Soils, Infiltration, and On-site Testing Presented by: Mr. Brian Oram, PG, PASEO Wilkes University GeoEnvironmental Sciences and Environmental Engineering Department Wilkes - Barre, PA 18766 570-408-4619 http://www.water-research.net

Soils Defined Natural Body that Occurs on the Land Surface that are Characterized by One or More of the Following: Consists of Distinct Horizons or Layers The ability to support rooted plants in a natural environment Upper Limit is Air or Shallow Water Lower Limit is Bedrock or Limit of Biological Activity Classification based on a typical depth of 2 m or approximately 6.0 feet

Another Definition of Soils A Natural 3 - Dimensional Body at the Earth Surface Capable of Supporting Plants Properties are the Result of Parent Material, Climate, Living Matter, Landscape Position and Time. Soil Composed of 4 Components (mineral matter, organic matter, air, and water)

Five Soil Formation Factors Organisms Climate Time Topography and Landscape Setting Parent Material R

Soil Food Web - Organisms Micro & Macroscopic Decomposition of Organic Matter Animals Living in Soil Vegetation Types Human Activity Redoximorphic Feature Formation Image Source: The University of Minnesota, 2003

Climatic Elements (Energy & Precipitation) Annual and Seasonal Rainfall Temperature Range Biologic Production and Activity Weathering (Wind, Water, and Ice) Translocation of Material

Climate and Soil Development Image Source: University of Wisconsin, 2002

Geologic Time Time

Landscape and Relief (Soil Texture) A- Sandy Texture and Loamy Sand B- Sandy Textures C- Clay Loam, Loam, Silt Loam Image Source: University of Wisconsin, 2002

Landscape and Relief (Drainage) Water Movement Soil Drainage Landscape Configuration (Convex, Concave) Elevation Water Movement Image Source: NJ NRCS, 2002

Parent Material Bedrock Geological Materials Minerals and Rocks Glacial Materials Loess (wind blown) Alluvial Deposits Marine Deposits Organic Deposits Influences Minerals Present Colors Chemical Reactions Water Movement Soil Development Glacial Material Bedrock

Describing Soils Soil Texture Structure Consistency Soil Color Coarse Fragment Content Redoximorphic Features other Diagnostic Properties

Soil Texture The way a soil "feels" is called the soil texture. Soil texture depends on the amount of each size of particle in the soil. The three soil separates are sand, silt, and clay Sand are the largest particles and they feel "gritty." Silt are medium sized, and they feel soft, silky or "floury." Clay are the smallest sized particles, and they feel "sticky" and they are hard to squeeze.

Soil Textural Triangle

Soil Structures

Water Movement and Structure

Soil Consistency Soil Consistency the feel of the soil, reflecting relative resistance to pressure: eg friable, firm, hard, loose, plastic. The term soil consistency is used to describe the resistance of a soil at various moisture contents to mechanical stresses or manipulations. It is commonly measured by feeling and manipulating the soil by hand.

Consistency Terms

Soil Color Munsell Notations In the Munsell system of notation, color characteristics are designated by three axes: Hue (the name of the color) Value (the darkness or lightness of the color) Chroma (the intensity, or strength of the color) For example, 10YR4/3 Hue (10YR), Value (4), Chroma (3) Color: brown In PA - The primary hues are typically 10YR and 7.5YR.

Soil Color-Munsell Notation Red- indicates the presence of Fe-oxides (iron oxides). Grey- indicates the presence of elevated water tables and reduced Fe (iron). Black-indicates the presence of organic matter, Mn-oxides (manganese), or FeS (iron sulfides). Organic matter suggest the soil is nutrient rich and fertile. Iron sulfides occur in wetlands and associated with rotten egg odor. White- indicates the presence of carbonate or soluble salts.

Soil Horizons Layer of Soil Parallel to Surface Properties a function of climate, landscape setting, parent material, biological activity, and other soil forming processes. Horizons (A, E, B, C, R, etc) Image Source: University of Texas, 2002

Soil Horizons O- Organic Horizons Organic Layers of Decaying Plant and Animal Tissue Aids Soil Structural Development Helps to Retain Moisture Enriches Soil with Nutrients Infiltration Capacity function of Organic Decomposition O Horizon Dark in Color Because of Humus Material - 1,000,000 bacteria per cm3

Soil Horizons A Horizons: “ Topsoil” Mineral Horizon Near Surface Accumulation of Organic Material Eluviation Process Moves Humic and Minerals form O Horizon into A horizon Ap - Plowed A Horizon Ab - Buried Horizon Soil dark in color, coarser in texture, and high porosity A Horizon

Soil Horizons: E Horizons Albic Horizon (Latin - White) Mineral Horizon Near Surface Movement of Silicate Clay, Iron, and Aluminum from the A Horizon through Eluviation Horizon does not mean a water table is present, but the horizon can be associated with high water table , use Symbol Eg (gleyed modifier) Underlain by a B (illuvial) horizon E Horizon

Soil Horizons: B Horizons Zone of Maximum Accumulation Mineral Horizon Illuviation is Occurring - Movement into the Horizon B Horizon Receives Organic and Inorganic Materials from Upper Horizons. Color Influence by Organic, Iron, Aluminum, and Carbonates Bw - Weakly Colored or Structured Bhs- Accumulation of illuvial organic material and sesquioxides Bs- Accumulation of sesquioxides Bt- Translocation of silicate clay Bx- Fragipan Horizon, brittle Bhs Horizon Bs Horizon Bw Horizon

Soil Horizons: Bx and Bt Horizons Horizons Indicate Reduced Infiltration Capacity and Permeability Bx: B horizon with fragipan, a compact, slowly permeable subsurface horizon that is brittle when moist and hard when dry. Prismatic soil structure, mineral coatings and high bulk density Area of Highest Permeability along Prism Contact Bt: Clay accumulation is indicated by finer soil textures and by clay coating peds and lining pores

C- Horizons Distinguished by Color, Structure, and Deposition Mineral Horizon or Layer, excluding Rock Little or No Soil-Forming May be Similar to Overlying Formation May be Called Parent Material Layer can be Gleyed Developed in Place or Deposited

R- Horizons Hard, Consolidated Bedrock Typically Underlies a C Horizon, but could be directly below an A or B Horizon. R Horizon

Soil Structure and Horizon

Source of Soils Data Soil Surveys in GIS Format Soil Survey Maps

Soil Hydrologic Cycle Source: Vepraskas, M.J, et. Al. “ Wetland Soils”, 2001.

Soil Drainage Class and Soil Group Soil Drainage Class - Refers to Frequency and Duration of Periods of Saturation or Partial Saturation During Soil Formation. There are 7 Natural Soil Drainage Classes. Hydrologic Soil Group-Refers to Soils Runoff Producing Characteristics as used in the NRCS Curve Number Method. There area 4 Hydrologic Soil Groups (A, B, C, D).

Group A and B Group A- Well Drained Group A is sand, loamy sand or sandy loam types of soils. It has low runoff potential and high infiltration rates even when thoroughly wetted. Deep, well to excessively drained sands or gravels and have a high rate of water transmission. Root Limiting / Impermeable layers over 100 cm or 40 inches ***************** Group B is silt loam or loam. It has a moderate infiltration rate when thoroughly wetted. Moderately deep to deep, moderately well to well drained soils with moderately fine to moderately coarse textures. Root Limiting / Impermeable e layers over 50 to 100 cm or 20 to 40 inches Group A- Well Drained

Group C and D Group D - Poorly Drained Highest Runoff Potential Group C soils are sandy clay loam. They have low infiltration rates when thoroughly wetted and consist chiefly of soils with a layer that impedes downward movement of water and soils with moderately fine to fine structure. Perched water table 100 to 150 cm or 40 to 60 inches; root limiting 20 to 40 inches. ***************** Group D soils are clay loam, silty clay loam, sandy clay, silty clay or clay. They have very low infiltration rates when thoroughly wetted and consist chiefly of clay soils with a high swelling potential, soils with a permanent high water table, soils with a claypan or clay layer at or near the surface and shallow soils over nearly impervious material ( < 20 inches). Group D - Poorly Drained Highest Runoff Potential

Definitions Infiltration - The downward entry of water into the immediate surface of soil or other materials. Infiltration Capacity- The maximum rate at which water can infiltrate into a soil under a given set of conditions. Infiltration Rate- The rate at which water penetrates the surface of the soil and expressed in cm/hr, mm/hr, or inches/hr. The rate of infiltration is limited by the capacity of the soil and rate at which water is applied to the surface. This is a volume flux of water flowing into the profile per unit of soil surface area (expressed as velocity). Percolation -Vertical and Lateral Movement of water through the soil by gravity.

Infiltration Rate and Capacity Soil Factors that Control Infiltration Rate: - Vegetative Cover, Root Development and Organic Content - Moisture Content - Soil Texture and Structure - Porosity and Permeability - Soil Bulk Density and Compaction - Slope, Landscape Position, Topography

Infiltration Rate (Time Dependent) Decreasing Infiltration Steady Gravity Induced Rate Infiltration with Time Rate is Initially High Because of a Combination of Capillary and Gravity Forces Final Infiltration Capacity (Equilibrium)- Infiltration Approaches Saturated Permeability

Infiltration Rate (Moisture) Infiltration Decreases with Time 1) Changes in Surface and Subsurface Conditions 2) Change in Matrix Potential 3) Overtime - Matrix Potential Decreases and Gravity Forces Dominate - Causing a Reduction in the Infiltration Rate

Measuring Infiltration Rate Flooding (ring) Infiltrometers Single ring Double ring Flooded Infiltrometers Tension Infiltrometers Rainfall-Runoff Plot Infiltrometers

Measuring Infiltration Rate

Single Rings Infiltrometers Cylinder - 30 cm in Diameter Drive 5 cm or more into Soil Surface or Horizon Water is Ponded Above the Surface Record Volume of Water Added with Time to Maintain a Constant Head Measures a Combination of Horizontal and Vertical Flow

Double Rings Infiltrometers Outer Rings are 6 to 24 inches in Diameter (ASTM - 12 to 24 inches) Mariotte Bottles Can be Used to Maintain Constant Head Rings Driven - 5 cm to 6 inches in the Soil and if necessary sealed

Other Infiltrometers Ponded Infiltrometers Tension Infiltrometer Unsaturated Flow Of Water

Infiltration Rate by Soil Group/ Texture Source: Texas Council of Governments, 2003.

Infiltration Rate Function of Slope & Texture Source: Rainbird Corporation, derived from USDA Data

Infiltration Rate Function of Vegetation Source: Gray, D., “Principles of Hydrology”, 1973.

Comparison Infiltration to Percolation Testing Percolation Testing Over Estimated Infiltration Rate by 40 to over 400%

Infiltration (Compaction/ Moisture Level)

Case 1 :Myers Proposed Development Worcester Township, Pennsylvania Abbottstown Silt Loam, Deep to Moderately Deep, Somewhat Poorly Drained Some Areas Shallow Depth to Firm Bedrock Signs of Erosion Low Surface and Near Surface Infiltration Rates Associated with Surface Smearing, Btx, Bx Horizons BC/ C /R Horizons Higher Infiltration Rate. Readington Silt Loam Deep Moderately Well Drained Low Infiltration Surface, Bd, and Btx High Infiltration in C and R Horizons

Infiltration Rate Function of Horizon A, B, Btx, Bt, C, R C/R Testing - Areas Fractured Rock Source: On-site Infiltration Testing - Mr. Brian Oram (Wilkes University)

Evaluation Infiltration Step 1: Desktop Assessment - GIS Review Published Data Related to Soils, Geology, Hydrology Step 2: Characterize the Hydrological Setting Where are the Discharge and Recharge Zones? What forms of Natural Infiltration or Depression Storage Occurs? Step 3: On-Site Assessment Deep Soil Testing Throughout Site Based on Soils and Geological Data Double Ring Infiltration Testing How will water move through the site ? Step 4: Engineering Review and Evaluation Step 5: Additional Infiltration or On-site Testing Step 6: Final Design

Soils, Infiltration, and On-site Testing Presented by: Mr. Brian Oram, PG, PASEO Wilkes University GeoEnvironmental Sciences and Environmental Engineering Department Wilkes - Barre, PA 18766 570-408-4619 http://www.water-research.net

Horton Equation (1939) Infiltration is a Function of Time as defined by: f(t) = fc + (fo – fc)e^-kt f(t) = infiltration rate for any time “t” from beginning of infiltration fc = infiltration capacity fo = initial infiltration rate at (t=0) e = 2.71 =base of natural log k is a measure of the rate of decrease in infiltration rate (constant that depends on soil type) Large Watershed Application - Replaced by Philip and Green-Ampt Horton Method Used in EPA Storm Water Management Model

Green-Ampt Equation Soil pores are saturated behind wetting front; Green-Ampt model was the first physically-based model/equation describing the infiltration of water into soil. The model yields cumulative infiltration and the infiltration rate as an implicit function of time. The volume of infiltration was a function of: Soil pores are saturated behind wetting front; Wetting front moves in response to capillary forces; and Darcy’s flow governs that headloss in the saturated zone. Approx. Equation: f = (A/F)+B; f = infiltration rate, F - accumulative infiltration, and A and B are fitted parameters The Green-Ampt Model has been modified to calculate water infiltration into non-uniform soils by several researchers . In 1989, GALAYER was developed for heterogenous soils Models Available at: http://www.epa.gov/ada/csmos/ninflmod.html http://www.bae.ncsu.edu/soil_water/drainmod/dmversions.htm

Philip Equation (1960) where: F = total depth of infiltrated water in mm. t = time in seconds K = hydraulic conductivity in mm/sec m = the average moisture content of the soil to the depth of the wetting front m­­0 = initial soil moisture content - based on API calculation or input Pot = capillary potential at the wetting front in mm Pot = 250 log (K) + 100 D1 = depth of water on the soil surface Takes into account the “Ponding Head” Models Available at: http://www.epa.gov/ada/csmos/ninflmod.html

Soils, Infiltration, and On-site Testing Presented by: Mr. Brian Oram, PG, PASEO Wilkes University GeoEnvironmental Sciences and Environmental Engineering Department Wilkes - Barre, PA 18766 http://www.water-research.net