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Ecological site PX136X00X640

Low Terraces and Drains, Occasional Inundation

Last updated: 5/02/2025
Accessed: 05/19/2025

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General information

Provisional. A provisional ecological site description has undergone quality control and quality assurance review. It contains a working state and transition model and enough information to identify the ecological site.

MLRA notes

Major Land Resource Area (MLRA): 136X–Southern Piedmont

This MLRA is on a large piedmont underlain by metamorphic and igneous bedrock. It stretches from north-central Virginia to east-central Alabama, running parallel to the Appalachian highlands to the northwest and the Atlantic coast to the southeast.

MLRA 136 has only subtle climatic differences with MLRA 148 (Northern Piedmont), with which it shares a common geologic origin. This adjacent MLRA sits to the north. Along the fall line, it shares a boundary with MLRA 133A (Southern Coastal Plain), MLRA 137 (Carolina and Georgia Sand Hills), and 133C (Gulf Coastal Plain). Here, unconsolidated Coastal Plain sediments intersect the much older Piedmont bedrock. Along it's northwestern boundary, it sits adjacent to MLRAs 130B (Southern Blue Ridge), 130A (Northern Blue Ridge), and 128 (Southern Appalachian Ridges and Valleys). These MLRAs are distinguished from the Southern Piedmont by topographic and elevational differences, as well as differences in the age, origin, and degree of metamorphism of the underlying bedrock.

Five states are intersected by the MLRA, including North Carolina (29 percent), Georgia (27 percent), Virginia (20 percent), South Carolina (17 percent), and Alabama (7 percent). The MLRA extent makes up about 63,720 square miles (165,034 square kilometers).

MLRA PHYSIOGRAPHY
The landscape is generally rolling to hilly, with a well-defined drainage pattern. Streams have dissected the original Piedmont plateau, forming narrow ridgetops, somewhat broad interfluves, and short, steep side slopes adjacent to the streams and drainageways. With some exceptions, the valley floors are generally narrow and make up about 10 percent or less of the land area. The associated stream terraces are generally small and of minor extent.

The landscape is moderately dissected overall, with isolated erosional remnants (monadnocks) and other areas of high topographic relief interspersed. Over most of the MLRA, elevation ranges from approximately 325 to 1,315 feet (100 to 400 meters), with elevations generally increasing toward the Appalachian Highlands, in the upper Piedmont, and decreasing toward the Coastal Plain, in the lower Piedmont.

The major rivers that cross this area en route to the ocean include, from north to south, the James, Roanoke, Cape Fear, Savannah, Altamaha, Chattahoochee, and Alabama Rivers. These rivers typically originate within the Piedmont or in the Blue Ridge. They flow east and south across the Coastal Plain and empty into the Atlantic Ocean or the Gulf of America.

MLRA GEOLOGY
Precambrian and Paleozoic metamorphic and igneous rocks underlie almost all of this MLRA. The dominant metamorphic rock types include gneiss, schist, slate, argillite, and phyllite, among others. Dominant igneous rock types include granite and other related felsic crystalline rocks. Mafic intrusive rocks, including gabbro, diabase, amphibolite, and other dark colored rocks, underlie a minority of the upland landscape. These mafic intrusions crop out in the form of dikes and sills, and often weather to produce soils high in base cations.

The Carolina Slate Belt runs lengthwise through the east-central part of the MLRA, in southern Virginia, North Carolina, South Carolina, and the eastern-most part of the Georgia Piedmont. This region is underlain by fine-grained metasedimentary and metavolcanic rock, which generally weathers to produce soils high in silt.

From Virginia to North Carolina, and in a single county in South Carolina, fault-bounded Triassic Basins are scattered amongst the igneous and metamorphic uplands. These basins are underlain by Triassic and Jurassic siltstone, shale, sandstone, and mudstone, which were laid down in response to continental rifting and subsequent erosion during the Mesozoic era.

MLRA SOILS
The dominant soil orders of the MLRA are Ultisols, Inceptisols, and Alfisols. Ultisols and Alfisols are typically found on more stable landforms, such as interfluves, gentle hillslopes, broad ridgetops, and stream terraces, while Inceptisols are typically found on less stable landforms, including flood plains, steep hillslopes, and narrow ridgetops.

Soils of the region predominantly have a thermic temperature regime, a udic moisture regime, and generally have kaolinitic or mixed mineralogy. In the upper Piedmont of Virginia and North Carolina however, soils have a mesic soil temperature regime, as depicted in figure 2. The mesic soil temperature regime portion of the MLRA is oriented from northeast to southwest and occupies approximately 18 percent of the MLRA extent, or 11,729 square miles (30,377 square kilometers).

Broadly speaking, soils of the Southern Piedmont uplands are shallow to very deep, well drained, and loamy or clayey. Soils of the river valleys are generally very deep, well to poorly drained, and loamy. Soils tend to be finer-textured than in Coastal Plain regions.

MLRA CLIMATE
In general, precipitation is evenly distributed throughout the year in this MLRA, with occasional drought-like conditions extending from late summer into autumn. During the growing season, most of the rainfall comes from high-intensity, convective thunderstorms. Significant moisture also comes from the movement of warm and cold fronts across the MLRA from November to April. High amounts of rain can also occur during hurricanes, usually during the months of August through October.

Over most of the MLRA, snowfall is typically light, though overall, the mesic soil temperature regime portion of the MLRA features colder temperatures, more snowfall, and a shorter growing season than in the thermic portion. The cooler climate in this region supports an increase in species with northern or Blue Ridge affinities. Both the mean annual temperature and the length of the freeze-free period increase from north to south and with decreasing elevation from the upper to the lower Piedmont.

MLRA LAND USE AND RESOURCES
Once largely cultivated, much of this region is now planted to loblolly pine or has reverted to successional pine and hardwood forests. The more productive lands support small to medium-size family farms that produce crops and livestock, while the less productive lands have been in forest for some time. Most of the open areas are used for grazing beef cattle, though in years past, dairy cattle were also important to the local economy. The principal crops of the region include corn, soybeans, and small grains. Burley tobacco remains a crop of local importance. Cotton is grown in the thermic soil temperature regime portion of the MLRA.

Several major land cover transformations have occurred in the Southern Piedmont over the past several centuries; from open woodlands sculpted by fire, to farmland, to closed forests and planted pine, past land uses have played an outsized role in shaping present-day soils and vegetation patterns in the region. Land-use intensity peaked with the arrival of the industrial revolution, which gradually increased demand for textiles. Cotton became the dominant crop over much of the region.

In spite of early successes, two centuries of poor management practices accelerated soil erosion, stripping away the fertility and moisture-supplying capacity of soils. In addition to soil losses in the uplands, legacy sediments derived from the eroded land rapidly accumulated in the river valleys below, often leading to changes in hydrology and flooding frequency.

After being stripped of it's loamy topsoil, many areas of the Piedmont had been so badly eroded as to render the land unsuitable or economically impractical for agriculture. The effects of erosion were widespread, with cumulative soil loss estimates ranging from 5 to 10 inches on average. The steeper slopes, which had often been cleared and farmed at the height of the Cotton era, generally suffered greater losses. By the 1930's, crop production was in rapid decline in the Southern Piedmont. The loss of soil productivity due to erosion, losses to the cotton boll weevil, development of synthetic fibers, and the onset of the Great Depression all contributed to rapid abandonment of cropland. By 1960, cropland acres had decreased by more than 50 percent in nearly every county in the Southern Piedmont.

While crop production is still important today on the more productive lands, those of lower productivity, or those that were subject to severe erosion, were often abandoned some time ago. Typically, they have either reverted to forest, or have been converted to other uses. Although the productivity of soils was greatly reduced through erosion, less intensive land uses such as grazing and forestry were still feasible. These land uses gained popularity as patterns of urban migration, low commodity prices, and other factors gradually made crop production less economical on the marginal lands.

In recent years, large-scale adoption of soil conservation practices have led to better outcomes with respect to erosion in much of MLRA, increasing the economic viability and long-term sustainability of Piedmont farms. Despite some success, water erosion remains one of the most important soil resource concerns in the MLRA.

Other major resource concerns include increasing conversion of prime farmland and farmland of statewide importance to urban uses. Throughout the MLRA, metropolitan areas are expanding into lands that have historically been used for timber or agriculture. This change in land use is occurring rapidly in the corridor called the Piedmont Crescent, which extends from Atlanta, Georgia, to Raleigh, North Carolina.

HISTORIC VEGETATION COVER
Over most of the Southern Piedmont uplands, the historic oak-hickory, or oak-hickory-pine forest, once covered large portions of the landscape. It was dominated by upland oaks, such as white oak (Quercus alba), northern red oak (Quercus rubra), and southern red oak (Quercus falcata), with a smaller contribution from hickories (Carya spp.) and pines. The principal pine species are shortleaf pine (Pinus echinata), loblolly pine (Pinus taeda), and to the north and west, Virginia pine (Pinus virginiana). In the southernmost and easternmost portions of the MLRA, the historic montane longleaf pine forest, dominated by longleaf pine (Pinus palustris), shortleaf pine (P. echinata), and dry-site oaks, was found on ridgetops and steep south or west-facing slopes.

According to historic accounts, forests and woodlands of the past were generally more open and park-like, having been exposed to a more frequent fire regime. Piedmont prairies, likely maintained by Native Americans, were also reportedly common across the landscape, as were fire-maintained canebrakes along the streams (Trimble 1974; Daniels 1987; Griffith et al. 2002; Van Lear et al. 2004; Dearman and James 2019; Schomberg et al. 2020; USDA-NRCS 2022).

LRU notes

MLRA 136 is one of the largest MLRAs in the United States. It has a broad north-south and east-west extent and covers a wide range of elevations. The MLRA is partitioned by the mesic-thermic line, which divides the MLRA into mesic and thermic soil temperature regimes (figure 2.). The mesic soil temperature regime was delineated based on estimates of the native range of loblolly pine, which was historically absent in this part of the MLRA. In addition, this region is said to represent the northern and western limits of cotton production, an important crop to the south and east.

ESDs developed for this MLRA were split geographically into mesic and thermic ecological site concepts. Climate variation across the MLRA extent warrants the development of Land Resource Unit (LRU) classifications, to further subdivide the MLRA and support more precise Ecological Site Descriptions.

Classification relationships

APPLICABLE USNVC ASSOCIATIONS
CEGL007356 Quercus pagoda - Quercus phellos - Quercus lyrata - Quercus michauxii / Chasmanthium latifolium

APPLICABLE EPA ECOREGIONS
Level III: 45. Piedmont
Level IV: 45a. Southern Inner Piedmont; 45b. Southern Outer Piedmont; 45c. Carolina Slate Belt; 45f. Northern Outer Piedmont; 45g. Triassic Basins (EPA 2013).

APPLICABLE USFS ECOLOGICAL UNITS
Domain: Humid Temperate
Division: Subtropical
Ecological province: 231. Southeastern Mixed Forest
Ecological sections: 231I.Central Appalachian Piedmont; 231A. Southern Appalachian Piedmont (Cleland et al. 2007).

Based on the USGS physiographic classification system (Fenneman and Johnson 1946), most of MLRA 136 is in the Piedmont Upland section of the Piedmont province, in the Appalachian Highlands division.

Ecological site concept

This ecological site includes wet areas on low stream terraces, or along drainageways, which sit slightly above the active flood plain and which are not subject to regular overbank flooding. It is situated in river valleys, or along the lower segments of drainageways leading down to river valleys, in the thermic soil temperature regime portion of the MLRA.

Because this ecological site typically sits at an intermediate elevation above the river, the frequency of flooding is typically lower than those ecological sites found on active flood plains. Flooding occurs mainly after periods of unusually wet weather, as floodwaters decant into depressions or remnant backswamps on low terraces of large river systems. Still, flooding frequency is usually higher than on PX136X00X660, an associated ecological site that often sits on the higher-lying stream terraces nearby. When overbank flooding does occur, it typically slows by the time it reaches this ecological site, so that scouring and movement of debris are relatively minor, but periodic deposition of sediment-bound nutrients is important for fertility. Though flooding is important to consider for planning purposes, it is not the primary driver of pedogenesis or ecological dynamics.

Soils on this ecological site are typically very deep, poorly drained Ultisols or Alfisols. They are generally better developed than those of adjacent flood plains, as the flooding frequency is not great enough to interfere with soil formation to any major extent. Being situated on more stable surfaces, soils on this ecological site usually have an argillic horizon in subsurface layers. Parent materials are typically fine-textured old alluvial sediments.

The reference state supports a closed canopy forest dominated by bottomland oaks, including willow oak (Quercus phellos), overcup oak (Quercus lyrata), and swamp chestnut oak (Quercus michauxii), along with other species typical of alluvial settings. Dominant land uses include wildlife habitat and wetland mitigation.

ES CHARACTERISTICS SUMMARY
• Thermic soil temperature regime
• Occurs on low stream terraces (flood-plain steps) in river valleys, or along the lower segments of drainageways leading down to river valleys
• Seasonal high water table: 0 - 12 inches from the soil surface
• Soils: very deep, poorly drained Ultisols or Alfisols

Associated sites

PX136X00X650	Low Terraces and Drains, Rare Inundation Found in similar or slightly higher landscape positions. The seasonal high water is deeper (12-18 inches from the soil surface), resulting in a decrease in obligate or facultative wetland indicator species.
PX136X00X660	High Terraces, Very Rare Inundation Found in in higher landscape positions where flooding is rarer. The seasonal high water table is much deeper (> 18 inches from the soil surface), resulting in a substantial decrease in obligate or facultative wetland indicator species and a notable increase in species diversity (including a significant contribution from species which are usually more prevalent in uplands).

PX136X00X650

Low Terraces and Drains, Rare Inundation

Found in similar or slightly higher landscape positions. The seasonal high water is deeper (12-18 inches from the soil surface), resulting in a decrease in obligate or facultative wetland indicator species.

PX136X00X660

High Terraces, Very Rare Inundation

Found in in higher landscape positions where flooding is rarer. The seasonal high water table is much deeper (> 18 inches from the soil surface), resulting in a substantial decrease in obligate or facultative wetland indicator species and a notable increase in species diversity (including a significant contribution from species which are usually more prevalent in uplands).

Similar sites

PX136X00X140	Mesic Temperature Regime, Low Terraces and Drains, Occasional Inundation The soil temperature regime is mesic, occurring outside of the native range of loblolly pine (Pinus taeda).
PX136X00X600	Flood Plain Forest, Very Wet On backswamps, sloughs, and depressions on active flood plains. Flooding is more frequent and of longer duration, leading to higher flooding-related tree mortality and an increase in riparian species which invest in rapid growth and early reproduction (e.g., red maple (Acer rubrum), green ash (Fraxinus pennsylvanica), etc.). Soil pH and natural fertility are usually higher on these younger surfaces.

PX136X00X140

Mesic Temperature Regime, Low Terraces and Drains, Occasional Inundation

The soil temperature regime is mesic, occurring outside of the native range of loblolly pine (Pinus taeda).

PX136X00X600

Flood Plain Forest, Very Wet

On backswamps, sloughs, and depressions on active flood plains. Flooding is more frequent and of longer duration, leading to higher flooding-related tree mortality and an increase in riparian species which invest in rapid growth and early reproduction (e.g., red maple (Acer rubrum), green ash (Fraxinus pennsylvanica), etc.). Soil pH and natural fertility are usually higher on these younger surfaces.

Figure 1. EPA level IV ecoregions of the Southern Piedmont (45).

Figure 2. Spatial illustration of soil temperature regimes of the Southern Piedmont.

Figure 3. Spatial extent of this ecological site representing the major areas where this site is important on the landscape.

Table 1. Dominant plant species

Tree	(1) Quercus phellos (2) Quercus lyrata
Shrub	(1) Ilex decidua (2) Lindera benzoin
Herbaceous	(1) Carex (2) Arisaema triphyllum

Legacy ID

F136XY640VA

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Physiographic features

This ecological site is generally found in depressional features, or on broad flats, on low stream terraces. Although colloquially these landforms are described as low stream terraces, they are formally classified as flood-plain steps, since they usually sit slightly below the 100 year flood zone. Occasionally, this ecological site can be found along the lower segments of drainageways leading down to river valleys. In either case, flooding is not the primary driver of pedogenesis or ecological dynamics.

This ecological site is geographically restricted to the thermic soil temperature regime portion of the MLRA. It is most extensive on the stepped surfaces of relatively broad river valleys of large river systems, where floodwaters periodically decant into depressions or remnant backswamps on low stream terraces. These low terraces sit elevated slightly above the active flood plain, and are spared from some of the flooding experienced on lower flood plain surfaces.

Stream terraces form in response to gradual downcutting of a stream channel and its immediately adjacent surfaces, usually initiated by events that shift erosional and depositional equilibrium. Over time, abandoned portions of the flood plain are left behind as remnant features. Representative locations are nearly level to gently sloping, with a representative slope of 0 to 2 percent and a maximum slope of 7 percent. The geologic substrate is typically fine-textured old alluvial sediments (Zinck 2016; Schoeneberger and Wysocki 2017).

Note: river valleys associated with Triassic Basins tend to be broader than in most other parts of the Southern Piedmont, irrespective of stream order, due to the high weatherability of Triassic sediments. Here, distinct landforms, such as stream terraces, flood plain flats, backswamps, and natural levees, tend to be better developed. This is known to have a strong influence over the vegetation communities that establish on a given site, allowing vegetation communities to sort out more neatly along gradients of hydroperiod, elevation above the river channel, and other flooding-related variables. At this time however, there is not enough data to support a geographic split between alluvial ecological site concepts associated with Triassic Basins (EPA ecoregion 45g) and those of other regions. Future ecological site work should consider targeting Triassic Basin river valleys to determine weather a distinct set of ecological site concepts is warranted, and if delineating these concepts across the landscape would be feasible.

Figure 4. Typical soil-landscape relationships in a broad river valley in the Southern Piedmont. Roanoke soils are associated with this ecological site, depicted here on depressions and remnant backswamps on low stream terraces above an active flood plain.

Table 2. Representative physiographic features

Landforms	(1) River valley > Flood-plain step (2) Piedmont > Drainageway
Runoff class	Low to high
Flooding duration	Brief (2 to 7 days)
Flooding frequency	Rare to occasional
Ponding duration	Brief (2 to 7 days)
Ponding frequency	None to rare
Elevation	380 – 880 ft
Slope	2%
Water table depth	6 – 10 in
Aspect	Aspect is not a significant factor

Table 3. Representative physiographic features (actual ranges)

Runoff class	Negligible to very high
Flooding duration	Very brief (4 to 48 hours) to long (7 to 30 days)
Flooding frequency	Rare to frequent
Ponding duration	Brief (2 to 7 days) to long (7 to 30 days)
Ponding frequency	None to frequent
Elevation	190 – 1,080 ft
Slope	7%
Water table depth	12 in

Climatic features

On this ecological site, the average mean annual precipitation is 48 inches. On average, the rainiest months occur in July and August, as well as in March. The driest months occur in April, May, and October.

Table 4. Representative climatic features

Frost-free period (characteristic range)	157-186 days
Freeze-free period (characteristic range)	184-220 days
Precipitation total (characteristic range)	45-51 in
Frost-free period (actual range)	151-195 days
Freeze-free period (actual range)	180-228 days
Precipitation total (actual range)	43-55 in
Frost-free period (average)	171 days
Freeze-free period (average)	202 days
Precipitation total (average)	48 in

Characteristic range

Actual range

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Figure 5. Monthly precipitation range

Characteristic range

Actual range

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Figure 6. Monthly minimum temperature range

Characteristic range

Actual range

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Figure 7. Monthly maximum temperature range

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Figure 8. Monthly average minimum and maximum temperature

Figure 9. Annual precipitation pattern

Figure 10. Annual average temperature pattern

Climate stations used

(1) LA GRANGE 1N [USC00094949], LaGrange, GA
(2) ALEXANDER CITY [USC00010160], Alexander City, AL
(3) ROCK MILLS [USC00017025], Roanoke, AL
(4) ASHLAND 3 ENE [USC00010369], Ashland, AL
(5) CROZIER [USC00442142], Maidens, VA
(6) AMELIA 8 NE [USC00440188], Amelia Court House, VA
(7) AMELIA COURTHOUSE 1 [USC00440187], Amelia Court House, VA
(8) CAMP PICKETT [USC00441322], Blackstone, VA
(9) LAWRENCEVILLE 3 E [USC00444768], Freeman, VA
(10) CLARKSVILLE [USC00441746], Clarksville, VA
(11) CHASE CITY [USC00441606], Chase City, VA
(12) JOHN H KERR DAM [USC00444414], Boydton, VA
(13) GREENBAY 3 NE [USC00443565], Burkeville, VA
(14) LOUISBURG [USC00315123], Louisburg, NC
(15) FALLS LAKE [USC00312993], Raleigh, NC
(16) CLAYTON WTP [USC00311820], Clayton, NC
(17) CARY [USC00311535], Cary, NC
(18) SANFORD 8 NE [USC00317656], Sanford, NC
(19) RALEIGH 4 SW [USC00317074], Raleigh, NC
(20) DURHAM [USC00312515], Durham, NC
(21) CONCORD [USC00311975], Concord, NC
(22) FOREST CITY 6 SW [USC00313150], Forest City, NC
(23) FOREST CITY 8 W [USC00313152], Rutherfordton, NC
(24) CHESTER 1 SE [USC00381633], Chester, SC
(25) NINETY NINE ISLANDS [USC00386293], Blacksburg, SC
(26) EXPERIMENT [USC00093271], Griffin, GA
(27) ATLANTA FULTON CO AP [USW00003888], Mableton, GA
(28) MABLETON 1 N [USC00095404], Smyrna, GA

Influencing water features

This ecological site sits high enough above the active flood plain to avoid some of the flooding experienced on lower surfaces. Flooding occurs mainly after a period of unusually wet weather. The heavy rainfall generates saturation-excess runoff, filling rivers and streams, leading to flooding on the higher river valley surfaces. Unless artificial drainage is introduced, a seasonal high water table is apparent at depths between 0 to 12 inches, generally during the months of November to May.

Wetland description

In the reference state, wetlands on this ecological site typically classify as follows according to the Cowardin system (Cowardin 1979).

System: Palustrine
Class: Forested
Subclass: Broad-leaved deciduous

Lower-level Modifiers
Water Regime: Saturated
Water Chemistry: Fresh, acid
Soil: Mineral

Soil features

Soils on this ecological site are typically very deep, poorly drained Ultisols or Alfisols. Under unusually rich conditions, soils may be high in base cations and may meet the criteria for the Mollisol order. Soils on this ecological site are better developed than soils of adjacent flood plains, as they are generally found on more stable surfaces that are more conducive to soil genesis. As such, soils on this ecological site usually have an argillic horizon in subsurface layers. Generally speaking, these soils are in a fine particle size family, although the range of variability includes fine-loamy and fine-silty families. Redoximorphic features (iron and/or manganese depletions) are found at depths between 0 to 12 inches and below. Parent materials are typically old clayey alluvial sediments.

Reaction in the subsoil is typically strongly acid to extremely acid (pH 3.5 to 5.5). Occasionally, it can naturally be closer to neutral under unusually rich site conditions. In the surface layers, reaction varies with land use and management. Under low input or forested conditions, it generally falls somewhere between pH 4.5 and 5.5.

Soils on this ecological site have a thermic soil temperature regime, which is characterized by a mean annual soil temperature of 15°C to 22°C and a winter to summer temperature differential of 6°C or more in the subsoil.

Modal taxa include: Typic Endoaquults
Modal soil series include: Roanoke
Other soils attributed to this ecological site include Armenia, Forestdale, Moncure, Partlow, and Toddstav.

Figure 11. An illustration of a soil profile belonging to the Roanoke series, a representative soil series associated with this ecological site.

Table 5. Representative soil features

Parent material	(1) Alluvium – igneous, metamorphic and sedimentary rock
Surface texture	(1) Loam (2) Silt loam (3) Silty clay loam (4) Fine sandy loam
Family particle size	(1) Fine
Drainage class	Poorly drained
Permeability class	Very slow to slow
Soil depth	80 in
Surface fragment cover <=3"	Not specified
Surface fragment cover >3"	Not specified
Available water capacity (0-80in)	9 – 11 in
Soil reaction (1:1 water) (0-10in)	4.5 – 5.5
Subsurface fragment volume <=3" (0-80in)	6%
Subsurface fragment volume >3" (0-80in)	Not specified

Table 6. Representative soil features (actual values)

Drainage class	Poorly drained
Permeability class	Very slow to moderately slow
Soil depth	80 in
Surface fragment cover <=3"	Not specified
Surface fragment cover >3"	Not specified
Available water capacity (0-80in)	8 – 17 in
Soil reaction (1:1 water) (0-10in)	3.5 – 7.3
Subsurface fragment volume <=3" (0-80in)	12%
Subsurface fragment volume >3" (0-80in)	1%

Ecological dynamics

U.S. National Vegetation Classification (USNVC) associations that are consistent with reference conditions on this ecological site include CEGL007356 Quercus pagoda - Quercus phellos - Quercus lyrata - Quercus michauxii / Chasmanthium latifolium, which is most common in the broad river valleys of Triassic Basins and portions of the lower Piedmont. This association covers two bottomland assemblages identified by Mathews et al. (2011), 'Quercus (phellos, pagoda, michauxii) - Ulmus americana / Ilex decidua / Arisaema triphyllum,' which is representative of examples with a slightly shorter hydroperiod and loamier soils, and 'Quercus lyrata - Fraxinus pennsylvanica / Saururus cernuus,' which is representative of examples with a longer hydroperiod and finer-textured soils. The latter assemblage is likely more representative of this ecological site.

The reference community on this ecological site also overlaps that of Schafale (2012) 'Piedmont Bottomland Forest (Typic Low Subtype),' which was developed based on plot data from the lower Piedmont and Triassic Basins of North Carolina. No USNVC associations are representative of upper Piedmont or Carolina Slate Belt examples, though this ecological site is not very extensive in these areas, as stream terraces tend to be slightly narrower and better drained. (USNVC 2022).

MATURE FORESTS
The reference state supports a closed canopy forest dominated by bottomland oaks, including willow oak (Quercus phellos), overcup oak (Quercus lyrata), and swamp chestnut oak (Quercus michauxii), among others. Overcup oak tends to occupy more of the canopy cover as the length of the hydroperiod increases. Bottomland oaks that require slightly drier site conditions, such as Shumard's oak (Quercus shumardii) and cherrybark oak (Quercus pagoda), are usually scarce or absent. Other characteristic species include green ash (Fraxinus pennsylvanica), American elm (Ulmus americana), red maple (Acer rubrum), sweetgum (Liquidambar styraciflua), winged elm (Ulmus alata), and loblolly pine (Pinus taeda). Upland oaks and hickories are largely absent.

In the subcanopy layer, American hornbeam (Carpinus caroliniana) is usually dominant, as it is in many alluvial settings. Other important species include blackgum (Nyssa sylvatica) and common persimmon (Diospyros virginiana).

Characteristic species of the shrub layer include possumhaw (Ilex decidua), common winterberry (Ilex verticillata), southern arrowwood (Viburnum recognitum, V. dentatum), swamp doghobble (Eubotrys racemosus), and black highbush blueberry (Vaccinium fuscatum), along with several vines. In the broad, coastal plain-like river valleys of Triassic Basins, species with coastal plain affinities may be present, including coral greenbrier (Smilax walteri), American snowbell (Styrax americanus), woodvamp (Decumaria barbara), florida grape (Vitis cinerea var. floridana), laurel greenbrier (Smilax laurifolia) and Elliott's blueberry (Vaccinium elliottii).

The herb layer is variable in composition and is usually sparse. Species that occur with some frequency include Jack in the pulpit (Arisaema triphyllum), lizard's tail (Saururus cernuus), and various species of Carex (C. critina, debilis, tribuloides, typhina, intumescens, lupulina, etc.)

The reference forest type is best developed on the stepped surfaces of relatively broad river valleys. Here, distinct landforms, such as stream terraces, flood plain flats, backswamps, and natural levees, tend to be better developed. In this setting, stream terraces tend to be broader and include more extensive wet areas.

DYNAMICS OF NATURAL SUCCESSION
Successional dynamics on this ecological site are not well-documented. Tree replacement likely takes place in canopy gaps caused by windthrow, disease, and the like, much like on moist uplands of the Piedmont. Flooding presumably plays a relatively minor role. Though fire was historically a key driver of successional dynamics on Piedmont uplands, the influence of fire on this ecological site was likely insignificant.

YOUNG SECONDARY FORESTS
Young secondary forests associated with this ecological site are usually even-aged and comparatively less diverse. These forests are more common on the landscape today due to the long history of agriculture and logging in river valleys of the Southern Piedmont. Typically, these forests are strongly dominated by only a handful of species, of which sweetgum (L. styraciflua) is probably most common overall. The dominance of sweetgum (L. styraciflua) and other early pioneers declines as the forest matures, though many of these species remain important in mature stands as well, albeit to a lesser extent. Other characteristic species of young secondary forests on this ecological site include red maple (Acer rubrum), loblolly pine (Pinus taeda), green ash (Fraxinus pennsylvanica), blackgum (Nyssa sylvatica), and common persimmon (Diospyros virginiana) (Nelson 1986; Wharton 1978; Wharton et al. 1982; Schafale and Weakley 1990; Brinson et al. 1996; Matthews et al. 2011; Schafale 2012a, 2012b; Edwards et al. 2013; Fleming et al. 2021).

SPECIES LIST
Canopy layer: Quercus phellos, Quercus lyrata, Fraxinus pennsylvanica, Ulmus americana, Quercus michauxii, Acer rubrum, Liquidambar styraciflua, Ulmus alata, Pinus taeda,

Subcanopy layer: Carpinus caroliniana, Nyssa sylvatica, Diospyros virginiana, Acer rubrum, Ulmus alata,

Vines/lianas: Bignonia capreolata, Smilax rotundifolia, Parthenocissus quinquefolia, Campsis radicans, Trachelospermum difforme, Vitis rotundifolia, Toxicodendron radicans, Apios americana, Smilax walteri, Decumaria barbara, Lonicera japonica (I)

Shrub layer: Ilex decidua, Ilex verticillata, Viburnum recognitum, Viburnum dentatum, Eubotrys racemosus, Vaccinium fuscatum, Viburnum nudum, Hypericum nudiflorum, Cornus foemina, Rosa palustris, Lyonia ligustrina, Styrax americanus, Aronia arbutifolia

Herb layer - forbs: Arisaema triphyllum, Saururus cernuus, Polygonum virginianum, Woodwardia areolata, Osmunda cinnamomea, Athyrium filix-femina ssp. asplenioides, Mitchella repens, Boehmeria cylindrica, Sphagnum spp., Mnium spp., Thuidium spp., Galium tinctorium, Solidago gigantea, Solidago rugosa, Agrimonia parviflora, Commelina virginica, Impatiens capensis, Pluchea camphorata, Onoclea sensibilis, Thelypteris noveboracensis, Botrychium dissectum, Botrychium biternatum, Pleopeltis polypodioides ssp. michauxiana, Scutellaria integrifolia, Verbesina alternifolia, Lycopus virginicus, Cicuta maculata, Itea virginica, Platanthera spp., Lysimachia nummularia (I), Murdannia keisak (I)

Herb layer - graminoids: Carex (albolutescens, crinita, debilis, tribuloides, typhina, intumescens, lupulina, joori, caroliniana, etc.), Leersia virginica, Glyceria striata, Chasmanthium laxum, Juncus coriaceus, Juncus effusus, Cinna arundinacea, Dichanthelium clandestinum, Microstegium vimineum (I), Arthraxon hispidus (I)

(I) = introduced

State and transition model

More interactive model formats are also available. View Interactive Models
Click on state and transition labels to scroll to the respective text

Ecosystem states

1. Reference State: Low-Bottomland Forest (Wet Variant)

2. Secondary Succession State

T1A	-	Clearcut logging or other large-scale disturbances that cause canopy removal.
T2A	-	Long-term natural succession.

State 2 submodel, plant communities

2.1. Forested Successional Phase

2.2. Shrub-dominated Successional Phase

2.3. Herbaceous Early Successional Phase

2.1A	-	Clearcut logging.
2.2A	-	Natural succession.
2.2B	-	Brush management.
2.3A	-	Natural succession.

State 1
Reference State: Low-Bottomland Forest (Wet Variant)

This mature forest state supports a closed canopy forest dominated by bottomland oaks and other bottomland hardwood species.

Characteristics and indicators. Stands are uneven-aged with at least some old trees present.

Dominant plant species

willow oak (Quercus phellos), tree
overcup oak (Quercus lyrata), tree
green ash (Fraxinus pennsylvanica), tree
American elm (Ulmus americana), tree
swamp chestnut oak (Quercus michauxii), tree
red maple (Acer rubrum), tree
sweetgum (Liquidambar styraciflua), tree
American hornbeam (Carpinus caroliniana), tree
winged elm (Ulmus alata), tree
loblolly pine (Pinus taeda), tree
possumhaw (Ilex decidua), shrub
roundleaf greenbrier (Smilax rotundifolia), shrub
common winterberry (Ilex verticillata), shrub
crossvine (Bignonia capreolata), shrub
Virginia creeper (Parthenocissus quinquefolia), shrub
trumpet creeper (Campsis radicans), shrub
southern arrowwood (Viburnum recognitum), shrub
climbing dogbane (Trachelospermum difforme), shrub
swamp doghobble (Eubotrys racemosus), shrub
black highbush blueberry (Vaccinium fuscatum), shrub
greenwhite sedge (Carex albolutescens), grass
fringed sedge (Carex crinita), grass
white edge sedge (Carex debilis), grass
blunt broom sedge (Carex tribuloides), grass
cattail sedge (Carex typhina), grass
whitegrass (Leersia virginica), grass
fowl mannagrass (Glyceria striata), grass
slender woodoats (Chasmanthium laxum), grass
Jack in the pulpit (Arisaema triphyllum), other herbaceous
lizard's tail (Saururus cernuus), other herbaceous
jumpseed (Polygonum virginianum), other herbaceous
netted chainfern (Woodwardia areolata), other herbaceous
cinnamon fern (Osmunda cinnamomea), other herbaceous
asplenium ladyfern (Athyrium filix-femina ssp. asplenioides), other herbaceous
partridgeberry (Mitchella repens), other herbaceous
stiff marsh bedstraw (Galium tinctorium), other herbaceous
smallspike false nettle (Boehmeria cylindrica), other herbaceous
sphagnum (Sphagnum), other herbaceous

State 2
Secondary Succession State

This successional phase develops in the wake of clearcut logging, storm-related catastrophic tree mortality, or other large-scale disturbances that have led to canopy removal in the recent past. Which species colonize a particular location in the wake of a disturbance does involve a considerable degree of chance. It also depends a great deal on the type, duration, and magnitude of the disturbance event.

Characteristics and indicators. Plant age distribution is usually even.

Community 2.1
Forested Successional Phase

This successional phase develops in the wake of logging, storm-related catastrophic tree mortality, or other large-scale disturbances that have led to canopy removal in the recent past. It is typically dominated by bottomland hardwoods or a mixture of bottomland hardwoods and pines.

Forest overstory. Representative canopy species include include red maple (Acer rubrum), sweetgum (Liquidambar styraciflua) and green ash (Fraxinus pennsylvanica). Species diversity is generally lower than in mature examples. Bottomland oaks are typically scarce in the canopy.

Forest understory. Typical subcanopy species include blackgum (Nyssa sylvatica) and common persimmon (Diospyros virginiana), along with saplings of canopy species. Seedlings of bottomland oaks and other slow growing, shade-tolerant tree species are usually present in the understory. These seedlings are released gradually as the forest matures and successional canopy species die.

The shrub layer is generally sparse, but vines can be abundant. Characteristic vines include roundleaf greenbrier (Smilax rotundifolia), trumpet creeper (Campsis radicans), and Virginia creeper (Parthenocissus quinquefolia), among others.

Dominant plant species

red maple (Acer rubrum), tree
sweetgum (Liquidambar styraciflua), tree
green ash (Fraxinus pennsylvanica), tree
loblolly pine (Pinus taeda), tree
blackgum (Nyssa sylvatica), tree
common persimmon (Diospyros virginiana), tree
willow oak (Quercus phellos), tree
roundleaf greenbrier (Smilax rotundifolia), shrub
trumpet creeper (Campsis radicans), shrub
Virginia creeper (Parthenocissus quinquefolia), shrub
eastern poison ivy (Toxicodendron radicans), shrub
fringed sedge (Carex crinita), grass
white edge sedge (Carex debilis), grass
blunt broom sedge (Carex tribuloides), grass
hop sedge (Carex lupulina), grass
whitegrass (Leersia virginica), grass
deertongue (Dichanthelium clandestinum), grass
leathery rush (Juncus coriaceus), grass
smallspike false nettle (Boehmeria cylindrica), other herbaceous
jewelweed (Impatiens capensis), other herbaceous
creeping jenny (Lysimachia nummularia), other herbaceous
harvestlice (Agrimonia parviflora), other herbaceous
wrinkleleaf goldenrod (Solidago rugosa ssp. rugosa), other herbaceous
wingstem (Verbesina alternifolia), other herbaceous
asplenium ladyfern (Athyrium filix-femina ssp. asplenioides), other herbaceous

Community 2.2
Shrub-dominated Successional Phase

This successional phase is dominated by shrubs and vines, along with seedlings of bottomland hardwoods and pines. It grades into the forested successional phase as tree seedlings become saplings and begin to occupy more of the canopy cover.

Dominant plant species

sweetgum (Liquidambar styraciflua), tree
red maple (Acer rubrum), tree
loblolly pine (Pinus taeda), tree
blackgum (Nyssa sylvatica), tree
common persimmon (Diospyros virginiana), tree
black elderberry (Sambucus nigra), shrub
common buttonbush (Cephalanthus occidentalis), shrub
roundleaf greenbrier (Smilax rotundifolia), shrub
trumpet creeper (Campsis radicans), shrub
eastern baccharis (Baccharis halimifolia), shrub
eastern poison ivy (Toxicodendron radicans), shrub
groundnut (Apios americana), shrub
silky dogwood (Cornus amomum), shrub
leathery rush (Juncus coriaceus), grass
common rush (Juncus effusus), grass
flatsedge (Cyperus), grass
woolgrass (Scirpus cyperinus), grass
deertongue (Dichanthelium clandestinum), grass
trumpetweed (Eutrochium fistulosum), other herbaceous
New York ironweed (Vernonia noveboracensis), other herbaceous
sensitive fern (Onoclea sensibilis), other herbaceous
wrinkleleaf goldenrod (Solidago rugosa ssp. rugosa), other herbaceous
wingstem (Verbesina alternifolia), other herbaceous
asplenium ladyfern (Athyrium filix-femina ssp. asplenioides), other herbaceous
common boneset (Eupatorium perfoliatum), other herbaceous
camphor pluchea (Pluchea camphorata), other herbaceous

Community 2.3
Herbaceous Early Successional Phase

This transient community is composed of the first herbaceous invaders in the aftermath of large-scale natural disturbances that have led to canopy removal. Species composition is highly variable at this stage of succession. In addition to the named species, other herbaceous pioneers common to this ecological site include dwarf St. Johnswort (Hypericum mutilum), wingstem (Verbesina alternifolia), common boneset (Eupatorium perfoliatum), giant goldenrod (Solidago gigantea), wrinkleleaf goldenrod (Solidago rugosa spp. rugosa), butterweed (Packera glabella), herbwilliam (Ptilimnium capillaceum), sharpwing monkeyflower (Mimulus alata), Allegheny monkeyflower (Mimulus ringens), camphor pluchea (Pluchea camphorata), creeping jenny (Lysimachia nummularia), wartremoving herb (Murdannia keisak), and many others.

Resilience management. If the user wishes to maintain this community/phase for wildlife or pollinator habitat, a prescribed burn, mowing, or prescribed grazing will be needed at least once annually to prevent community pathway 2.3A. To that end, as part of long-term maintenance, periodic overseeding of wildlife or pollinator seed mixtures can be helpful in ensuring the viability of certain desired species and maintaining the desired composition of species for user goals.

Dominant plant species

trumpet creeper (Campsis radicans), shrub
greenbrier (Smilax), shrub
rush (Juncus), grass
sedge (Carex), grass
flatsedge (Cyperus), grass
woolgrass (Scirpus cyperinus), grass
small carpetgrass (Arthraxon hispidus), grass
spikerush (Eleocharis), grass
beaksedge (Rhynchospora), grass
barnyardgrass (Echinochloa crus-galli), grass
beggarticks (Bidens), other herbaceous
jewelweed (Impatiens capensis), other herbaceous
stiff marsh bedstraw (Galium tinctorium), other herbaceous
smallspike false nettle (Boehmeria cylindrica), other herbaceous
Virginia water horehound (Lycopus virginicus), other herbaceous
Virginia buttonweed (Diodia virginiana), other herbaceous
knotweed (Polygonum), other herbaceous
golden ragwort (Packera aurea), other herbaceous
smooth white oldfield aster (Symphyotrichum racemosum), other herbaceous
calico aster (Symphyotrichum lateriflorum), other herbaceous

Pathway 2.1A
Community 2.1 to 2.3

The forested successional phase can return to the herbaceous early successional phase through clearcut logging or other large-scale disturbances that cause canopy removal.

Pathway 2.2A
Community 2.2 to 2.1

The shrub-dominated successional phase naturally moves towards the forested successional phase through natural succession.

Pathway 2.2B
Community 2.2 to 2.3

The shrub-dominated successional phase can return to the herbaceous early successional phase through brush management, including herbicide application, mechanical removal, prescribed grazing, or fire.

Context dependence. Note: if the user wishes to use this community pathway to create wildlife or pollinator habitat, please contact a local NRCS office for a species list specific to the area of interest and user needs. If the user wishes to maintain the shrub-dominated successional phase long term, for wildlife habitat or other uses, periodic use of this community pathway is necessary to prevent community pathway 2.2A, which happens inevitably unless natural succession is set back through disturbance.

Pathway 2.3A
Community 2.3 to 2.2

The herbaceous early successional phase naturally moves towards the shrub-dominated successional phase through natural succession.

Transition T1A
State 1 to 2

The reference state can transition to the secondary succession state through clearcut logging or other large-scale disturbances that cause canopy removal.

Transition T2A
State 2 to 1

The secondary succession state can transition to the reference state through long-term natural succession.

Additional community tables

Supporting information

Inventory data references

Data collection and analysis of field data will be performed during the Verification Stage of ESD development.

Other references

Brinson, M.M., W.L. Nutter, R. Rheinhardt, B. Pruitt. 1996. Background and recommendations for establishing reference wetlands in the Piedmont of the Carolinas and Georgia. EPA/600/R-96/057. United States Environmental Protection Agency. National Health Environmental Effects Research Laboratory. Corvallis, OR.

Cleland, D.T., J.A. Freeouf, J.E. Keys, G.J. Nowacki, C.A. Carpenter, W.H. McNab. 2007. Ecological Subregions: Sections and Subsections for the conterminous United States. General Technical Report WO-76D. U.S. Department of Agriculture, Forest Service. Washington, D.C.

Cowardin, L.M. 1979. Classification of wetlands and deepwater habitats of the United States. Washington, D.C., Fish and Wildlife Service, U.S. Dept. of the Interior.

Daniels, R.B. 1987. Soil Erosion and Degradation in the Southern Piedmont of the USA. In: M.G. Wolman, F.G.A. Fournier (eds.) Land Transformation in Agriculture. John Wiley and Sons. New York, NY.

Dearman, T.L., L.A. James. 2019. Patterns of legacy sediment deposits in a small South Carolina Piedmont catchment, USA. Geomorphology. 343(15):1-14.

Environmental Protection Agency (EPA). 2013. Level III and IV ecoregions of the continental
United States. National Health and Environmental Effects Research Laboratory. Corvallis, Oregon. Map scale 1:3,000,000.

Edwards, L., J., Ambrose, and L.K. Kirkman. 2013. Piedmont Ecoregion. In L. Edwards et al. (ed.) The natural communities of Georgia. University of Georgia Press, Athens, GA. 257-345.

Fenneman, N.M., Johnson D.W. 1946. Physiographic Divisions of the Conterminous U.S. U.S. Geological Survey. Washington, DC.

Fleming, G. P., K. D. Patterson, and K. Taverna. 2021. The natural communities of Virginia: A classification of ecological community groups and community types. Third approximation. Version 3.3. Virginia Department of Conservation and Recreation, Division of Natural Heritage, Richmond, VA. [http://www.dcr.virginia.gov/natural-heritage/natural-communities/]

Griffith, G.E., J.M. Omernik, J.A. Comstock, M.P. Schafale, W.H. McNab, D.R. Lenat, T.F. MacPherson, J.B. Glover, V.B. Shelburne. 2002. Ecoregions of North Carolina and South Carolina. United States Geological Survey. Reston, Virginia.

Matthews, E.M., R.K. Peet and A.S. Weakley. 2011. Classification and description of alluvial plant communities of the Piedmont region. North Carolina, U.S.A. Applied Vegetation Science. 14:485-505.

Mulholland, P., D. Lenat. 1992. Streams of the southeastern piedmont, Atlantic drainage. In: C.T. Hackney, S. Marshall Adams, W.A. Martin (eds.) Biodiversity of the Southeastern United States - Aquatic Communities. John Wiley & Sons, Inc. Hoboken, NJ.

Nelson, J.B. 1986. The natural communities of South Carolina: Initial classification and description. South Carolina Wildlife and Marine Resources Department, Division of Wildlife and Freshwater Fisheries. Columbia, SC.

Schafale, M.P. 2012a. Classification of the natural communities of North Carolina, 4th Approximation. North Carolina Department of Environment, Health, and Natural Resources, Division of Parks and Recreation. Natural Heritage Program. Raleigh, NC.

Schafale, M.P. 2012b. Guide to the Natural Communities of North Carolina. 4th Approximation. North Carolina Department of Environment, Health, and Natural Resources, Division of Parks and Recreation. Natural Heritage Program. Raleigh, NC.

Schafale, M.P., A.S. Weakley. 1990. Classification of the natural communities of North Carolina. Third approximation. North Carolina Department of Environment, Health, and Natural Resources, Division of Parks and Recreation, Natural Heritage Program. Raleigh, NC.

Schoeneberger, P.J., Wysocki, D.A. 2017. Geomorphic Description System, Version 5.0. United States Department of Agriculture, Natural Resources Conservation Service, National Soil Survey Center. Lincoln, NE.

Schomberg, H., G. Hoyt, B. Brock, G. Naderman. A. Meijer. 2020. Southern Piedmont Case Studies. In: J. Bergtold, M. Sailus (eds.) Conservation Tillage Systems in the Southeast. Sustainable Agriculture Research and Education (SARE) program.

Spira, T.P. 2011. Wildflowers & Plant Communities of the Southern Appalachian Mountains and Piedmont. A naturalist’s guide to the Carolinas, Virginia, Tennessee, and Georgia. The University of North Carolina Press. Chapel Hill, NC.

Trimble, S.W. 1974. Man-Induced Soil Erosion on the Southern Piedmont, 1700–1970. Soil Conservation Society of America. Ankeny, IA.

United States Department of Agriculture, Natural Resources Conservation Service. 2022. Land resource regions and major land resource areas of the United States, the Caribbean, and the Pacific Basin. U.S. Department of Agriculture, Agriculture Handbook 296.

United States National Vegetation Classification (USNVC) Database Version 2.04. 2022. Federal Geographic Data Committee, Vegetation Subcommittee. Washington, DC. Available at https://usnvc.org.

Van Lear, D.H, R.A. Harper, P.R. Kapeluck, and W.D. Carroll. 2004. History of Piedmont Forests: Implications for Current Pine Management. General Technical Report SRS–71. U.S. Department of Agriculture, Forest Service, Southern Research Station. Asheville, NC.

Weakley, A.S., and Southeastern Flora Team. 2023. Flora of the southeastern United States. University of North Carolina Herbarium, North Carolina Botanical Garden, Chapel Hill, NC.

Wharton, C.H. 1978. Natural environments of Georgia. Georgia Department of Natural Resources. Atlanta, Georgia.

Wharton, C.H., W.M. Kitchens, E.C. Pendleton, T.W. Sipe. 1982. The ecology of bottomland hardwood swamps of the Southeast: a community profile. U.S. Fish and Wildlife Service, Biological Services Program. Washington, DC. FWS/OBS-81/37.

Zinck, J.A. 2016. The Geopedologic Approach. In: J.A Zinck, G. Metternicht, G. Bocco, H.F. Del Valle (eds.) Geopedology. Springer, Cham.

Contributors

Yogev Erez
Dee Pederson

Approval

Charles Stemmans, 5/02/2025

Rangeland health reference sheet

Interpreting Indicators of Rangeland Health is a qualitative assessment protocol used to determine ecosystem condition based on benchmark characteristics described in the Reference Sheet. A suite of 17 (or more) indicators are typically considered in an assessment. The ecological site(s) representative of an assessment location must be known prior to applying the protocol and must be verified based on soils and climate. Current plant community cannot be used to identify the ecological site.

Author(s)/participant(s)
Contact for lead author
Date	05/03/2025
Approved by	Charles Stemmans
Approval date
Composition (Indicators 10 and 12) based on	Annual Production

Indicators

Number and extent of rills:
Presence of water flow patterns:
Number and height of erosional pedestals or terracettes:
Bare ground from Ecological Site Description or other studies (rock, litter, lichen, moss, plant canopy are not bare ground):
Number of gullies and erosion associated with gullies:
Extent of wind scoured, blowouts and/or depositional areas:
Amount of litter movement (describe size and distance expected to travel):
Soil surface (top few mm) resistance to erosion (stability values are averages - most sites will show a range of values):
Soil surface structure and SOM content (include type of structure and A-horizon color and thickness):
Effect of community phase composition (relative proportion of different functional groups) and spatial distribution on infiltration and runoff:
Presence and thickness of compaction layer (usually none; describe soil profile features which may be mistaken for compaction on this site):
Functional/Structural Groups (list in order of descending dominance by above-ground annual-production or live foliar cover using symbols: >>, >, = to indicate much greater than, greater than, and equal to):

Dominant:

Sub-dominant:

Other:

Additional:
Amount of plant mortality and decadence (include which functional groups are expected to show mortality or decadence):
Average percent litter cover (%) and depth ( in):
Expected annual annual-production (this is TOTAL above-ground annual-production, not just forage annual-production):
Potential invasive (including noxious) species (native and non-native). List species which BOTH characterize degraded states and have the potential to become a dominant or co-dominant species on the ecological site if their future establishment and growth is not actively controlled by management interventions. Species that become dominant for only one to several years (e.g., short-term response to drought or wildfire) are not invasive plants. Note that unlike other indicators, we are describing what is NOT expected in the reference state for the ecological site:
Perennial plant reproductive capability: