is large enough, animals such as muskrats may also use the site.

There have been no species identified with special emphasis specific to this site. However, bald eagles and peregrine falcons will use the habitats provided by this ecological site, adjacent sites, and the associated stream for portions of their life cycle.

Hydrological functions

Soils have been classified into hydrologic soil groups and are defined by NRCS soil scientists. The soils associated with this ecological site are generally in Hydrologic Soil Group B. The infiltration rates for these soils are moderate when thoroughly wet with a moderate rate of water transmission. The runoff potential for this site is low.

This ecological site receives and generates runoff. The site is typically wet, receiving the majority of its moisture from its hydrologic connection with streamflow and water table fluctuations.

Runoff is characterized by surface flooding from overbank flows. On-site precipitation is generally considered a minor source of runoff at this site. As the streamflow subsides, runoff typically becomes subsurface return flows.

Any condition that would cause an increased instantaneous runoff peak (e.g., poorly designed clearcutting in the watershed) could degrade the channel, causing headcutting. An incised stream (Rosgen G or F type) is often the result.

Downcutting (incisement) would be a catastrophic event for this ecosystem. Channel downcutting will increase subsurface drainage, lower the seasonal water table, reduce the frequency of overbank flow, and reduce the duration of near-surface saturation. Bank erosion will increase.

The stream, in time, will adjust to a lower base elevation. However, the result of downcutting will be a new floodplain at a lower elevation, a lower water table elevation, a less floodprone width, and a smaller adjacent riparian and wetland area. The dominant vegetation in the previous riparian/wetland area will change (i.e., from obligative and facultative-wet to facultative, etc.). Given enough time, these conditions will eventually result in this site becoming either a Stream Terrace, or an upland site, depending on the resulting depth of the water table.

The vegetative community can also be changed for other reasons, such as if the water table drops during the growing season due to a lowering of the base elevation of adjacent streams or several years of drought conditions.

Plant cover affects overbank flow and runoff in several ways. The foliage and litter maintain the soil's infiltration potential by preventing the impact of raindrops from sealing the soil surface. Some of the precipitation will be intercepted by the plants and withheld from the initial runoff. Vegetation, including litter, forms numerous barriers to water flow, lengthening the time of concentration, dissipating energy, and reducing the peak discharge.

The hydrologic condition of this site has a significant effect on overbank flow. The hydrologic condition considers the effects of cover, including litter, and management on infiltration. Good hydrologic conditions indicate that the site usually has a lower runoff potential. A good hydrologic condition for this site also indicates that the site should remain stable and functional after high-flow events.

Erosion is minor for sites with high similarity. Sites with high similarity generally have enough cover and litter to optimize infiltration, minimize runoff and erosion, minimize streambank erosion, and have a good hydrologic condition. The deep root systems of the willows, sedges, and grasses in the Reference Plant Community will help maintain or improve site stability and function, as well as reduce erosion.

Sites in states 3, 4, or 5 are generally considered to be in less than good hydrologic condition. However, sites may still exhibit a high percentage of cover. The cover is often from shallow-rooted species (e.g., Kentucky bluegrass, redtop) that cannot hold the banks together during high-flow events, etc.

On-site precipitation will seldom be necessary to keep the root zone at field capacity during the growing season. The root zone should have free water available from stream overflow in the early part of the growing season and from the water table within two feet of the surface the remainder of the year. Plant cover and litter help retain soil moisture for use by the plants.

Recreational uses

This site provides multiple recreational opportunities for fishing, hiking, horseback riding, big game hunting, and bird hunting. Some plants have flowers that appeal to photographers. This site provides valuable open space.

Wood products

None

Other products

none

Inventory data references

Information presented was derived from the site’s Range Site Description (Riparian Meadow, Northern Rocky Mountain Valleys, South, East of Continental Divide), NRCS clipping data, literature, field observations, and personal contacts with range-trained personnel (i.e., used professional opinion of agency specialists, observations of land managers, and outside scientists).

References

• Pokorny, M.L., R. Sheley, C.A. Zabinski, R. Engel, T.J. Svejcar, and J.J. Borkowski. 2005. Plant Functional Group Diversity as a Mechanism for Invasion Resistance.

• . 2005. Fire Effects Information System. http://www.fs.fed.us/database/feis/.

• . 2021 (Date accessed). USDA PLANTS Database. http://plants.usda.gov.

• Arno, S.F. and G.E. Gruell. 1982. Fire History at the Forest-Grassland Ecotone in Southwestern Montana. Journal of Range Management 36:332–336.

• Bestelmeyer, B., J.R. Brown, J.E. Herrick, D.A. Trujillo, and K.M. Havstad. 2004. Land Management in the American Southwest: a state-and-transition approach to ecosystem complexity. Environmental Management 34:38–51.

• Bestelmeyer, B. and J. Brown. 2005. State-and-Transition Models 101: A Fresh look at vegetation change.

• Blaisdell, J.P. 1958. Seasonal development and yield of native plants on the Upper Snake River Plains and their relation to certain climate factors.

• Blaisdell, J.P. and R.C. Holmgren. 1984. Managing Intermountain Rangelands--Salt-Desert Shrub Ranges. General Tech Report INT-163. USDA Forest Service, Intermountain Forest and Range Experiment Station, Ogden, UT. 52.

• DiTomaso, J.M. 2000. Invasive weeds in Rangelands: Species, Impacts, and Management. Weed Science 48:255–265.

• Dormaar, J.F., B.W. Adams, and W.D. Willms. 1997. Impacts of rotational grazing on mixed prairie soils and vegetation. Journal of Range Management 50:647–651.

• Gerhard, L.M. 2019. IMPACTS OF KENTUCKY BLUEGRASS AND PATCH-BURN GRAZING MANAGEMENT ON SOIL PROPERTIES IN THE NORTHERN GREAT PLAINS.

• Hobbs, J.R. and S.E. Humphries. 1995. An integrated approach to the ecology and management of plant invasions. Conservation Biology 9:761–770.

• Kuchler, A.W. 1964. Potential natural vegetation of the conterminous United States.

• Lacey, J.R., C.B. Marlow, and J.R. Lane. 1989. Influence of Spotted knapweed (Centaurea maculosa) on surface runoff and sediment yield.. Weed Technology 3:627–630.

• Lesica, P. and S.V. Cooper. 1997. Presettlement vegetation of Southern Beaverhead County, MT.

• Manske, L.L. 1980. Habitat, phenology, and growth of selected sandhills range plants.

• Masters, R. and R. Sheley. 2001. Principles and practices for managing rangeland invasive plants. Journal of Range Management 38:21–26.

• Matt A. Bahm, Thomas G. Barnes, and Kent C. Jensen. 2011. Herbicide and Fire Effects on Smooth Brome (Bromus inermis) and Kentucky Bluegrass (Poa pratensis) in Invaded Prairie Remnants. Invasive Plant Science and Management 4:189–197.

• McCalla, G.R., W.H. Blackburn, and L.B. Merrill. 1984. Effects of Livestock Grazing on Infiltration Rates of the Edwards Plateau of Texas. Journal of Range Management 37:265–269.

• Moulton, G.E. and T.W. Dunlay. 1988. The Journals of the Lewis and Clark Expedition. Pages in University of Nebraska Press.

• Mueggler, W.F. and W.L. Stewart. 1980. Grassland and Shrubland Habitat Types of Western Montana.

• Pelant, M., P. Shaver, D.A. Pyke, and J.E. Herrick. 2005. Interpreting Indicators of Rangeland Health.

• Pitt, M.D. and B.M. Wikeem. 1990. Phenological patterns and adaptations in an Artemisia/Agropyron plant community. Journal of Range Management 43:350–357.

• Ross, R.L., E.P. Murray, and J.G. Haigh. July 1973. Soil and Vegetation of Near-pristine sites in Montana.

• Schoeneberger, P.J. and D.A. Wysocki. 2017. Geomorphic Description System, Version 5.0..

• Smoliak, S., R.L. Ditterlin, J.D. Scheetz, L.K. Holzworth, J.R. Sims, L.E. Wiesner, D.E. Baldridge, and G.L. Tibke. 2006. Montana Interagency Plant Materials Handbook.

• Stavi, I. 2012. The potential use of biochar in reclaiming degraded rangelands. Journal of Environmental Planning and Management 55:1–9.

• Stringham, T.K., W.C. Kreuger, and P.L. Shaver. 2003. State and Transition Modeling: an ecological process approach. Journal of Range Management 56:106–113.

• Stringham, T.K. and W.C. Krueger. 2001. States, Transitions, and Thresholds: Further refinement fro rangeland applications.

• Sturm, J.J. 1954. A study of a relict area in Northern Montana. University of Wyoming, Laramie 37.

• Thurow, T.L., Blackburn W. H., and L.B. Merrill. 1986. Impacts of Livestock Grazing Systems on Watershed. Page in Rangelands: A Resource Under Siege: Proceedings of the Second International Rangeland Congress.

• Various NRCS Staff. 2013. National Range and Pasture Handbook.

• Walker, L.R. and S.D. Smith. 1997. Impacts of invasive plants on community and ecosystem properties. Pages 69–86 in Assessment and management of plant invasions. Springer, New York, NY.

• Whitford, W.G., E.F. Aldon, D.W. Freckman, Y. Steinberger, and L.W. Parker. 1989. Effects of Organic Amendments on Soil Biota on a Degraded Rangeland. Journal of Range Management 41:56–60.

Approval

Kirt Walstad, 5/01/2024