HomeMy WebLinkAboutSDP201400005 Assessment - Environmental 2014-01-22 Thomas Jefferson Soil and Water Conservation
" «M District
„• 706G Forest Street, Charlottesville, VA 22903
" Tel: (434) 975-0224 Fax: (434) 975-1367
Web Page: www.tjswcd.org
Louisa Office: 39 Industrial Dr, Louisa, VA 23093
Phone: 540-967-5940 Fax: 540-967-2557
To: Planning Dept—Albemarle County
ATTN: Ellie Ray
Date: February 7, 2014
From:Debris Bradshaw
Re: Soils Report
Soils Report for:
Riverside Village
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Soil Map—Albemarle County,Virginia Riverside Village
Map Unit Legend
Albemarle County,Virginia(VA003)
Map Unit Symbol Map Unit Name Acres in AOM Percent of AOI
12C Catoctin silt loam,7 to 15 5.5 29.9%
percent slopes
12D Catoctin silt loam, 15 to 25 0.2 1.2%
percent slopes
71B Rabun clay loam,2 to 7 percent 4.9 26.4%
slopes
71C Rabun clay loam,7 to 15 3.4 18.6%
percent slopes
76 Riverview loam 3.1 16.6%
79B Starr silt loam,2 to 7 percent 1.3 7.2%
slopes
Totals for Area of Interest 18.5 100.0%
USDA Natural Resources Web Soil Survey 2/7/2014
"Mu Conservation Service National Cooperative Soil Survey Page 3 of 3
Now, Nos"
Map Unit Description(Brief,Generated)---Albemarle County,Virginia Riverside Village
Map Unit Description (Brief, Generated)
The map units delineated on the detailed soil maps in a soil survey represent the
soils or miscellaneous areas in the survey area.The map unit descriptions in this
report, along with the maps, can be used to determine the composition and
properties of a unit.
A map unit delineation on a soil map represents an area dominated by one or more
major kinds of soil or miscellaneous areas.A map unit is identified and named
according to the taxonomic classification of the dominant soils.Within a taxonomic
class there are precisely defined limits for the properties of the soils. On the
landscape, however,the soils are natural phenomena, and they have the
characteristic variability of all natural phenomena. Thus,the range of some
observed properties may extend beyond the limits defined for a taxonomic class.
Areas of soils of a single taxonomic class rarely, if ever, can be mapped without
including areas of other taxonomic classes. Consequently, every map unit is made
up of the soils or miscellaneous areas for which it is named and some minor
components that belong to taxonomic classes other than those of the major soils.
The Map Unit Description (Brief, Generated)report displays a generated
description of the major soils that occur in a map unit. Descriptions of non-soil
(miscellaneous areas)and minor map unit components are not included. This
description is generated from the underlying soil attribute data.
Additional information about the map units described in this report is available in
other Soil Data Mart reports,which give properties of the soils and the limitations,
capabilities,and potentials for many uses.Also,the narratives that accompany the
Soil Data Mart reports define some of the properties included in the map unit
descriptions.
Report—Map Unit Description (Brief, Generated)
Albemarle County, Virginia
Map Unit: 12C—Catoctin silt loam, 7 to 15 percent slopes
Component: Catoctin (80%)
The Catoctin component makes up 80 percent of the map unit. Slopes are 7 to 15
percent.This component is on hillslopes, piedmonts.The parent material consists
of residuum weathered from greenstone. Depth to a root restrictive layer, bedrock,
lithic, is 20 to 40 inches. The natural drainage class is well drained. Water
movement in the most restrictive layer is high.Available water to a depth of 60
inches is low. Shrink-swell potential is low.This soil is not flooded. It is not ponded.
There is no zone of water saturation within a depth of 72 inches. Organic matter
content in the surface horizon is about 1 percent. Nonirrigated land capability
classification is 3e. This soil does not meet hydric criteria.
Map Unit: 12D—Catoctin silt loam, 15 to 25 percent slopes
USDA Natural Resources Web Soil Survey 2/7/2014
;10111 Conservation Service National Cooperative Soil Survey Page 1 of 3
•
err+ "S
Map Unit Description(Brief,Generated)--Albemarle County,Virginia Riverside Village
Component: Catoctin (80%)
The Catoctin component makes up 80 percent of the map unit. Slopes are 15 to 25
percent. This component is on hillslopes, piedmonts.The parent material consists
of residuum weathered from greenstone. Depth to a root restrictive layer, bedrock,
lithic, is 20 to 40 inches. The natural drainage class is well drained. Water
movement in the most restrictive layer is high.Available water to a depth of 60
inches is low.Shrink-swell potential is low.This soil is not flooded. It is not ponded.
There is no zone of water saturation within a depth of 72 inches. Organic matter
content in the surface horizon is about 1 percent. Nonirrigated land capability
classification is 4e. This soil does not meet hydric criteria.
Map Unit: 71 B—Rabun clay loam, 2 to 7 percent slopes
Component: Rabun (80%)
The Rabun component makes up 80 percent of the map unit. Slopes are 2 to 7
percent.This component is on uplands, interfluves.The parent material consists of
residuum weathered from greenstone. Depth to a root restrictive layer is greater
than 60 inches.The natural drainage class is well drained.Water movement in the
most restrictive layer is moderately high.Available water to a depth of 60 inches is
moderate. Shrink-swell potential is low.This soil is not flooded. It is not ponded.
There is no zone of water saturation within a depth of 72 inches. Organic matter
content in the surface horizon is about 2 percent. Nonirrigated land capability
classification is 2e. This soil does not meet hydric criteria.
Map Unit: 71C—Rabun clay loam, 7 to 15 percent slopes
Component: Rabun (80%)
The Rabun component makes up 80 percent of the map unit. Slopes are 7 to 15
percent.This component is on uplands, interfluves.The parent material consists of
residuum weathered from greenstone. Depth to a root restrictive layer is greater
than 60 inches.The natural drainage class is well drained.Water movement in the
most restrictive layer is moderately high.Available water to a depth of 60 inches is
moderate. Shrink-swell potential is low. This soil is not flooded. It is not ponded.
There is no zone of water saturation within a depth of 72 inches. Organic matter
content in the surface horizon is about 2 percent. Nonirrigated land capability
classification is 6e.This soil does not meet hydric criteria.
Map Unit: 76—Riverview loam
Component: Riverview(75%)
USDA Natural Resources Web Soil Survey 2/7/2014
"111111 Conservation Service National Cooperative Soil Survey Page 2 of 3
'roof Nome
Map Unit Description(Brief,Generated)--Albemarle County,Virginia Riverside Village
The Riverview component makes up 75 percent of the map unit. Slopes are 0 to 2
percent. This component is on river valleys, flood plains. The parent material
consists of alluvium derived from igneous rock. Depth to a root restrictive layer is
greater than 60 inches.The natural drainage class is well drained.Water movement
in the most restrictive layer is moderately high.Available water to a depth of 60
inches is moderate. Shrink-swell potential is low. This soil is occasionally flooded.
It is not ponded.A seasonal zone of water saturation is at 48 inches during January,
February,March,December.Organic matter content in the surface horizon is about
1 percent. Nonirrigated land capability classification is 2w. This soil does not meet
hydric criteria.
Component: Wehadkee (3%)
Generated brief soil descriptions are created for major components.The Wehadkee
soil is a minor component.
Map Unit: 79B—Starr silt loam, 2 to 7 percent slopes
Component: Starr(80%)
The Starr component makes up 80 percent of the map unit. Slopes are 2 to 7
percent. This component is on drainageways, uplands. The parent material
consists of colluvium derived from igneous rock. Depth to a root restrictive layer is
greater than 60 inches.The natural drainage class is well drained.Water movement
in the most restrictive layer is moderately high.Available water to a depth of 60
inches is high. Shrink-swell potential is moderate.This soil is occasionally flooded.
It is not ponded. There is no zone of water saturation within a depth of 72 inches.
Organic matter content in the surface horizon is about 1 percent. Nonirrigated land
capability classification is 2e. This soil does not meet hydric criteria.
Data Source Information
Soil Survey Area: Albemarle County,Virginia
Survey Area Data: Version 10, Dec 11, 2013
USDA Natural Resources Web Soil Survey 2/7/2014
—milli Conservation Service National Cooperative Soil Survey Page 3 of 3
Noe
Dwellings and Small Commercial Buildings--Albemarle County,Virginia Riverside Village
Dwellings and Small Commercial Buildings
Soil properties influence the development of building sites, including the selection
of the site,the design of the structure,construction,performance after construction,
and maintenance.This table shows the degree and kind of soil limitations that affect
dwellings and small commercial buildings.
The ratings in the table are both verbal and numerical. Rating class terms indicate
the extent to which the soils are limited by all of the soil features that affect building
site development. Not limited indicates that the soil has features that are very
favorable for the specified use. Good performance and very low maintenance can
be expected. Somewhat limited indicates that the soil has features that are
moderately favorable for the specified use. The limitations can be overcome or
minimized by special planning, design, or installation. Fair performance and
moderate maintenance can be expected. Very limited indicates that the soil has
one or more features that are unfavorable for the specified use.The limitations
generally cannot be overcome without major soil reclamation, special design, or
expensive installation procedures. Poor performance and high maintenance can
be expected.
Numerical ratings in the table indicate the severity of individual limitations. The
ratings are shown as decimal fractions ranging from 0.01 to 1.00. They indicate
gradations between the point at which a soil feature has the greatest negative
impact on the use(1.00)and the point at which the soil feature is not a limitation
(0.00).
Dwellings are single-family houses of three stories or less. For dwellings without
basements, the foundation is assumed to consist of spread footings of reinforced
concrete built on undisturbed soil at a depth of 2 feet or at the depth of maximum
frost penetration,whichever is deeper. For dwellings with basements, the
foundation is assumed to consist of spread footings of reinforced concrete built on
undisturbed soil at a depth of about 7 feet. The ratings for dwellings are based on
the soil properties that affect the capacity of the soil to support a load without
movement and on the properties that affect excavation and construction costs.The
properties that affect the load-supporting capacity include depth to a water table,
ponding, flooding, subsidence, linear extensibility(shrink-swell potential), and
compressibility. Compressibility is inferred from the Unified classification. The
properties that affect the ease and amount of excavation include depth to a water
table, ponding,flooding, slope, depth to bedrock or a cemented pan, hardness of
bedrock or a cemented pan, and the amount and size of rock fragments.
Small commercial buildings are structures that are less than three stories high and
do not have basements. The foundation is assumed to consist of spread footings
of reinforced concrete built on undisturbed soil at a depth of 2 feet or at the depth
of maximum frost penetration, whichever is deeper. The ratings are based on the
soil properties that affect the capacity of the soil to support a load without movement
and on the properties that affect excavation and construction costs.The properties
that affect the load-supporting capacity include depth to a water table, ponding,
flooding, subsidence, linear extensibility(shrink-swell potential), and
compressibility(which is inferred from the Unified classification).The properties that
affect the ease and amount of excavation include flooding, depth to a water table,
ponding, slope, depth to bedrock or a cemented pan, hardness of bedrock or a
cemented pan, and the amount and size of rock fragments.
USDA Natural Resources Web Soil Survey 2/7/2014
'Ill. Conservation Service National Cooperative Soil Survey Page 1 of 3
**me Ione
Dwellings and Small Commercial Buildings---Albemarle County,Virginia Riverside Village
Information in this table is intended for land use planning,for evaluating land use
alternatives, and for planning site investigations prior to design and construction.
The information, however, has limitations. For example, estimates and other data
generally apply only to that part of the soil between the surface and a depth of 5 to
7 feet. Because of the map scale, small areas of different soils may be included
within the mapped areas of a specific soil.
The information is not site specific and does not eliminate the need for onsite
investigation of the soils or for testing and analysis by personnel experienced in the
design and construction of engineering works.
Government ordinances and regulations that restrict certain land uses or impose
specific design criteria were not considered in preparing the information in this table.
Local ordinances and regulations should be considered in planning, in site
selection, and in design.
Report—Dwellings and Small Commercial Buildings
[Onsite investigation may be needed to validate the interpretations in this table and
to confirm the identity of the soil on a given site.The numbers in the value columns
range from 0.01 to 1.00.The larger the value,the greater the potential limitation.
The table shows only the top five limitations for any given soil. The soil may have
additional limitations]
Dwellings and Small Commercial Buildings–Albemarle County,Virginia
Map symbol and soil Pct.of Dwellings without basements Dwellings with basements Small commercial buildings
name map
unit Rating class and Value Rating class and Value Rating class and Value
limiting features limiting features limiting features
12C—Catoctin silt
loam,7 to 15
percent slopes
Catoctin 80 Somewhat limited Very limited Very limited
Depth to hard bedrock 0.64 Depth to hard bedrock 1.00 Slope 1.00
Slope 0.37 Slope 0.37 Depth to hard bedrock 0.64
12D—Catoctin silt
loam, 15 to 25
percent slopes
Catoctin 80 Very limited Very limited Very limited
Slope 1.00 Slope 1.00 Slope 1.00
Depth to hard bedrock 0.64 Depth to hard bedrock 1.00 Depth to hard bedrock 0.64
71B—Rabun clay
loam,2 to 7 percent I
slopes
------ ---------
Rabun 80 Not limited Not limited Somewhat limited
Slope j 0.13
USDA Natural Resources Web Soil Survey 2/7/2014
"111.111 Conservation Service National Cooperative Soil Survey Page 2 of 3
Dwellings and Small Commercial Buildings---Albemarle County,Virginia Riverside Village
Dwellings and Small Commercial Buildings-Albemarle County,Virginia
Map symbol and soil Pct.of Dwellings without basements Dwellings with basements Small commercial buildings
name map
unit Rating class and Value Rating class and Value Rating class and Value
limiting features limiting features limiting features
71C—Rabun clay
loam,7 to 15
percent slopes
Rabun 80 Somewhat limited Somewhat limited Very limited
Slope 0.37 Slope 0.37 Slope 1.00
76—Riverview loam
Riverview 75 Very limited Very limited Very limited
Flooding 1.00 Flooding 1.00 Flooding 1.00
Depth to saturated 0.61
zone 1
79B—Starr silt loam,2
to 7 percent slopes
Starr 80 Very limited Very limited Very limited
Flooding 1.00 Flooding 1.00 Flooding 1.00
Shrink-swell 0.50 Shrink-swell 0.28 Shrink-swell 0.50
Slope 0.13
Data Source Information
Soil Survey Area: Albemarle County,Virginia
Survey Area Data: Version 10, Dec 11, 2013
USDA Natural Resources Web Soil Survey 2/7/2014
'gill. Conservation Service National Cooperative Soil Survey Page 3 of 3
Noe Ns/
Roads and Streets,Shallow Excavations,and Lawns and Landscaping---Albemarle County, Riverside Village
Virginia
Roads and Streets, Shallow Excavations, and Lawns and
Landscaping
Soil properties influence the development of building sites, including the selection
of the site,the design of the structure,construction,performance after construction,
and maintenance.This table shows the degree and kind of soil limitations that affect
local roads and streets, shallow excavations, and lawns and landscaping.
The ratings in the table are both verbal and numerical. Rating class terms indicate
the extent to which the soils are limited by all of the soil features that affect building
site development. Not limited indicates that the soil has features that are very
favorable for the specified use. Good performance and very low maintenance can
be expected. Somewhat limited indicates that the soil has features that are
moderately favorable for the specified use. The limitations can be overcome or
minimized by special planning, design, or installation. Fair performance and
moderate maintenance can be expected. Very limited indicates that the soil has
one or more features that are unfavorable for the specified use. The limitations
generally cannot be overcome without major soil reclamation, special design, or
expensive installation procedures. Poor performance and high maintenance can
be expected.
Numerical ratings in the table indicate the severity of individual limitations. The
ratings are shown as decimal fractions ranging from 0.01 to 1.00. They indicate
gradations between the point at which a soil feature has the greatest negative
impact on the use (1.00)and the point at which the soil feature is not a limitation
(0.00).
Local roads and streets have an all-weather surface and carry automobile and light
truck traffic all year.They have a subgrade of cut or fill soil material;a base of gravel,
crushed rock,or soil material stabilized by lime or cement;and a surface of flexible
material(asphalt), rigid material(concrete),or gravel with a binder.The ratings are
based on the soil properties that affect the ease of excavation and grading and the
traffic-supporting capacity.The properties that affect the ease of excavation and
grading are depth to bedrock or a cemented pan, hardness of bedrock or a
cemented pan, depth to a water table, ponding,flooding, the amount of large
stones,and slope.The properties that affect the traffic-supporting capacity are soil
strength (as inferred from the AASHTO group index number), subsidence, linear
extensibility(shrink-swell potential),the potential for frost action, depth to a water
table, and ponding.
Shallow excavations are trenches or holes dug to a maximum depth of 5 or 6 feet
for graves, utility lines, open ditches, or other purposes. The ratings are based on
the soil properties that influence the ease of digging and the resistance to sloughing.
Depth to bedrock or a cemented pan, hardness of bedrock or a cemented pan,the
amount of large stones, and dense layers influence the ease of digging,filling, and
compacting. Depth to the seasonal high water table,flooding, and ponding may
restrict the period when excavations can be made. Slope influences the ease of
using machinery. Soil texture, depth to the water table, and linear extensibility
(shrink-swell potential) influence the resistance to sloughing.
USDA Natural Resources Web Soil Survey 2/7/2014
' Conservation Service National Cooperative Soil Survey Page 1 of 4
Roads and Streets,Shallow Excavations,and Lawns and Landscaping--Albemarle County, Riverside Village
Virginia
Lawns and landscaping require soils on which turf and ornamental trees and shrubs
can be established and maintained. Irrigation is not considered in the ratings. The
ratings are based on the soil properties that affect plant growth and trafficability
after vegetation is established.The properties that affect plant growth are reaction;
depth to a water table; ponding; depth to bedrock or a cemented pan;the available
water capacity in the upper 40 inches; the content of salts, sodium, or calcium
carbonate; and sulfidic materials. The properties that affect trafficability are
flooding,depth to a water table,ponding,slope,stoniness,and the amount of sand,
clay, or organic matter in the surface layer.
Information in this table is intended for land use planning,for evaluating land use
alternatives, and for planning site investigations prior to design and construction.
The information, however, has limitations. For example, estimates and other data
generally apply only to that part of the soil between the surface and a depth of 5 to
7 feet. Because of the map scale, small areas of different soils may be included
within the mapped areas of a specific soil.
The information is not site specific and does not eliminate the need for onsite
investigation of the soils or for testing and analysis by personnel experienced in the
design and construction of engineering works.
Government ordinances and regulations that restrict certain land uses or impose
specific design criteria were not considered in preparing the information in this table.
Local ordinances and regulations should be considered in planning, in site
selection, and in design.
Report—Roads and Streets, Shallow Excavations, and Lawns
and Landscaping
[Onsite investigation may be needed to validate the interpretations in this table and
to confirm the identity of the soil on a given site.The numbers in the value columns
range from 0.01 to 1.00. The larger the value,the greater the potential limitation.
The table shows only the top five limitations for any given soil. The soil may have
additional limitations]
Roads and Streets,Shallow Excavations,and Lawns and Landscaping—Albemarle County,Virginia
Map symbol and soil Pct.of Local roads and streets Shallow excavations Lawns and landscaping
name map
unit Rating class and Value Rating class and Value Rating class and Value
limiting features limiting features limiting features
12C—Catoctin silt
loam,7 to 15
percent slopes
Catoctin 80 Somewhat limited Very limited Somewhat limited
Depth to hard bedrock 0.64 Depth to hard bedrock 1.00 Low exchange 0.75
capacity
Frost action 0.50 Slope 0.37 Depth to bedrock 0.65
Slope 0.37 Dusty 0.07 Slope 0.37
Unstable excavation 0.01 Droughty 0.16
walls
-- - -- - — Dusty 0.07
USDA Natural Resources Web Soil Survey 2/7/2014
"'i" Conservation Service National Cooperative Soil Survey Page 2 of 4
Nose Noy'
Roads and Streets,Shallow Excavations,and Lawns and Landscaping---Albemarle County, Riverside Village
Virginia
Roads and Streets,Shallow Excavations,and Lawns and Landscaping-Albemarle County,Virginia
Map symbol and soil Pct.of Local roads and streets Shallow excavations Lawns and landscaping
name map
unit Rating class and Value Rating class and Value Rating class and Value
limiting features limiting features limiting features
12D-Catoctin silt
loam,15 to 25
percent slopes
Catoctin 80 Very limited Very limited Very limited
Slope 1.00 Depth to hard bedrock 1.00 Slope 1.00
Depth to hard bedrock 0.64 Slope 1.00 Low exchange 0.75
capacity
Frost action 0.50 Dusty 0.07 Depth to bedrock 0.65
Unstable excavation 0.01 Droughty 0.16
walls
Dusty 0.07
71B-Rabun clay
loam,2 to 7 percent
slopes
Rabun 80 Very limited Somewhat limited Somewhat limited
Low strength 1.00 Too clayey 0.97 Low exchange 0.75
capacity
Frost action 0.50 Dusty 0.07 Too clayey 0.50
Unstable excavation 0.01 Dusty 0.07
walls
71C-Rabun clay
loam,7 to 15
percent slopes
Rabun 80 Very limited Somewhat limited Somewhat limited
Low strength 1.00 Too clayey 0.97 Too clayey 0.50
Frost action 0.50 Slope 0.37 Slope 0.37
Slope 0.37 Dusty 0.07 Dusty 0.07
Unstable excavation 0.01
walls
76-Riverview loam
Riverview 75 Very limited Somewhat limited Somewhat limited
Flooding 1.00 Depth to saturated 0.61 Low exchange 0.75
zone capacity
Low strength 0.78 Flooding 0.60 Flooding 0.60
Dusty 0.06 Dusty 0.06
Unstable excavation 0.01
walls
USDA Natural Resources Web Soil Survey 2/7/2014
alio- Conservation Service National Cooperative Soil Survey Page 3 of 4
'firere `41110
Roads and Streets,Shallow Excavations,and Lawns and Landscaping---Albemarle County, Riverside Village
Virginia
Roads and Streets,Shallow Excavations,and Lawns and Landscaping—Albemarle County,Virginia
Map symbol and soil Pct.of Local roads and streets Shallow excavations Lawns and landscaping
name map
unit Rating class and Value Rating class and Value Rating class and Value
limiting features limiting features limiting features
79B—Starr silt loam,2
to 7 percent slopes
Starr 80 Very limited Somewhat limited Somewhat limited
Flooding 1.00 Flooding 0.60 Low exchange 0.75
capacity
Low strength 0.78 Dusty 0.08 Flooding 0.60
Shrink-swell 0.50 Unstable excavation 0.01 Dusty 0.08
walls
Data Source Information
Soil Survey Area: Albemarle County, Virginia
Survey Area Data: Version 10, Dec 11, 2013
USDA Natural Resources Web Soil Survey 2/7/2014
: Conservation Service National Cooperative Soil Survey Page 4 of 4
w '.,.,i
Sewage Disposal--Albemarle County,Virginia Riverside Village
Sewage Disposal
This table shows the degree and kind of soil limitations that affect septic tank
absorption fields and sewage lagoons.The ratings are both verbal and numerical.
Rating class terms indicate the extent to which the soils are limited by all of the soil
features that affect these uses. Not limited indicates that the soil has features that
are very favorable for the specified use. Good performance and very low
maintenance can be expected. Somewhat limited indicates that the soil has
features that are moderately favorable for the specified use.The limitations can be
overcome or minimized by special planning, design, or installation. Fair
performance and moderate maintenance can be expected. Very limited indicates
that the soil has one or more features that are unfavorable for the specified use.
The limitations generally cannot be overcome without major soil reclamation,
special design, or expensive installation procedures. Poor performance and high
maintenance can be expected.
Numerical ratings in the table indicate the severity of individual limitations. The
ratings are shown as decimal fractions ranging from 0.01 to 1.00. They indicate
gradations between the point at which a soil feature has the greatest negative
impact on the use (1.00)and the point at which the soil feature is not a limitation
(0.00).
Septic tank absorption fields are areas in which effluent from a septic tank is
distributed into the soil through subsurface tiles or perforated pipe. Only that part
of the soil between depths of 24 and 72 inches or between a depth of 24 inches
and a restrictive layer is evaluated.The ratings are based on the soil properties that
affect absorption of the effluent, construction and maintenance of the system, and
public health. Saturated hydraulic conductivity(Ksat), depth to a water table,
ponding,depth to bedrock or a cemented pan,and flooding affect absorption of the
effluent. Stones and boulders, ice, and bedrock or a cemented pan interfere with
installation. Subsidence interferes with installation and maintenance. Excessive
slope may cause lateral seepage and surfacing of the effluent in downslope areas.
Some soils are underlain by loose sand and gravel or fractured bedrock at a depth
of less than 4 feet below the distribution lines. In these soils the absorption field
may not adequately filter the effluent, particularly when the system is new. As a
result, the ground water may become contaminated.
Sewage lagoons are shallow ponds constructed to hold sewage while aerobic
bacteria decompose the solid and liquid wastes. Lagoons should have a nearly
level floor surrounded by cut slopes or embankments of compacted soil. Nearly
impervious soil material for the lagoon floor and sides is required to minimize
seepage and contamination of ground water. Considered in the ratings are slope,
saturated hydraulic conductivity(Ksat), depth to a water table, ponding, depth to
bedrock or a cemented pan,flooding, large stones, and content of organic matter.
USDA Natural Resources Web Soil Survey 2/7/2014
''� Conservation Service National Cooperative Soil Survey Page 1 of 3
'fir► "W
Sewage Disposal---Albemarle County,Virginia Riverside Village
Saturated hydraulic conductivity(Ksat)is a critical property affecting the suitability
for sewage lagoons. Most porous soils eventually become sealed when they are
used as sites for sewage lagoons. Until sealing occurs, however, the hazard of
pollution is severe. Soils that have a Ksat rate of more than 14 micrometers per
second are too porous for the proper functioning of sewage lagoons. In these soils,
seepage of the effluent can result in contamination of the ground water. Ground-
water contamination is also a hazard if fractured bedrock is within a depth of 40
inches, if the water table is high enough to raise the level of sewage in the lagoon,
or if floodwater overtops the lagoon.
A high content of organic matter is detrimental to proper functioning of the lagoon
because it inhibits aerobic activity. Slope, bedrock,and cemented pans can cause
construction problems,and large stones can hinder compaction of the lagoon floor.
If the lagoon is to be uniformly deep throughout, the slope must be gentle enough
and the soil material must be thick enough over bedrock or a cemented pan to make
land smoothing practical.
Information in this table is intended for land use planning,for evaluating land use
alternatives, and for planning site investigations prior to design and construction.
The information, however, has limitations. For example, estimates and other data
generally apply only to that part of the soil between the surface and a depth of 5 to
7 feet. Because of the map scale, small areas of different soils may be included
within the mapped areas of a specific soil.
The information is not site specific and does not eliminate the need for onsite
investigation of the soils or for testing and analysis by personnel experienced in the
design and construction of engineering works.
Government ordinances and regulations that restrict certain land uses or impose
specific design criteria were not considered in preparing the information in this table.
Local ordinances and regulations should be considered in planning, in site
selection, and in design.
Report—Sewage Disposal
[Onsite investigation may be needed to validate the interpretations in this table and
to confirm the identity of the soil on a given site.The numbers in the value columns
range from 0.01 to 1.00. The larger the value, the greater the potential limitation.
The table shows only the top five limitations for any given soil. The soil may have
additional limitations]
Sewage Disposal-Albemarle County,Virginia
Map symbol and soil name Pct.of Septic tank absorption fields Sewage lagoons
map unit
Rating class and limiting Value Rating class and limiting Value
features features
12C—Catoctin silt loam,7 to
15 percent slopes
Catoctin 80 Very limited Very limited
Depth to bedrock 1.00 Depth to hard bedrock 1.00
Seepage,bottom layer 1.00 Slope 1.00
Slope 0.37 Seepage 1.00
USDA Natural Resources Web Soil Survey 2/7/2014
Conservation Service National Cooperative Soil Survey Page 2 of 3
%moo *awe
Sewage Disposal--Albemarle County,Virginia Riverside Village
Sewage Disposal-Albemarle County,Virginia
Map symbol and soil name Pct.of Septic tank absorption fields Sewage lagoons
map unit
Rating class and limiting Value Rating class and limiting Value
features features
12D—Catoctin silt loam, 15 to
25 percent slopes
Catoctin 80 Very limited Very limited
Slope 1.00 Depth to hard bedrock 1.00
Depth to bedrock 1.00 Slope 1.00
Seepage,bottom layer 1.00 Seepage 1.00
71B—Rabun clay loam,2 to 7
percent slopes
Rabun 80 Somewhat limited Somewhat limited
Slow water movement 0.50 Slope 0.68
Seepage 0.50
71C—Rabun clay loam,7 to 15
percent slopes
Rabun 80 Somewhat limited Very limited
Slow water movement 0.50 Slope 1.00
Slope 0.37 Seepage 0.50
76—Riverview loam ---_�--- - - ---- -
Riverview
e j 75 Very limited Very limited
Flooding 1.00 Flooding 1.00
Seepage,bottom layer 1.00 Seepage 1.00
Depth to saturated zone 0.99 Depth to saturated zone 0.72
Slow water movement 0.50
79B—Starr silt loam,2 to 7 i
percent slopes
Starr 80 Very limited Very limited
Flooding 1.00 Flooding 1.00
Slow water movement 0.50 Slope 0.68
Seepage 0.50
Data Source Information
Soil Survey Area: Albemarle County, Virginia
Survey Area Data: Version 10, Dec 11, 2013
USDA Natural Resources Web Soil Survey 2/7/2014
Conservation Service National Cooperative Soil Survey Page 3 of 3
viese **we
Physical Soil Properties---Albemarle County,Virginia Riverside Village
Physical Soil Properties
This table shows estimates of some physical characteristics and features that affect
soil behavior.These estimates are given for the layers of each soil in the survey
area.The estimates are based on field observations and on test data for these and
similar soils.
Depth to the upper and lower boundaries of each layer is indicated.
Particle size is the effective diameter of a soil particle as measured by
sedimentation, sieving, or micrometric methods. Particle sizes are expressed as
classes with specific effective diameter class limits. The broad classes are sand,
silt, and clay, ranging from the larger to the smaller.
Sand as a soil separate consists of mineral soil particles that are 0.05 millimeter to
2 millimeters in diameter. In this table,the estimated sand content of each soil layer
is given as a percentage,by weight,of the soil material that is less than 2 millimeters
in diameter.
Silt as a soil separate consists of mineral soil particles that are 0.002 to 0.05
millimeter in diameter. In this table, the estimated silt content of each soil layer is
given as a percentage, by weight,of the soil material that is less than 2 millimeters
in diameter.
Clay as a soil separate consists of mineral soil particles that are less than 0.002
millimeter in diameter. In this table,the estimated clay content of each soil layer is
given as a percentage, by weight,of the soil material that is less than 2 millimeters
in diameter.
The content of sand,silt, and clay affects the physical behavior of a soil. Particle
size is important for engineering and agronomic interpretations, for determination
of soil hydrologic qualities, and for soil classification.
The amount and kind of clay affect the fertility and physical condition of the soil and
the ability of the soil to adsorb cations and to retain moisture.They influence shrink-
swell potential, saturated hydraulic conductivity(Ksat), plasticity, the ease of soil
dispersion, and other soil properties.The amount and kind of clay in a soil also
affect tillage and earthmoving operations.
Moist bulk density is the weight of soil (ovendry) per unit volume.Volume is
measured when the soil is at field moisture capacity,that is, the moisture content
at 1/3-or 1/10-bar(33kPa or 10kPa) moisture tension. Weight is determined after
the soil is dried at 105 degrees C. In the table, the estimated moist bulk density of
each soil horizon is expressed in grams per cubic centimeter of soil material that is
less than 2 millimeters in diameter. Bulk density data are used to compute linear
extensibility, shrink-swell potential, available water capacity, total pore space, and
other soil properties. The moist bulk density of a soil indicates the pore space
available for water and roots. Depending on soil texture,a bulk density of more than
1.4 can restrict water storage and root penetration. Moist bulk density is influenced
by texture, kind of clay, content of organic matter, and soil structure.
USDA Natural Resources Web Soil Survey 2/7/2014
"r Conservation Service National Cooperative Soil Survey Page 1 of 5
*4108100 NoolOO
Physical Soil Properties--Albemarle County,Virginia Riverside Village
Saturated hydraulic conductivity(Ksat) refers to the ease with which pores in a
saturated soil transmit water.The estimates in the table are expressed in terms of
micrometers per second.They are based on soil characteristics observed in the
field, particularly structure, porosity, and texture. Saturated hydraulic conductivity
(Ksat)is considered in the design of soil drainage systems and septic tank
absorption fields.
Available water capacity refers to the quantity of water that the soil is capable of
storing for use by plants.The capacity for water storage is given in inches of water
per inch of soil for each soil layer.The capacity varies,depending on soil properties
that affect retention of water. The most important properties are the content of
organic matter,soil texture,bulk density,and soil structure.Available water capacity
is an important factor in the choice of plants or crops to be grown and in the design
and management of irrigation systems.Available water capacity is not an estimate
of the quantity of water actually available to plants at any given time.
Linear extensibility refers to the change in length of an unconfined clod as moisture
content is decreased from a moist to a dry state. It is an expression of the volume
change between the water content of the clod at 1/3-or 1/10-bar tension(33kPa or
10kPa tension)and oven dryness. The volume change is reported in the table as
percent change for the whole soil.The amount and type of clay minerals in the soil
influence volume change.
Linear extensibility is used to determine the shrink-swell potential of soils. The
shrink-swell potential is low if the soil has a linear extensibility of less than 3 percent;
moderate if 3 to 6 percent;high if 6 to 9 percent;and very high if more than 9 percent.
If the linear extensibility is more than 3, shrinking and swelling can cause damage
to buildings, roads, and other structures and to plant roots. Special design
commonly is needed.
Organic matter is the plant and animal residue in the soil at various stages of
decomposition. In this table,the estimated content of organic matter is expressed
as a percentage, by weight, of the soil material that is less than 2 millimeters in
diameter. The content of organic matter in a soil can be maintained by returning
crop residue to the soil.
Organic matter has a positive effect on available water capacity, water infiltration,
soil organism activity,and tilth.It is a source of nitrogen and other nutrients for crops
and soil organisms.
Erosion factors are shown in the table as the K factor(Kw and Kf)and the T factor.
Erosion factor K indicates the susceptibility of a soil to sheet and rill erosion by
water.Factor K is one of six factors used in the Universal Soil Loss Equation(USLE)
and the Revised Universal Soil Loss Equation (RUSLE)to predict the average
annual rate of soil loss by sheet and rill erosion in tons per acre per year.The
estimates are based primarily on percentage of silt, sand, and organic matter and
on soil structure and Ksat.Values of K range from 0.02 to 0.69. Other factors being
equal,the higher the value,the more susceptible the soil is to sheet and rill erosion
by water.
Erosion factor Kw indicates the erodibility of the whole soil. The estimates are
modified by the presence of rock fragments.
Erosion factor Kf indicates the erodibility of the fine-earth fraction, or the material
less than 2 millimeters in size.
USDA Natural Resources Web Soil Survey 2/7/2014
Conservation Service National Cooperative Soil Survey Page 2 of 5
*are ■arsce
Physical Soil Properties--Albemarle County,Virginia Riverside Village
Erosion factor T is an estimate of the maximum average annual rate of soil erosion
by wind and/or water that can occur without affecting crop productivity over a
sustained period.The rate is in tons per acre per year.
Wind erodibility groups are made up of soils that have similar properties affecting
their susceptibility to wind erosion in cultivated areas. The soils assigned to group
1 are the most susceptible to wind erosion, and those assigned to group 8 are the
least susceptible. The groups are described in the"National Soil Survey
Handbook."
Wind erodibility index is a numerical value indicating the susceptibility of soil to wind
erosion,or the tons per acre per year that can be expected to be lost to wind erosion.
There is a close correlation between wind erosion and the texture of the surface
layer,the size and durability of surface clods, rock fragments, organic matter, and
a calcareous reaction. Soil moisture and frozen soil layers also influence wind
erosion.
Reference:
United States Department of Agriculture, Natural Resources Conservation Service.
National soil survey handbook, title 430-VI. (http://soils.usda.gov)
USDA Natural Resources Web Soil Survey 2/7/2014
MITI Conservation Service National Cooperative Soil Survey Page 3 of 5
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Physical Soil Properties--Albemarle County,Virginia Riverside Village
Physical Soil Properties
This table shows estimates of some physical characteristics and features that affect
soil behavior.These estimates are given for the layers of each soil in the survey
area.The estimates are based on field observations and on test data for these and
similar soils.
Depth to the upper and lower boundaries of each layer is indicated.
Particle size is the effective diameter of a soil particle as measured by
sedimentation, sieving, or micrometric methods. Particle sizes are expressed as
classes with specific effective diameter class limits. The broad classes are sand,
silt, and clay, ranging from the larger to the smaller.
Sand as a soil separate consists of mineral soil particles that are 0.05 millimeter to
2 millimeters in diameter.In this table,the estimated sand content of each soil layer
is given as a percentage,by weight,of the soil material that is less than 2 millimeters
in diameter.
Silt as a soil separate consists of mineral soil particles that are 0.002 to 0.05
millimeter in diameter. In this table, the estimated silt content of each soil layer is
given as a percentage, by weight,of the soil material that is less than 2 millimeters
in diameter.
Clay as a soil separate consists of mineral soil particles that are less than 0.002
millimeter in diameter. In this table, the estimated clay content of each soil layer is
given as a percentage, by weight,of the soil material that is less than 2 millimeters
in diameter.
The content of sand, silt, and clay affects the physical behavior of a soil. Particle
size is important for engineering and agronomic interpretations, for determination
of soil hydrologic qualities, and for soil classification.
The amount and kind of clay affect the fertility and physical condition of the soil and
the ability of the soil to adsorb cations and to retain moisture.They influence shrink-
swell potential, saturated hydraulic conductivity(Ksat), plasticity, the ease of soil
dispersion, and other soil properties.The amount and kind of clay in a soil also
affect tillage and earthmoving operations.
Moist bulk density is the weight of soil (ovendry)per unit volume.Volume is
measured when the soil is at field moisture capacity, that is,the moisture content
at 1/3-or 1/10-bar(33kPa or 10kPa)moisture tension. Weight is determined after
the soil is dried at 105 degrees C. In the table, the estimated moist bulk density of
each soil horizon is expressed in grams per cubic centimeter of soil material that is
less than 2 millimeters in diameter. Bulk density data are used to compute linear
extensibility, shrink-swell potential, available water capacity,total pore space, and
other soil properties.The moist bulk density of a soil indicates the pore space
available for water and roots. Depending on soil texture,a bulk density of more than
1.4 can restrict water storage and root penetration. Moist bulk density is influenced
by texture, kind of clay, content of organic matter, and soil structure.
USDA Natural Resources Web Soil Survey 2/7/2014
Warm Conservation Service National Cooperative Soil Survey Page 1 of 5
NOW
Physical Soil Properties---Albemarle County,Virginia Riverside Village
Saturated hydraulic conductivity(Ksat) refers to the ease with which pores in a
saturated soil transmit water.The estimates in the table are expressed in terms of
micrometers per second.They are based on soil characteristics observed in the
field, particularly structure, porosity, and texture. Saturated hydraulic conductivity
(Ksat)is considered in the design of soil drainage systems and septic tank
absorption fields.
Available water capacity refers to the quantity of water that the soil is capable of
storing for use by plants.The capacity for water storage is given in inches of water
per inch of soil for each soil layer.The capacity varies,depending on soil properties
that affect retention of water. The most important properties are the content of
organic matter,soil texture,bulk density,and soil structure.Available water capacity
is an important factor in the choice of plants or crops to be grown and in the design
and management of irrigation systems.Available water capacity is not an estimate
of the quantity of water actually available to plants at any given time.
Linear extensibility refers to the change in length of an unconfined clod as moisture
content is decreased from a moist to a dry state. It is an expression of the volume
change between the water content of the clod at 1/3-or 1/10-bar tension (33kPa or
10kPa tension)and oven dryness. The volume change is reported in the table as
percent change for the whole soil.The amount and type of clay minerals in the soil
influence volume change.
Linear extensibility is used to determine the shrink-swell potential of soils. The
shrink-swell potential is low if the soil has a linear extensibility of less than 3 percent;
moderate if 3 to 6 percent;high if 6 to 9 percent;and very high if more than 9 percent.
If the linear extensibility is more than 3, shrinking and swelling can cause damage
to buildings, roads, and other structures and to plant roots. Special design
commonly is needed.
Organic matter is the plant and animal residue in the soil at various stages of
decomposition. In this table, the estimated content of organic matter is expressed
as a percentage, by weight, of the soil material that is less than 2 millimeters in
diameter.The content of organic matter in a soil can be maintained by returning
crop residue to the soil.
Organic matter has a positive effect on available water capacity,water infiltration,
soil organism activity,and tilth.It is a source of nitrogen and other nutrients for crops
and soil organisms.
Erosion factors are shown in the table as the K factor(Kw and Kf)and the T factor.
Erosion factor K indicates the susceptibility of a soil to sheet and rill erosion by
water.Factor K is one of six factors used in the Universal Soil Loss Equation(USLE)
and the Revised Universal Soil Loss Equation (RUSLE)to predict the average
annual rate of soil loss by sheet and rill erosion in tons per acre per year. The
estimates are based primarily on percentage of silt, sand, and organic matter and
on soil structure and Ksat.Values of K range from 0.02 to 0.69. Other factors being
equal,the higher the value,the more susceptible the soil is to sheet and rill erosion
by water.
Erosion factor Kw indicates the erodibility of the whole soil. The estimates are
modified by the presence of rock fragments.
Erosion factor Kf indicates the erodibility of the fine-earth fraction, or the material
less than 2 millimeters in size.
USDA Natural Resources Web Soil Survey 2/7/2014
r Conservation Service National Cooperative Soil Survey Page 2 of 5
Physical Soil Properties--Albemarle County,Virginia Riverside Village
Erosion factor T is an estimate of the maximum average annual rate of soil erosion
by wind and/or water that can occur without affecting crop productivity over a
sustained period. The rate is in tons per acre per year.
Wind erodibility groups are made up of soils that have similar properties affecting
their susceptibility to wind erosion in cultivated areas. The soils assigned to group
1 are the most susceptible to wind erosion, and those assigned to group 8 are the
least susceptible. The groups are described in the"National Soil Survey
Handbook."
Wind erodibility index is a numerical value indicating the susceptibility of soil to wind
erosion,or the tons per acre per year that can be expected to be lost to wind erosion.
There is a close correlation between wind erosion and the texture of the surface
layer, the size and durability of surface clods, rock fragments, organic matter, and
a calcareous reaction. Soil moisture and frozen soil layers also influence wind
erosion.
Reference:
United States Department of Agriculture, Natural Resources Conservation Service.
National soil survey handbook,title 430-VI. (http://soils.usda.gov)
USDA Natural Resources Web Soil Survey 2/7/2014
'i" Conservation Service National Cooperative Soil Survey Page 3 of 5
7/
m-
•.<
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Soil Features---Albemarle County,Virginia Riverside Village
Soil Features
This table gives estimates of various soil features. The estimates are used in land
use planning that involves engineering considerations.
A restrictive layer is a nearly continuous layer that has one or more physical,
chemical, or thermal properties that significantly impede the movement of water
and air through the soil or that restrict roots or otherwise provide an unfavorable
root environment. Examples are bedrock, cemented layers, dense layers, and
frozen layers.The table indicates the hardness and thickness of the restrictive layer,
both of which significantly affect the ease of excavation. Depth to top is the vertical
distance from the soil surface to the upper boundary of the restrictive layer.
Subsidence is the settlement of organic soils or of saturated mineral soils of very
low density. Subsidence generally results from either desiccation and shrinkage,
or oxidation of organic material,or both,following drainage.Subsidence takes place
gradually, usually over a period of several years. The table shows the expected
initial subsidence,which usually is a result of drainage,and total subsidence,which
results from a combination of factors.
Potential for frost action is the likelihood of upward or lateral expansion of the soil
caused by the formation of segregated ice lenses(frost heave)and the subsequent
collapse of the soil and loss of strength on thawing. Frost action occurs when
moisture moves into the freezing zone of the soil. Temperature, texture, density,
saturated hydraulic conductivity(Ksat), content of organic matter, and depth to the
water table are the most important factors considered in evaluating the potential for
frost action. It is assumed that the soil is not insulated by vegetation or snow and
is not artificially drained. Silty and highly structured, clayey soils that have a high
water table in winter are the most susceptible to frost action. Well drained, very
gravelly, or very sandy soils are the least susceptible. Frost heave and low soil
strength during thawing cause damage to pavements and other rigid structures.
Risk of corrosion pertains to potential soil-induced electrochemical or chemical
action that corrodes or weakens uncoated steel or concrete. The rate of corrosion
of uncoated steel is related to such factors as soil moisture, particle-size
distribution, acidity, and electrical conductivity of the soil.The rate of corrosion of
concrete is based mainly on the sulfate and sodium content, texture, moisture
content,and acidity of the soil.Special site examination and design may be needed
if the combination of factors results in a severe hazard of corrosion. The steel or
concrete in installations that intersect soil boundaries or soil layers is more
susceptible to corrosion than the steel or concrete in installations that are entirely
within one kind of soil or within one soil layer.
For uncoated steel,the risk of corrosion, expressed as low, moderate, or high, is
based on soil drainage class, total acidity, electrical resistivity near field capacity,
and electrical conductivity of the saturation extract.
For concrete, the risk of corrosion also is expressed as low, moderate, or high. It
is based on soil texture, acidity, and amount of sulfates in the saturation extract.
USDA Natural Resources Web Soil Survey 2/7/2014
Conservation Service National Cooperative Soil Survey Page 1 of 3
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