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Home My WebLink About20201677.tiff BEIlligY PIPELINE PHILLIPS 66 COLORADO LIBERTY PIPELINE PROJECT Weld County Department of Planning Services Use by Special Review Submittal Item # 24 Soil Report November 2019 USDA United States A product of the National Custom S Resource „,,.. . .......„. Department of Cooperative Soil Survey, Agriculture a joint effort of the United Report for N States Department of Agriculture and otherweld RCS Federal agencies , State Natural agencies including the Resources Agricultural Experiment Colorado Conservation Stations and local , Service participantssouthern Platteville Terminal site yr - L r 'AV + t r ' r • t 4iii7 y �' 'r Itart n�31 +'1 cam( ti LC1(4:::* �i{r air r :44.4.: sill11;ff - t l{N- --I,"• -1'1.... •'' • ° t`rr• -s.•. + - _. 1/2-- _n _..---''.a 1_ +.ii �, - .y r _ f q' _ — � • • Coen Road 30 _ , .PI • 'MHz. � It 6 ' . _ ♦ - _ 'y , •he •-ygi•t ` i• _ m 't 4 I _I da T it 7 •ly,. •� < _ f ayr, • a IrrI' •� • ._ - '' L ,ly•1 _ T• • Itit...a-I. -T - 14-47.11...` }_ h 16 i •fir - -1 ,, ' ' ' _ -.-0 111 1 �..• • ' r- ' . I _ ,J. ..t"•••••---r _ „- 0. _� - ;. . ° :�"C .. i� _ _ !1'f i - ' -w -�' 1 r .~" , 1 " : !' -r ice' ' 'u A.est ; . 1•Wore- . — • T ;1 _ - - • 1. . . . - , . a. I • la �. ' � ��,,,,..� y -1 ' fit_ - _ ..'• �_ 4 •i• [ ` - . , • •► . -LEI- • y a+-L _ 4. _ - •r+ ; r I - * eic 1, + �Jr r• i_ �..� _ate , >` Il s < r - -_y4 Tice le.i y r _ty}..��_ , _ 1 , -( •n '+1 - _ _ ' I _ Fy r.. a - .�� air - ',- , r • , _ i -� •{,^ -j.r w _ y `vr' .-� - r--• 1 P' ?.-r.j `• u N•`t•. T+eT ?'�•.. o F 1 r :. 1��, s. _ ', 3t- /r - -s •'.' .�•`^'T —_'f i .:l ��e • .ninl�� . _: .' ' -_.ca- F. _ , of _ • , • P • I ._ _ - i - ° _ 1- 'te a �'. - - S II �` • - . _ r - -of ir _I _ . .' is ---• Y ..E. - . - ._ ti • N , a �, ,o00 it • - , ir•g, r ` November 12 , 2019 Preface Soil surveys contain information that affects land use planning in survey areas. They highlight soil limitations that affect various land uses and provide information about the properties of the soils in the survey areas . Soil surveys are designed for many different users , including farmers , ranchers , foresters , agronomists , urban planners , community officials , engineers , developers , builders , and home buyers . Also, conservationists , teachers , students , and specialists in recreation , waste disposal , and pollution control can use the surveys to help them understand , protect, or enhance the environment. Various land use regulations of Federal , State , and local governments may impose special restrictions on land use or land treatment. Soil surveys identify soil properties that are used in making various land use or land treatment decisions . The information is intended to help the land users identify and reduce the effects of soil limitations on various land uses . The landowner or user is responsible for identifying and complying with existing laws and regulations . Although soil survey information can be used for general farm , local , and wider area planning , onsite investigation is needed to supplement this information in some cases . Examples include soil quality assessments (http://www. nres. usda .gavlwpsl portal/n reslm ain/so i l sf health/) and certain conservation and engineering applications . For more detailed information , contact your local USDA Service Center (https ://offices .sc. egov. usda .govllacatorlapp?agency=arcs) or your N RCS State Soil Scientist (http ://www. nres .0 sda.gov/wps/portal/nresfd etail/soils/contactu sl? cid =nres142p2_053951 ). Great differences in soil properties can occur within short distances . Some soils are seasonally wet or subject to flooding . Some are too unstable to be used as a foundation for buildings or roads . Clayey or wet soils are poorly suited to use as septic tank absorption fields . A high water table makes a soil poorly suited to basements or underground installations . The National Cooperative Soil Survey is a joint effort of the United States Department of Agriculture and other Federal agencies, State agencies including the Agricultural Experiment Stations, and local agencies . The Natural Resources Conservation Service (NRCS) has leadership for the Federal part of the National Cooperative Soil Survey. Information about soils is updated periodically. Updated information is available through the N RCS Web Soil Survey, the site for official soil survey information . The U . S. Department of Agriculture (USDA) prohibits discrimination in all its programs and activities on the basis of race, color, national origin , age, disability, and where applicable , sex, marital status , familial status , parental status , religion , sexual orientation , genetic information , political beliefs , reprisal , or because all or a part of an individual's income is derived from any public assistance program . (Not all prohibited bases apply to all programs . ) Persons with disabilities who require 2 alternative means for communication of program information (Braille, large print, audiotape, etc.) should contact USDA's TARGET Center at (202) 720-2600 (voice and TDD ) . To file a complaint of discrimination , write to USDA, Director, Office of Civil Rights , 1400 Independence Avenue , S .W. , Washington , D . C . 20250-9410 or call (800) 795-3272 (voice) or (202) 720-6382 (TDD). USDA is an equal opportunity provider and employer. 3 Contents Preface 2 How Soil Surveys Are Made 5 Soil Map 8 Soil Map 9 Legend 10 Map Unit Legend 11 Map Unit Descriptions 11 Weld County, Colorado, Southern Part 13 69—Valent sand , 0 to 3 percent slopes 13 70—Valent sand , 3 to 9 percent slopes 14 72—Vona loamy sand , 0 to 3 percent slopes 16 Soil Information for All Uses 18 Soil Reports 18 Building Site Development 18 Dwellings and Small Commercial Buildings 18 Construction Materials 20 Source of Reclamation Material , Roadfill , and Topsoil 21 Soil Health 23 Soil Health - Aggregate Stability (West US) 24 Soil Health - Bulk Density and Texture 27 Soil Health - Compaction , Surface Sealing 30 Soil Physical Properties 34 Engineering Properties 34 Particle Size and Coarse Fragments 42 Physical Soil Properties 44 Soil Qualities and Features 52 Soil Features 52 References 55 4 ■ How Soil Surveys Soil surveys are made to provide information about the soils and miscellaneous areas in a specific area . They include a description of the soils and miscellaneous areas and their location on the landscape and tables that show soil properties and limitations affecting various uses . Soil scientists observed the steepness , length , and shape of the slopes ; the general pattern of drainage; the kinds of crops and native plants ; and the kinds of bedrock . They observed and described many soil profiles . A soil profile is the sequence of natural layers , or horizons , in a soil . The profile extends from the surface down into the unconsolidated material in which the soil formed or from the surface down to bedrock. The unconsolidated material is devoid of roots and other living organisms and has not been changed by other biological activity. Currently, soils are mapped according to the boundaries of major land resource areas ( MLRAs). MLRAs are geographically associated land resource units that share common characteristics related to physiography, geology, climate , water resources , soils , biological resources , and land uses (USDA, 2006). Soil survey areas typically consist of parts of one or more MLRA. The soils and miscellaneous areas in a survey area occur in an orderly pattern that is related to the geology, landforms, relief, climate , and natural vegetation of the area . Each kind of soil and miscellaneous area is associated with a particular kind of landform or with a segment of the landform . By observing the soils and miscellaneous areas in the survey area and relating their position to specific segments of the landform , a soil scientist develops a concept, or model , of how they were formed . Thus , during mapping , this model enables the soil scientist to predict with a considerable degree of accuracy the kind of soil or miscellaneous area at a specific location on the landscape . Commonly, individual soils on the landscape merge into one another as their characteristics gradually change. To construct an accurate soil map, however, soil scientists must determine the boundaries between the soils. They can observe only a limited number of soil profiles . Nevertheless , these observations , supplemented by an understanding of the soil-vegetation-landscape relationship , are sufficient to verify predictions of the kinds of soil in an area and to determine the boundaries . Soil scientists recorded the characteristics of the soil profiles that they studied . They noted soil color, texture , size and shape of soil aggregates , kind and amount of rock fragments , distribution of plant roots , reaction , and other features that enable them to identify soils. After describing the soils in the survey area and determining their properties , the soil scientists assigned the soils to taxonomic classes (units). Taxonomic classes are concepts . Each taxonomic class has a set of soil characteristics with precisely defined limits . The classes are used as a basis for comparison to classify soils systematically. Soil taxonomy, the system of taxonomic classification used in the United States , is based mainly on the kind and character of soil properties and the arrangement of horizons within the profile . After the soil 5 Custom Soil Resource Report scientists classified and named the soils in the survey area, they compared the individual soils with similar soils in the same taxonomic class in other areas so that they could confirm data and assemble additional data based on experience and research . The objective of soil mapping is not to delineate pure map unit components; the objective is to separate the landscape into landforms or landform segments that have similar use and management requirements . Each map unit is defined by a unique combination of soil components and/or miscellaneous areas in predictable proportions . Some components may be highly contrasting to the other components of the map unit. The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data . The delineation of such landforms and landform segments on the map provides sufficient information for the development of resource plans . If intensive use of small areas is planned , onsite investigation is needed to define and locate the soils and miscellaneous areas . Soil scientists make many field observations in the process of producing a soil map. The frequency of observation is dependent upon several factors , including scale of mapping , intensity of mapping , design of map units , complexity of the landscape, and experience of the soil scientist. Observations are made to test and refine the soil-landscape model and predictions and to verify the classification of the soils at specific locations . Once the soil-landscape model is refined , a significantly smaller number of measurements of individual soil properties are made and recorded . These measurements may include field measurements , such as those for color, depth to bedrock, and texture , and laboratory measurements , such as those for content of sand , silt, clay, salt, and other components. Properties of each soil typically vary from one point to another across the landscape. Observations for map unit components are aggregated to develop ranges of characteristics for the components. The aggregated values are presented . Direct measurements do not exist for every property presented for every map unit component. Values for some properties are estimated from combinations of other properties . While a soil survey is in progress , samples of some of the soils in the area generally are collected for laboratory analyses and for engineering tests . Soil scientists interpret the data from these analyses and tests as well as the field-observed characteristics and the soil properties to determine the expected behavior of the soils under different uses . Interpretations for all of the soils are field tested through observation of the soils in different uses and under different levels of management. Some interpretations are modified to fit local conditions , and some new interpretations are developed to meet local needs . Data are assembled from other sources, such as research information , production records , and field experience of specialists . For example, data on crop yields under defined levels of management are assembled from farm records and from field or plot experiments on the same kinds of soil . Predictions about soil behavior are based not only on soil properties but also on such variables as climate and biological activity. Soil conditions are predictable over long periods of time , but they are not predictable from year to year. For example , soil scientists can predict with a fairly high degree of accuracy that a given soil will have a high water table within certain depths in most years, but they cannot predict that a high water table will always be at a specific level in the soil on a specific date. After soil scientists located and identified the significant natural bodies of soil in the survey area, they drew the boundaries of these bodies on aerial photographs and 6 Custom Soil Resource Report identified each as a specific map unit. Aerial photographs show trees, buildings , fields , roads , and rivers , all of which help in locating boundaries accurately. 7 Soil Map The soil map section includes the soil map for the defined area of interest, a list of soil map units on the map and extent of each map unit, and cartographic symbols displayed on the map. Also presented are various metadata about data used to produce the map , and a description of each soil map unit. 8 Custom Soil Resource Report l.fiSoil Map ti en en do 8 531300 531400 531500 531600 531700 531800 531900 5la0a 40° 12' 17" M F ! -1• e F ,• ,YT : I, I 40° 12' 17" N nc:. . zi r r'_'" I i . . yi r 4 ^ " 4 • a IrC r , _ _ - 7 t� • ` • i"'elP ( I. C ..f'is III'. •, f Oq,• r- .. I . -. r .. ... _ ._- r - d Ilk 1 1tl�y L _ • • I�M I '4 �- r .!^ 'L } 1 J ' f.�rF•' '•G •T .ti 7�• �c,��Iy�,,�, •r. J�''i• I ` ; - _ftir ! 4: ' : a�.T1 T, 1.1L •. _-' a 3---5‘,}-;., fey. � • ! , . .• '�• _ r - i¢TT\ T -__ '_•7s3)'}[ -� . L_I:1},.—..y �E�.. ,.� _ l -- 1 .•�y - ' 1 .. ywll — r 1 1 �. _ X11 in = t 1' .Ti ,111,W741 4',�� ti j '`• -- t.ip - arr.----....-‘--- `+3T r r r 71-3 v S! • N _ .f ■ " ' ; 11 Via^ T_ n I• !: • n� . ^ tl_ - , _ • W p • , 1 . J . u • r,T4�" t( , 1,, ', i ..k , ilipsix 1 { fai- _I b 11• allf ,, .v, ,_-. " . • u _ ' •I L n 1 • RF r• `r 1� G•ti - ilefill r . r •• ' I , '1 W • 111 A • .11 M i•.> T' r t: t [e4L.; �, R 1 t�I WI\ !Y r� alb iI 1 , I v 1. ik-1:4:1P01 pi: 1 j ti*� , '>< X ' �,. ''' q.'os •I may. --T::1 1 1, •_I�T in I - • .V r r 1. T LT I " : i is _ . OM •Z• .&�� 11, 111. 1•ii'--. t»• « . .. O,1Y Li ¢ fit".[awl (- 1 • i g , JI • ii _io_ : . - ...)-;:: .r . . . .. II r .0 SSSII - 1 • 4 , i �.— s_Zr ►r'� li 1 :,c a .. - �T__ _ ' _ -= _ O fir.- i - _ • - 1 a 'Y • • • 1 1 - - - - - f.' - — i . . . . ... na I A011,Pa. 1 r by •rata Soil Map may not be mid a 1_- , 1, --l- ' sa,0 . _ , .• 4a° 11' 41" N I , I = ll • : I I .:tr-•= ,_ 1.. •. _ 40° 11' 41" N 531300 531 0 531500 531600 531700 531800 531900 532000 m O.1 F. Map Scale: 1 :5,490 if printed on A portrait (83' x 11") shed. `'r' en so Meters 0 OOP, N 0 50 100 200 300 8 A 0 / I Feet 250 500 1000 1500 Map pro je'c-iion : Wab Mercator Corner coordinates: X111 G584 Edge tics: UTM Zone 13N WG584 9 Custom Soil Resource Report MAP LEGEND MAP INFORMATION Area of Interest (AOl) IN Spoil Area The soil surveys that comprise your AOI were mapped at Area of Interest (AOI) 1 :24,000. Stony Spot Soils Very Stony Spot Soil Map Unit Polygons Warning : Soil Map may not be valid at this scale.. V. Wet Spot Lj Soil Map Unit Lines Other Enlargement of maps beyond the scale of mapping can cause Soil Map Unit Points misunderstanding of the detail of mapping and accuracy of soil Special Line Features line placement. The maps do not show the small areas of Special Point Features contrasting soils that could have been shown at a more detailed lull Blowout Water Features scale. Streams and Canals r4 Borrow Pit Transportation Please rely on the bar scale on each map sheet for map Clay Spot Rails measurements . Closed Depression Interstate Highways Source of Map: Natural Resources Conservation Service FX Gravel Pit US Routes Web Soil Survey URL: Gravelly Spot Coordinate System : Web Mercator (EPSG :3857) Major Roads Landfill Local Roads Maps from the Web Soil Survey are based on the Web Mercator ss. Lava Flow projection, which preserves direction and shape but distorts Background distance and area. A projection that preserves area, such as the Marsh or swamp 1 Aerial Photography Albers equal-area conic projection , should be used if more * Mine or Quarry accurate calculations of distance or area are required . Miscellaneous Water This product is generated from the USDA-NRCS certified data as Perennial Water of the version date(s) listed below. Rock Outcrop Soil Survey Area: Weld County, Colorado, Southern Part Saline Spot Survey Area Data: Version 18, Sep 13, 2019 . 4.O Sandy Spot 9 0 Soil map units are labeled (as space allows) for map scales ,e Severely Eroded Spot 1 :50,000 or larger. Sinkhole Date(s) aerial images were photographed : Jul 17, 2015—Oct 2, 31, Slide or Slip 2017 Sodic Spot The orthophoto or other base map on which the soil lines were compiled and digitized probably differs from the background imagery displayed on these maps . As a result, some minor shifting of map unit boundaries may be evident. 10 Custom Soil Resource Report Map Unit Legend Map Unit Symbol Map Unit Name Acres in Aol Percent of AOI 69 Talent sand, 0 to 3 percent 8.1 5 .6% slopes 70 Valent sand, 3 to 9 percent 57.6 40 . 1 % slopes 72 Vona loamy sand, 0 to 3 77.9 54 .2% percent slopes Totals for Area of Interest 143.5 100.0% Map Unit Descriptions 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 , 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 . Most minor soils have properties similar to those of the dominant soil or soils in the map unit, and thus they do not affect use and management. These are called noncontrasting , or similar, components . They may or may not be mentioned in a particular map unit description . Other minor components , however, have properties and behavioral characteristics divergent enough to affect use or to require different management. These are called contrasting , or dissimilar, components. They generally are in small areas and could not be mapped separately because of the scale used . Some small areas of strongly contrasting soils or miscellaneous areas are identified by a special symbol on the maps . If included in the database for a given area , the contrasting minor components are identified in the map unit descriptions along with some characteristics of each . A few areas of minor components may not have been observed , and consequently they are not mentioned in the descriptions, especially where the pattern was so complex that it was impractical to make enough observations to identify all the soils and miscellaneous areas on the landscape . The presence of minor components in a map unit in no way diminishes the usefulness or accuracy of the data. The objective of mapping is not to delineate pure taxonomic classes but rather to separate the landscape into landforms or 11 Custom Soil Resource Report landform segments that have similar use and management requirements . The delineation of such segments on the map provides sufficient information for the development of resource plans . If intensive use of small areas is planned , however, onsite investigation is needed to define and locate the soils and miscellaneous areas . An identifying symbol precedes the map unit name in the map unit descriptions . Each description includes general facts about the unit and gives important soil properties and qualities. Soils that have profiles that are almost alike make up a soil series. Except for differences in texture of the surface layer, all the soils of a series have major horizons that are similar in composition , thickness , and arrangement. Soils of one series can differ in texture of the surface layer, slope , stoniness , salinity, degree of erosion , and other characteristics that affect their use. On the basis of such differences, a soil series is divided into soil phases. Most of the areas shown on the detailed soil maps are phases of soil series . The name of a soil phase commonly indicates a feature that affects use or management. For example, Alpha silt loam , 0 to 2 percent slopes, is a phase of the Alpha series . Some map units are made up of two or more major soils or miscellaneous areas . These map units are complexes , associations , or undifferentiated groups . A complex consists of two or more soils or miscellaneous areas in such an intricate pattern or in such small areas that they cannot be shown separately on the maps . The pattern and proportion of the soils or miscellaneous areas are somewhat similar in all areas . Alpha-Beta complex, 0 to 6 percent slopes , is an example . An association is made up of two or more geographically associated soils or miscellaneous areas that are shown as one unit on the maps . Because of present or anticipated uses of the map units in the survey area, it was not considered practical or necessary to map the soils or miscellaneous areas separately. The pattern and relative proportion of the soils or miscellaneous areas are somewhat similar. Alpha- Beta association , 0 to 2 percent slopes , is an example . An undifferentiated group is made up of two or more soils or miscellaneous areas that could be mapped individually but are mapped as one unit because similar interpretations can be made for use and management. The pattern and proportion of the soils or miscellaneous areas in a mapped area are not uniform . An area can be made up of only one of the major soils or miscellaneous areas , or it can be made up of all of them . Alpha and Beta soils , 0 to 2 percent slopes , is an example . Some surveys include miscellaneous areas. Such areas have little or no soil material and support little or no vegetation . Rock outcrop is an example . 12 Custom Soil Resource Report Weld County, Colorado , Southern Part 69 Valent sand , 0 to 3 percent slopes Map Unit Setting National map unit symbol: 2tczd Elevation: 3,000 to 5,210 feet Mean annual precipitation: 13 to 20 inches Mean annual air temperature: 48 to 52 degrees F Frost-free period: 130 to 166 days Farmland classification: Farmland of local importance Map Unit Composition Valent and similar soils: 85 percent Minor components: 15 percent Estimates are based on observations, descriptions, and transects of the mapunit Description of Valent Setting Landform: Interdunes un es Landform position (two-dimensional) : Faotslope , toeslope Landforr ► position (three-dimensional) : Base slope Down-slope shape: Linear Across-slope shape: Linear Parent material: Noricalcareous eolian sands Typical profile A - gto 5 inches: sand A - 5 to 12 inches: sand CI - 12 to 30 inches: sand C2 - 30 to 80 inches: sand Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature : More than 80 inches Natural drainage class: Excessively drained Runoff class: Negligible Capacity of the most limiting layer to transmit water ( sat) : High to very high (6 . 00 to 39 .96 inlhr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Calcium carbonate, maximum in profile: 1 percent Salinity, maximum in profile : Non saline (0 . 1 to 1 . 9 rrrm hoslcm ) Available water storage in profile: Very low (about 2 . 4 inches) Interpretive groups Land capability classification ('irrigated): 4e Land capability classification (nonirrigated): 6e Hydrologic Soil Group: A Ecological site: Deep Sand (R067BY01 SCO), Sands (North) (PE 16-20) (R072XA021 IBS) Hydric soil rating: No 13 Custom Soil Resource Report Minor Components Julesburg Percent of map unit: 5 percent Landform: I nterdun es Landform position (two-dimensional) : Toeslope Landform position (three-dimensional) : Base slope Down-slope shape: Linear Across-slope shape : Linear Ecological site: Sandy Plains (R067BY024CO), Sandy (North ) Draft (April 2010) (PE 16-20) (8072 A022KS) Hydric soil rating: No Vona Percent of map unit: 5 percent Landform: I nterd unes Landform position (two-dimensional) : Toeslope Landform position (three-dimensional) : Base slope Down-slope shape: Linear Across-slope shape: Linear Ecological site: Sandy Plains (R067BY024CO ) , Sandy (North ) Draft (April 2010) (PE 16-20) (8072 A022KS ) Hydric soil rating: No Dailey Percent of map unit: 5 percent Landform: Interdunes Landform position (two-dimensional) : Toeslope Landform position (three-dimensional) : Base slope Down-slope shape: Linear Across-slope shape : Concave Ecological site: Deep Sand ( R007BY015CO), Sandy (North) Draft (April 2010) ( PE 16-20) ( R072XA022KS ) Hydric soil rating: No 70 'talent sand , 3 to 9 percent slopes Map Unit Setting National map unit symbol: 2tczf Elevation: 3,050 to 5, 150 feet Mean annual precipitation: 12 to 18 inches Mean annual air temperature: 48 to 55 degrees F Frost-free period: 130 to 180 days Farmland classification: Not prime farmland Map Unit Composition Valent and similar soils: 80 percent Minor components: 20 percent Estimates are based on observations, descriptions, and transects of the mapunit. 14 Custom Soil Resource Report Description of Valent Setting Landform: Dunes , hills Landform position (two-dimensional) : Shoulder, backslope , summit, Footslope Landform position (three-dimensional) : Crest, side slope, head slope , nose slope Down-slope shape: Linear, convex Across-slope shape : Linear, convex Parent material: Noncalcareous eolian sands Typical profile A - g to 5 inches: sand AC - 5 to 12 inches: sand C1 - 12 to 30 inches: sand C2 - 30 to 80 inches: sand Properties and qualities Slope: 3 to 9 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Excessively drained Runoff class: Very low Capacity of the most limiting layer to transmit water (Ksat) : High to very high (6 . 00 to 39 .96 inlhr) Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Calcium carbonate, maximum in profile: 1 percent Salinity, maximum in profile : Nonsaline (0 .0 to 1 . 9 mmhoslcm ) Available water storage in profile: Very low (about 2 .4 inches) Interpretive groups Land capability classification (irrigated): 4e Land capability classification (nonirrigated): 6e Hydrologic Soil Group: A Ecological site: Deep Sand (RO67BYO15CO), Rolling Sands ( ROT2 Y1 O9KS) Hydric soil rating: No Minor Components Dailey Percent of map unit: 10 percent Landform: Interdunes u n es Landform position (two-dimensional) : Footslope , toeslope Landform position (three-dimensional) : Base slope Down-slope shape: Linear Across-slope shape: Concave Ecological site: Deep Sand ( R067BYO15CO), Sands (North) (PE 16-20) (R072XA021KS) Hydric soil rating: No Vona Percent of map unit: 5 percent Landform: Hills Landform position (two-dimensional) : Footslope, backslope , shoulder Landform position (three-dimensional) : Side slope , head slope , nose slope, base slope 15 Custom Soil Resource Report Down-slope shape: Linear Across-slope shape: Linear Ecological site: Sandy Plains (R067BY024CO ) ,O ) , Sandy (North ) Draft (April 2010) (PE 16-20) (R072 A0221KS ) Hydric soil rating: No Haxtun Percent of map unit: 5 percent Landform: Interdunes un es Landform position (two-dimensional) : Footslope, toeslope Landform position (three-dimensional) : Base slope Down slope shape: Linear Across-slope shape: Concave Ecological site: Sandy Plains (R0 7BY024C +O ) , Sandy Plains ( 8072 Y111 KS) Hydric soil rating: No 72 Vona loamy sand , 0 to 3 percent slopes Map Unit Setting National map unit symbol: 363r Elevation: 4, 600 to 5,200 feet Mean annual precipitation: 13 to 15 inches Mean annual air temperature: 48 to 55 degrees F Frost-free period: 130 to 160 days Farmland classification: Farmland of local importance Map Unit Composition Vona and► similar soils: 85 percent Minor components: 15 percent Estimates are based on observations, descriptions, and transects of the mapunit. Description of Vona Setting Landform: Terraces , plains Down-slope shape: Linear Across-slope shape: Linear Parent material: Alluvium and/or eolian deposits Typical profile NI - 0 to 6 inches: loamy sand H2 - 6 to 28 inches: fine sandy loam H3 - 28 to 60 inches: sandy loam Properties and qualities Slope: 0 to 3 percent Depth to restrictive feature: More than 80 inches Natural drainage class: Well drained Runoff class: Very low Capacity of the most limiting layer to transmit water 'Ksat,) : High ( 1 . 98 to 6. 00 inlhr) 16 Custom Soil Resource Report Depth to water table: More than 80 inches Frequency of flooding: None Frequency of ponding: None Calcium carbonate, maximum in profile: 15 percent Salinity, maximum in profile : Non aline to slightly saline (0 . 0 to 4 . 0 mmhoslcm) Available water storage in profile: Moderate (about 6 .5 inches) Interpretive groups Land capability classification (irrigated): 3e Land capability classification (nonirrigated): 4e Hydrologic Soil Group: A Ecological site: Sandy Plains (R067BY024CO) Hydric soil rating: No Minor Components Remmit Percent of map unit: 10 percent Hydric soil rating: No Valent Percent of map unit: 5 percent Hydric soil rating: No 17 Soil Information for All Uses Soil Reports The Soil Reports section includes various formatted tabular and narrative reports (tables) containing data for each selected soil map unit and each component of each unit. No aggregation of data has occurred as is done in reports in the Soil Properties and Qualities and Suitabilities and Limitations sections . The reports contain soil interpretive information as well as basic soil properties and qualities . A description of each report (table) is included . Building Site Development This folder contains a collection of tabular reports that present soil interpretations related to building site development. The reports (tables) include all selected map units and components for each map unit, limiting features and interpretive ratings . Building site development interpretations are designed to be used as tools for evaluating soil suitability and identifying soil limitations for various construction purposes. As part of the interpretation process , the rating applies to each soil in its described condition and does not consider present land use . Example interpretations can include corrosion of concrete and steel , shallow excavations, dwellings with and without basements , small commercial buildings , local roads and streets , and lawns and landscaping . 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 18 Custom Soil Resource Report 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. 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 . 19 Custom Soil Resource Report 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—Weld County, Colorado, Southern Part 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 69—Valent sand , 0 to 3 percent slopes Valent 85 Not limited Not limited Not limited Dailey 5 Not limited Not limited Not limited Julesburg 5 Not limited Not limited Not limited Vona 5 Not Limited Not limited Not limited 70—Valent sand , 3 to 9 percent slopes Valent 80 Not limited Not limited Somewhat limited Slope 0 .52 Dailey 10 Not limited Not limited Not limited Haxtun 5 Not limited Not limited Not limited Vona 5 Not limited Not limited Somewhat limited Slope 0 .52 72—Vona loamy sand, 0 to 3 percent slopes Vona 85 Not limited Not limited Not limited Remmit 10 Not rated Not rated Not rated Valent 5 Not rated Not rated Not rated Construction Materials This folder contains a collection of tabular reports that present soil interpretations related to sources of construction materials . The reports (tables) include all selected map units and components for each map unit, limiting features and interpretive ratings . Construction materials interpretations are tools designed to provide guidance to users in selecting a site for potential source of various materials . Individual soils or groups of soils may be selected as a potential source because they are close at hand , are the only source available , or they meets some or all of the physical or chemical properties required for the intended application . Example interpretations include roadfill , sand and gravel , topsoil and reclamation material . 20 Custom Soil Resource Report Source of Reclamation Material , Roadfill , and Topsoil This table gives information about the soils as potential sources of reclamation material , roadfill , and topsoil . Normal compaction , minor processing , and other standard construction practices are assumed . The soils are rated good, fair, or poor as potential sources of reclamation material , roadfill , and topsoil . The features that limit the soils as sources of these materials are specified in the table. Numerical ratings between 0 .00 and 0 .99 are given after the specified features . These numbers indicate the degree to which the features limit the soils as sources of topsoil , reclamation material , or roadfill . The lower the number, the greater the limitation . Reclamation material is used in areas that have been drastically disturbed by surface mining or similar activities. When these areas are reclaimed , layers of soil material or unconsolidated geological material , or both , are replaced in a vertical sequence . The reconstructed soil favors plant growth . The ratings in the table do not apply to quarries and other mined areas that require an offsite source of reconstruction material . The ratings are based on the soil properties that affect erosion and stability of the surface and the productive potential of the reconstructed soil . These properties include the content of sodium , salts , and calcium carbonate; reaction ; available water capacity; erodibility; texture; content of rock fragments ; and content of organic matter and other features that affect fertility. Roadfill is soil material that is excavated in one place and used in road embankments in another place. In this table , the soils are rated as a source of roadfill for low embankments , generally less than 6 feet high and less exacting in design than higher embankments . The ratings are for the whole soil , from the surface to a depth of about 5 feet. It is assumed that soil layers will be mixed when the soil material is excavated and spread . The ratings are based on the amount of suitable material and on soil properties that affect the ease of excavation and the performance of the material after it is in place. The thickness of the suitable material is a major consideration . The ease of excavation is affected by large stones , depth to a water table , and slope. How well the soil performs in place after it has been compacted and drained is determined by its strength (as inferred from the AASHTO classification of the soil) and linear extensibility (shrink-swell potential ). Topsoil is used to cover an area so that vegetation can be established and maintained . The upper 40 inches of a soil is evaluated for use as topsoil . Also evaluated is the reclamation potential of the borrow area . The ratings are based on the soil properties that affect plant growth ; the ease of excavating , loading , and spreading the material ; and reclamation of the borrow area. Toxic substances , soil reaction , and the properties that are inferred from soil texture, such as available water capacity and fertility, affect plant growth . The ease of excavating , loading , and spreading is affected by rock fragments , slope, depth to a water table , soil texture , and thickness of suitable material . Reclamation of the borrow area is affected by slope , depth to a water table, rock fragments , depth to bedrock or a cemented pan , and toxic material . The surface layer of most soils is generally preferred for topsoil because of its organic matter content. Organic matter greatly increases the absorption and retention of moisture and nutrients for plant growth . 21 Custom Soil Resource Report 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—Source of Reclamation Material , Roadfill , and Topsoil [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 . 00 to 0. 99. The smaller the value , the greater the limitation] Source of Reclamation Material, Roadfill, and Topsoil—Weld County, Colorado, Southern Part Map symbol and soil Pct. of Potential as a source of Potential as a source of Potential as a source of name map reclamation material roadfill topsoil unit Rating class and Value Rating class and Value Rating class and Value limiting features limiting features limiting features 69—Valent sand , 0 to 3 percent slopes Valent 85 Poor Good Poor Too sandy 0.00 Too sandy 0 .00 Wind erosion 0.00 Exchange capacity 0.31 Droughty 0.01 Low content of organic 0.02 matter Dailey 5 Poor Good Fair Wind erosion 0.00 Too sandy 0 .21 Too sandy 0.21 Exchange capacity 0 .53 Low content of organic 0. 50 matter • Juleburg 5 Fair Good Fair Low content of organic 0.88 Exchange capacity 0 .93 matter Too sandy 0.99 Too sandy 0 .99 Vona 5 Fair Good Fair Low content of organic 0.02 Exchange capacity 0 .92 matter 22 Custom Soil Resource Report Source of Reclamation Material, Roadfill, and Topsoil—Weld County, Colorado, Southern Part Map symbol and soil Pct. of Potential as a source of Potential as a source of Potential as a source of name map reclamation material roadfill topsoil unit Rating class and Value Rating class and Value Rating class and Value limiting features limiting features limiting features 70—Valent sand , 3 to 9 percent slopes Valent 80 Poor Good Poor Too sandy 0.00 Too sandy 0 .00 Wind erosion 0.00 Exchange capacity 0 .31 Droughty 0:01 Low content of organic 0.02 matter Dailey 10 Poor Good Poor Too sandy 0.00 Too sandy 0 .00 Wind erosion 0.00 Exchange capacity 0 .51 Droughty 0.27 Low content of organic 0. 50 matter Haxtun 5 Poor Good Good Wind erosion 0.00 Vona 5 Poor Good Fair Wind erosion 0.00 Exchange capacity 0 .86 Low content of organic 0.02 Too sandy 0 .99 matter Too sandy 0.99 72—Vona loamy sand, 0 to 3 percent slopes Vona 85 Poor Good Fair Wind erosion 0.00 Exchange capacity 0 .80 Low content of organic 0. 13 matter Remmit 10 Not rated Not rated Not rated Valent 5 Not rated Not rated Not rated Soil Health Soil health , also referred to as soil quality, is defined as the continued capacity of soil to function as a vital living ecosystem that sustains plants , animals , and humans . This folder contains the tabular reports that provide the information specific to the education and importance of managing soils so they are sustainable for future generations . 23 Custom Soil Resource Report Soil Health - Aggregate Stability (West US) Definition of What is Estimated Aggregate stability is defined as the stability of macroaggregates ( 1 -2 mm in size) against flowing water and is expressed as percent stable aggregates of the less than 2mm fraction . It is estimated from the organic matter content, total clay, and sodium adsorption ratio . Aggregate stability values are provided for horizons within the upper 6 inches , but not for sandy and organic surface layers . Significance Soil aggregate stability is an important soil property affecting soil health and crop production . It is important for stabilizing soil structure, increasing water infiltration , and reducing erosion . Soil aggregates are the smallest unit of soil structure . They are composed of decaying particulate organic matter, clay particles , microbial products , and fine roots . Aggregates are generally divided into macroaggregates (greater than 250 µm) and microaggregates (less than 250 pm) . The size, strength , and stability of aggregates depend upon the stabilizing agents involved . They can be classified as temporary, transient, or persistent. Improved aggregate stability leads to increased water infiltration and storage in the profile, reduced erosion , and soil structure that is resistant to compaction . Increases in soil organic carbon improves aggregation and aggregate stability, which protect carbon compounds enmeshed in the aggregates from decomposition , leading to carbon sequestration . Factors Affecting Soil Aggregation and Aggregate Stability Inherent Factors - Microaggregation ation is generally considered to be an inherent property of the soil . Persistent binding agents include highly decomposed , high molecular weight organic materials (e.g . , humic compounds), polymers , and polyvalent cations (e.g . , calcium , aluminum , iron) that have a heterogeneous , non- specific structure . These agents are associated with microaggregation as well as soil organic carbon (SOC ) sequestration . These persistent compounds are found in the interior of aggregates , forming organo-mineral complexes via the polyvalent cations . These agents are long-lasting , and the degree of aggregation formed by them is considered part of the inherent soil properties . Generally, management does not impact soil microaggregation . Soils naturally high in clay and polyvalent cations are likely to form more microaggregates . Dynamic Factors - Transient binding agents consist mainly of complex carbohydrates , or polysaccharides, and organic mucilages . As plant residues and compounds extruded by plant roots decompose, bacteria release mucilages that are complex carbon-rich carbohydrates . These carbohydrates serve as binding agents, or "glues ," to which clay particles can be adsorbed and bound together. The polysaccharides are non-humic compounds of high molecular weight and comprise about 20 to 25% of the soil humus . They are critical for binding microaggregates together, via polymer and polyvalent cation bridges , to form larger macroaggregates . Although binding with clay particles does provide some protection against decomposition , these binding agents generally decompose within a few weeks and need to be continually renewed through actively growing plants , decaying residues , or organic amendments . Temporary binding agents consist of plant roots , especially fine roots and root hairs , fungal hyphae , and bacterial and algal cells . These agents develop along with plant 24 Custom Soil Resource Report roots , forming a network that entangles mineral particles , through adsorption , to form macroaggregates . As roots cease to grow, the amount of these temporary agents is reduced . Planting cover crops or perennial plants maintains living roots longer in the soil , thus maintaining and strengthening the aggregates . Tillage reduces the amount of roots and the microbial biomass, especially in the surface horizon . Consequences of Weak Aggregates The first step in erosion is the breakdown of surface aggregates . Aggregates at the soil surface are weakened if the binding agents degrade at rates exceeding replenishment rates . These aggregates can be broken apart by outside forces , of which raindrops , wind , and tillage are among the most important. Changes in soil chemistry, such as increased sodicity of the soil , can also contribute to aggregate breakdown . As aggregates are broken down , the component particles clog the surface pores and surface sealing and crusting follow. This process results in reduced water infiltration , ponding , increased runoff and erosion , and sediment transport on and off site . Its occurrence can be minimized by strengthening aggregates . Additionally, reducing the size and strength of the aggregates throughout the profile weakens soil structure so that it is more easily compacted by field operations , especially if the soil is too wet. Poor structure can lead to ponding after rainstorms , which can result in increased evaporation and less water in the profile that might otherwise have been available for crop growth . Maintaining and increasing aggregation and aggregate strength can be accomplished through the implementation of soil health management systems. These systems may include reduced tillage operations (or preferably no tillage operations) and the incorporation of cover crops or a cash crop (such as winter wheat) into the rotation . Having crops and cover crops with varied rooting structures improves soil structure, as does maintaining living roots in the soil as long as possible. Studies have shown that plants will push into the rhizosphere , via the root system , about 20% of the carbon dioxide is fixed through photosynthesis . Those carbon compounds can support the soil microbial population , which is critical to soil structure, water infiltration , and nutrient cycling . Any management system that leads to increased soil organic carbon is likely to improve aggregate stability. Measuring Aggregate Stability Aggregate stability is determined by a wet sieving technique preceded by vacuum saturation of the 1 -2 mm size aggregates as described in USDA-ARS ( 1966). Stable aggregates are corrected for sand greater than 0.25 mm as follows : Aggregate stability (% ) = ((wt. of stable aggregates and sand ) — (wt. of sand ))/((wt. of sample) — (wt. of sand)). References Blanco-Canqui , H . , and R. Lal . 2004 . Mechanisms of carbon sequestration in soil aggregates . Criti . Rev. Plant Sci . 23:481 -504 . doi : 10 . 1080/07352680490886842 Cambardella , C .A. , and E.T. Elliott. 1993. Carbon and nitrogen distribution in aggregates from cultivated and native grassland soils . Soil Sci . Soc. Am . J . 57: 1071 - 1076 . doi : 10.2136/sssaj 1993 .03615995005700040032x Denef, K. , J . Six, H . Bossuyt, S. C . Frey, E .T. Elliott, R. Merckx, and K. Paustian . 2001 . Influence of dry-wet cycles on the interrelationship between aggregate, particulate organic matter, and microbial community dynamics . Soil Biol . Biochem . 33: 1599- 1611 . doi : 10. 1016/s0038-0717(01 )00076- 1 25 Custom Soil Resource Report Gale , W.J . , and C .A. Cambardella. 2000. Carbon dynamics of surface residue- and root-derived organic matter under simulated no-till . Soil Sci . Soc. Am . J . 64: 190- 195 . doi : 10 .2136/sssaj2000 . 641190x Gale , W.J . , C .A. Cambardella, and T. B . Bailey. 2000a . Root-derived carbon and the formation and stabilization of aggregates. Soil Sci . Soc. Am . J . 64 :201 -207. doi : 10.21361sssaj2000. 641201 x Gale , W.J . , C .A. Cambardella, and T. B . Bailey. 2000b. Surface residue- and root- derived carbon in stable and unstable aggregates . Soil Sci . Soc. Am . J . 64 : 196-201 . doi : 10 .2136/sssaj2000 . 641196x s aj2 000 . 64119 6x Martin , J . P. 1971 . Decomposition and binding action of polysaccharides in soil . Soil Biol . Biochem . 3 : 33-41 . Six, J . , E .T. Elliott, and K. Paustian . 1999 . Aggregate and soil organic matter dynamics under conventional and no-tillage systems . Soil Sci . Soc. Am . J . 63: 1350- 1358 . Six, J . , K. Paustian , E.T. Elliott, and C . Combrink. 2000. Soil structure and organic matter: I . Distribution of aggregate-size classes and aggregate-associated carbon . Soil Sci . Soc. Am . J . 64 : 681 -689 . Tisdall , J . M . , and J . M . Oades . 1982 . Organic matter and water-stable aggregates in soil . J . Soil Sci . 33 : 141 - 163. USDA-ARS . 1966. Aggregate stability of soils from western United States and Canada . Tech . Bull . No. 1355 . Agricultural Research Service , United States Department of Agriculture in cooperation with Colorado Agricultural Experiment Station . U . S. Govn't Printing Office . Washington , D . C . Report—Soil Health - Aggregate Stability (West US ) Soil Health - Aggregate Stability (West US)-Weld County, Colorado, Southern Part Map symbol and soil Pct. of map Horizon Depth Aggregate Aggregate Aggregate name unit Name (Inches) Stability low Stability RV (Pct) Stability high (Pct) (Pct) 69—'talent sand , 0 to 3 percent slopes Valent 85 A 0-5 — —AC 5-12 — —Dailey 5 A 0-16 — — J u lesbu rg 5 A 0-5 64 69 75 Bt1 5-10 55 63 69 Vona 5 A 0-7 45 54 61 26 Custom Soil Resource Report soil Health - Aggregate Stability (West US)-Weld County, Colorado, Southern Part Map symbol and soil Pct. of map Horizon Depth Aggregate Aggregate Aggregate name unit Name (Inches) Stability low Stability RV (Pct) Stability high (Pct) (Pct) 70—Valent sand , 3 to 9 percent slopes Valent 80 A 0-5 — — A►C 5-12 — —Dailey 10 A 0-14 54 62 68 Haxtun 5 A►l 0-5 54 63 69 A2 5-12 54 63 71 Vona 5 A 0-7 45 53 57 72—Vona loamy sand, 0 to 3 percent slopes Vona 85 H1 0-6 45 49 54 Soil Health - Bulk Density and Texture Bulk density is a physical soil property measured by the ratio of dry weight of soil to its volume. Significance Bulk density is one of several soil properties frequently used as a measure of soil health (Volchko, et al . , 2014) and is an indicator for soil compaction and root restriction . Even though bulk density varies with soil texture, it is a dynamic soil property that changes based on soil management with different soil cover, amount of organic matter, soil structure, and porosity ( USDA, 2008). It influences water movement in the soil , root growth and penetration and seed germination . Some of the practices that can improve bulk density include increasing organic matter content, reducing soil disturbance when the soil is wet, and maintaining soil surface protection with a cover crop , especially multi-species that can provide a wide range of root penetration . Bulk density influences plant growth and engineering applications . Within a family level particle-size class , bulk density is an indicator of how well plant roots are able to extend into the soil . Bulk density is used to calculate porosity. Bulk density at a water tension of 1 /3 bar (33 kPa) is used for soil classification in the required characteristics for andic soil properties and in the criteria for Andic, Aquandic, and Vitrandic is subgroups . Factors Affecting Bulk Density Inherent - Bulk density is dependent on soil texture and the densities of soil mineral (sand , silt, and clay) and organic matter particles, as well as their packing arrangement. Generally, loose , porous soils and those rich in organic matter have lower bulk density. Sandy soils have relatively high bulk density since total pore space in sands is less than that of silt or clay soils . Finer-textured soils that have good structure , such as silt loams and clay loams, have higher pore space and lower bulk density compared to sandy soils . General relationship of soil bulk density to root growth based on soil texture 27 Custom Soil Resource Report Soil Texture Idea I bulk densities for plant growth (g/ Bulk densities that restrict root growth cm3) (glcm3) Sandy Less than 1 .60 More than 1 .80 Loamy Less than 1 .40 More than 1 .65 Clayey Less than 1 . 10 More than 1 .47 Dynamic - Bulk density is changed by crop and land management practices that affect soil cover, organic matter, soil structure , and/or porosity. Cultivation can result in compacted soil layers with increased bulk density. Livestock as well as the use of agricultural and construction equipment exert pressure that compacts the soil and reduces porosity, especially on wet soils . Freeze-thaw action in the soil can lead to lowered bulk density. Database Entries Methods: In general , there are two broad groupings of bulk density methods . One group is for soil materials coherent enough that a field sample can be removed , and the other group is for soils that are too fragile to remove a sample and therefore an excavation operation must be performed . In the former group, there are clod methods in which the sample has an undefined volume and is coated and then the volume is determined by submergence. Also under the former there are various methods in which a cylinder of known volume is obtained of soil sufficiently coherent that it remains in the cylinder. The detailed procedures are outlined in Soil Survey Investigations Report No. 42 , Soil Survey Laboratory Methods Manual , Version 5. 0 , November 2014 , USDA, NRCS . Bulk density, one-third bar is the oven-dried weight of the less than 2 millimeter soil material per unit volume of soil at a water tension of 1 /3 bar (33 kPa) . The bulk density of each soil horizon is expressed in grams per cubic centimeter of soil material . Three columns represent the low, representative value (RV), and high values expected in the soil horizon . Bulk density is used to convert the results of other soil measurements from a weight to a volume basis . Texture is given in the standard terms used by the U . S . Department of Agriculture . These terms are defined according to percentages of sand , silt, and clay in the fraction of the soil that is less than 2 millimeters in diameter. " Loam ," for example, is soil that is 7 to 27 percent clay, 28 to 50 percent silt, and less than 52 percent sand . If the content of particles coarser than sand is 15 percent or more, an appropriate modifier is added , for example, "gravelly. " The representative texture of each horizon is displayed . References: Soil Survey Staff. 2014. Kellogg Soil Survey Laboratory Methods Manual . Soil Survey Investigations Report No . 42 , Version 5. 0. R. Burt and Soil Survey Staff (ed . ). U . S. Department of Agriculture, Natural Resources Conservation Service. United State Department of Agriculture, Natural Resources Conservation Service. 2008. Soil Quality Indicators — Bulk Density. Volchko Y, Norrman J , Rosen , and Norberg T. 2014 . A minimum data set for evaluation the ecological soil functions in remediation ation projects . J Soils Sediments 14: 1850- 1860 . 28 Custom Soil Resource Report Report—Soil Health - Bulk Density and Texture Soil Health - Bulk Density and Texture—Weld County, Colorado, Southern Part Map symbol and Pct. of Horizon Depth USDA texture - RV Bulk density Bulk density Bulk density soil name map unit name (inches) 113 bar low 1 /3 bar RV 1 /3 bar high (glc m3) (g/cm3) (g/cm3) 69-Valent sand, g to 3 percent slopes Valent 85 A 0-5 Sand 1 .00 1 .63 1 .66 AC 5-12 Sand 1 .60 1 .64 1 .69 Cl 12-30 Sand 1 .58 1 .62 1 .67 C2 30-80 Sand 1 .00 1 .64 1 .67 Dailey 5 A 0-16 Loamy sand 1 .56 1 .62 1 .69 C 16-80 Loamy sand 1 .51 1 .54 1 . 58 Julesburg 5 A 0-5 Fine sandy loam 1 .43 1 .48 1 . 53 Bt1 5-10 Sandy loam 1 .47 1 .53 1 . 59 Bt2 10-31 Sandy loam 1 .49 1 .54 1 . 59 Cl 31 -46 Loamy sand 1 .48 1 .55 1 .62 O2 46-80 Sand 1 .50 1 .64 1 . 70 Vona 5 A 0-7 Sandy loam 1 .48 1 .56 1 .63 Bt1 7-12 Sandy loam 1 .59 1 .61 1 .63 Bt2 12- 15 Sandy loam 1 .50 1 .60 1 .62 Bk1 15-35 Fine sandy loam 1 .55 1 .58 1 .61 Bk2 35-48 Loamy sand 1 .54 1 .62 1 . 70 Bk3 48-80 Very fine sandy loam 1 .52 1 .56 1 . 59 29 Custom Soil Resource Report Soil Health - Bulk Density and Texture-Weld County, Colorado, Southern Part Map symbol and Pct. of Horizon Depth USDA texture - RV Bulk density Bulk density Bulk density soil name map unit name (inches) 113 bar low 1 /3 bar RV 113 bar high (glcm3) (glcm3) (g/cm3) 70-Valent sand , 3 to 9 percent slopes Valent 80 A 0-5 Sand 1 .60 1 .63 1 .66 AC 5-12 Sand 1 .58 1 .62 1 .65 Cl 12-30 Sand 1 .60 1 .63 1 .66 C2 30-80 Sand 1 .59 1 .63 1 .67 Dailey 10 A 0-14 Loamy sand 1 .61 1 .67 1 . 73 C 14-80 Sand 1 .58 1 .62 1 .67 Haxtun 5 Al 0-5 Loamy sand 1 .55 1 .60 1 .66 A2 5-12 Loamy sand 1 .49 1 .56 1 .62 Bt1 12-17 Sandy loam 1 .43 1 .52 1 .60 Bt2 17-24 Sandy clay loam 1 .43 1 .48 1 .53 Btbl 24-29 Sandy clay loam 1 .41 1 .46 1 . 51 Btb2 29-45 Clay loam 1 .37 1 .44 1 . 51 Bk 45-60 Loam 1 .50 1 .54 1 . 59 C 60-80 Sandy loam 1 .49 1 .64 1 . 78 Vona 5 A 0-7 Loamy sand 1 .45 1 .64 1 . 71 Bt1 7-14 Sandy loam 1 .55 1 .59 1 .61 Bt2 14-20 Sandy loam 1 .55 1 .65 1 .68 Bk 20-45 Sandy loam 1 .45 1 .59 1 .69 C 45-80 Loamy sand 1 .45 1 .58 1 .61 72-Vona loamy sand, 0 to 3 percent slopes Vona 85 H1 0-6 Loamy sand 1 .45 1 .53 1 .60 H2 6-28 Fine sandy loam 1 .40 1 .45 1 . 50 H3 28-60 Sandy loam 1 .45 1 .50 1 . 55 Remmit 10 - Valent 5 - Soil Health - Compaction , Surface Sealing Soil health is primarily influenced by human management, which is not captured in soil survey data at this time. These interpretations provide information on inherent soil properties that influence our ability to build healthy soils through management. The ratings are both verbal and numerical . Numerical ratings indicate the propensity of individual soil properties to influence specific aspects of soil health management. The ratings are shown in decimal fractions ranging from 0 . 01 to 1 . 00 . They indicate gradations between the point at which a soil feature has the greatest ability to 30 Custom Soil Resource Report enhance soil health ( 1 . 00 ) and the point at which the soil feature becomes least likely to enhance soil health (0. 00). The ratings forsoil susceptibility to compaction are based on soil properties in the upper 12 inches of soil . Factors considered are soil texture , soil organic matter content, soil structure, rock fragment content, and the existing bulk density. Each of these factors contributes to the soil's ability to resist compaction . Rating class terms indicate the potential for soil compaction . " Low" indicates that the potential for compaction is insignificant. Soils with a low rating can support standard equipment with minimal compaction . These soils are moisture insensitive, exhibiting only small changes in density with changing moisture content. " Medium" indicates that the potential for compaction is significant. The growth rate of seedlings may be reduced following compaction . After the initial compaction (i . e . , the first pass of equipment) , soils with a medium rating are able to support standard equipment with only minimal increases in soil density. These soils are intermediate between moisture insensitive and moisture sensitive . "High" indicates that the potential for compaction is significant. The growth rate of seedlings will be reduced following compaction . After initial compaction , soils with a high rating are still able to support standard equipment but will continue to compact with each subsequent pass . These soils are moisture sensitive , exhibiting large changes in density with changing moisture content. The ratings forsoil susceptibility to surface sealing are based on soil properties at the soil surface. They are applicable to conditions or times when the soil surface , or any portion of it, is exposed to the impact of raindrops and there is significant rain or sprinkler irrigation . Soil surfaces that are void of vegetative , canopy, residue, litter, or duff cover are the most vulnerable to surface sealing . Factors considered are exchangeable sodium , a silt/crusting index , water dispersible clay, and organic matter. Rating class terms indicate the soil's inherent potential to form a surface seal . "Low" indicates that the soil has a low inherent susceptibility to form a surface seal . These soils are not likely to form a surface seal . " Moderate" indicates that the soil has a moderate inherent susceptibility to form a surface seal . The potential to form a surface seal is significant. "High " indicates that the soil has a high susceptibility to form a surface seal . The inherent soil properties are highly conducive to forming a surface seal . Management that protects the soil from raindrop impact and minimizes soil disturbance helps prevent surface sealing . Plant and mulch cover can shield the soil from raindrop impact and so reduce sealing in otherwise susceptible soils . Soil management practices that increase organic matter content combined with the use of plant or residue cover for protection help prevent the formation of surface seals in most soils. Because tillage disrupts soil structure and aggregates , it accelerates the formation of seals . Management that minimizes soil disturbances and protects the soil from raindrop impact greatly increases infiltration and reduces runoff. Report—soil Health - Compaction, Surface Sealing [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 limitations for any given soil . The soil may have additional limitations] 31 Custom Soil Resource Report Soil Health - Compaction, Surface Sealing—Weld County, Colorado, Southern Part Map symbol and soil name Pct. of Soil Susceptibility to Surface Sealing Soil Susceptibilty to Compaction map unit Rating class and limiting Value Rating class and limiting Value features features 69—Valent sand , 0 to 3 percent slopes Valent 85 Low Low Rock fragments, 0-12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Bulk density-compactibility to 1 .00 30cm Organic matter content, 0-30 1 .00 cm Subaerial 1 .00 Dailey 5 Moderate Low Moderate silt/crusting potential 0.27 Rock fragments, 0- 12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Subaerial 1 .00 Organic matter content , 0- 30 0 .89 cm Bulk density-compactibility to 0 .58 30cm Julesburg 5 Low Medium Rock fragments, 0-12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Subaerial 1 .00 Organic matter content, 0-30 0 .86 cm Bulk density-compactibility to 0 .59 30cm Vona 5 Moderate Medium Moderate silt/crusting potential 0.63 Rock fragments, 0- 12 inches 1 .00 Moderate water dispersible 0.49 Soil structure grade, 0-12 1 .00 clay inches Moderate organic matter 0.45 Organic matter content , 0- 30 1 .00 relative to clay cm Subaerial 1 .00 Bulk density-compactibility to 0 .65 30cm 32 Custom Soil Resource Report Soil Health - Compaction, Surface Sealing—Weld County, Colorado, Southern Part Map symbol and soil name Pct. of Soil Susceptibility to Surface Sealing Soil Susceptibilty to Compaction map unit Rating class and limiting Value Rating class and limiting Value features features 70—Valent sand , 3 to 9 percent slopes Valent 80 Low Low Rock fragments, 0-12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Bulk density-compactibility to 1 .00 30cm Organic matter content, 0-30 1 .00 cm Subaerial 1 .00 Dailey 10 Moderate Low Moderate silt/crusting potential 0.27 Rock fragments, 0- 12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Subaerial 1 .00 Organic matter content , 0- 30 0 .89 cm Bulk density-compactibility to 0 . 16 30cm Haxtun 5 Moderate Low Moderate silt/crusting potential 0.23 Rock fragments, 0-12 inches 1 .00 Soil structure grade, 0-12 1 .00 inches Subaerial 1 .00 Organic matter content, 0-30 0 .89 cm Bulk density-compactibility to 0 .44 30cm Vona 5 Moderate Low Moderate water dispersible 0. 32 Rock fragments, 0- 12 inches 1 .00 clay Moderate silt/crusting potential 0.26 Soil structure grade, 0-12 1 .00 inches Organic matter content , 0-30 1 .00 cm Subaerial 1 .00 Bulk density-compactibility to 0 .67 30cm 33 Custom Soil Resource Report Soil Health - Compaction, Surface Sealing-Weld County, Colorado, Southern Part Map symbol and soil name Pct. of Soil Susceptibility to Surface Sealing Soil Susceptibilty to Compaction map unit Rating class and limiting Value Rating class and limiting Value features features 72—Vona loamy sand, 0 to 3 percent slopes Vona 85 Moderate Low Moderate water dispersible 0.45 Rock fragments, 0-12 inches 1 .00 clay Moderate organic matter 0.34 Soil structure grade, 0-12 1 .00 relative to clay inches Moderate silt/crusting potential 0.28 Organic matter content, 0-30 1 .00 cm Subaerial 1 .00 Bulk density-compactibility to 0 .70 30cm Remmit 10 Not rated Not rated Valent 5 Not rated Not rated Soil Physical Properties This folder contains a collection of tabular reports that present soil physical properties . The reports (tables) include all selected map units and components for each map unit. Soil physical properties are measured or inferred from direct observations in the field or laboratory. Examples of soil physical properties include percent clay, organic matter, saturated hydraulic conductivity, available water capacity, and bulk density. Engineering Properties This table gives the engineering classifications and the range of engineering properties for the layers of each soil in the survey area . Hydrologic soil group is a group of soils having similar runoff potential under similar storm and cover conditions . The criteria for determining Hydrologic soil group is found in the National Engineering Handbook, Chapter 7 issued May 2007(http:// d irectives .sc. egov. usda .gov/Open NanWebCantent. aspx?content= 17757.wba). Listing HSGs by soil map unit component and not by soil series is a new concept for the engineers . Past engineering references contained lists of HSGs by soil series . Soil series are continually► being defined and redefined , and the list of soil series names changes so frequently as to make the task of maintaining a single national list virtually impossible. Therefore , the criteria is now used to calculate the HSG using the component soil properties and no such national series lists will be maintained . All such references are obsolete and their use should be discontinued . Soil properties that influence runoff potential are those that influence the minimum rate of infiltration for a bare soil after prolonged welling and when not frozen . These properties are depth to a seasonal high water table , saturated hydraulic conductivity after prolonged wetting , and depth to a layer with a very slow water transmission 34 Custom Soil Resource Report rate. Changes in soil properties caused by land management or climate changes also cause the hydrologic soil group to change . The influence of ground cover is treated independently. There are four hydrologic soil groups , A, B, C , and D , and three dual groups, AID , BID , and C/D . In the dual groups , the first letter is for drained areas and the second letter is for undrained areas . The four hydrologic soil groups are described in the following paragraphs : Group A. Soils having a high infiltration rate (low runoff potential) when thoroughly wet. These consist mainly of deep , well drained to excessively drained sands or gravelly sands . These soils have a high rate of water transmission . Group B. Soils having a moderate infiltration rate when thoroughly wet. These consist chiefly of moderately deep or deep , moderately well drained or well drained soils that have moderately fine texture to moderately coarse texture . These soils have a moderate rate of water transmission . Group C. Soils having a slow infiltration rate when thoroughly wet. These consist chiefly of soils having a layer that impedes the downward movement of water or soils of moderately fine texture or fine texture. These soils have a slow rate of water transmission . Group D. Soils having a very slow infiltration rate (high runoff potential ) when thoroughly wet. These consist chiefly of clays that have a high shrink-swell potential , soils that have a high water table, soils that have a claypan or clay layer at or near the surface, and soils that are shallow over nearly impervious material . These soils have a very slow rate of water transmission. Depth to the upper and lower boundaries of each layer is indicated . Texture is given in the standard terms used by the U . S . Department of Agriculture . These terms are defined according to percentages of sand , silt, and clay in the fraction of the soil that is less than 2 millimeters in diameter. " Loam ," for example, is soil that is 7 to 27 percent clay, 28 to 50 percent silt, and less than 52 percent sand . If the content of particles coarser than sand is 15 percent or more, an appropriate modifier is added , for example, "gravelly. " Classification of the soils is determined according to the Unified soil classification system (ASTM , 2005) and the system adopted by the American Association of State Highway and Transportation Officials (AASHTO , 2004). The Unified system classifies soils according to properties that affect their use as construction material . Soils are classified according to particle-size distribution of the fraction less than 3 inches in diameter and according to plasticity index, liquid limit, and organic matter content. Sandy and gravelly soils are identified as GW, GP, GM , GC , SW, SP, SM , and SC ; silty and clayey soils as ML, CL, OL , MH , CH , and OH ; and highly organic soils as PT. Soils exhibiting engineering properties of two groups can have a dual classification , for example , CL-ML. The AASHTO system classifies soils according to those properties that affect roadway construction and maintenance. In this system , the fraction of a mineral soil that is less than 3 inches in diameter is classified in one of seven groups from A- 1 through A-7 on the basis of particle-size distribution , liquid limit, and plasticity index. Soils in group A- 1 are coarse grained and low in content of fines (silt and clay). At the other extreme , soils in group A-7 are fine grained . Highly organic soils are classified in group A-8 on the basis of visual inspection . If laboratory data are available , the A- 1 , A-2 , and A-7 groups are further classified as A- 1 -a, A- 1 -b , A-2-4 , A-2-5, A-2-6 , A►-2-7, A-7-5, or A-7-6. As an additional refinement, the suitability of a soil as subgrade material can be indicated by a group 35 Custom Soil Resource Report index number. Group index numbers range from 0 for the best subgrade material to 20 or higher for the poorest. Percentage of rock fragments larger than 10 inches in diameter and 3 to 10 inches in diameter are indicated as a percentage of the total soil on a dry-weight basis . The percentages are estimates determined mainly by converting volume percentage in the field to weight percentage. Three values are provided to identify the expected Low (L), Representative Value (R), and High ( H ). Percentage (of soil particles) passing designated sieves is the percentage of the soil fraction less than 3 inches in diameter based on an ovendry weight. The sieves , numbers 4, 10 , 40, and 200 (USA Standard Series), have openings of 4. 76, 2 . 00, 0 .420 , and 0 .074 millimeters , respectively. Estimates are based on laboratory tests of soils sampled in the survey area and in nearby areas and on estimates made in the field . Three values are provided to identify the expected Low ( L), Representative Value (R), and High (H ). Liquid limit and plasticity index (Atterberg limits) indicate the plasticity characteristics of a soil . The estimates are based on test data from the survey area or from nearby areas and on field examination . Three values are provided to identify the expected Low (L) , Representative Value ( R), and High (H ) . References : American Association of State Highway and Transportation Officials (AASHTO). 2004. Standard specifications for transportation materials and methods of sampling and testing . 24th edition . American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes . ASTM Standard D2487-00 . 36 Custom Soil Resource Report Absence of an entry indicates that the data were not estimated . The asterisk '*' denotes the representative texture; other possible textures follow the dash . The criteria for determining the hydrologic soil group for individual soil components is found in the National Engineering Handbook, Chapter 7 issued May 2007(http : //directives. sc. egov. usda . gov/ OpenNonWebContent. aspx?content= 17757.wba). Three values are provided to identify the expected Low ( L), Representative Value ( R), and High (H ). 37 Custom Soil Resource Report Engineering Properties—Weld County, Colorado, Southern Part Map unit symbol and Pet of Hydrolo Depth USDA texture Classification Pet Fragments Percentage passing sieve number— Liquid Plasticit soil name map gic limit y index unit group Unified AASHTO '10 3-10 4 10 40 200 inches inches in L-R-H L-R-H L-R-H L-R-h► L-R-H L-R-H L-R-H L-R-H 69—Valent sand , 0 to 3 percent slopes Valent 85 A 0-5 Sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 100- 100 74-77- 7- 9- 12 0-0 -22 NP-0 -3 -100 - 100 81 5-12 Sand, loamy sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 73-77- 6- 8- 14 0-0 -21 NP-0 -4 -100 100 83 12-30 Sand, loamy sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 73-77- 6- 8- 14 0-0 -20 NP-0 -4 -100 100 83 30-80 Loamy sand, sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 73-77- 6- 8- 14 0-0 -20 NP-0 -4 -100 100 83 Dailey 5 A 0-16 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 100-100 100- 100 75-79- 24-29- 0-19 -25 NP-2 -3 -100 - 100 87 32 16-80 Loamy sand, sand SM A-2-4 0- 0- 0 0- 0- 0 100-100 95-97-1 72-76- 25-27- 0-16 -20 NP-2 -3 -100 00 82 32 Julesburg 5 A 0-5 Fine sandy loam, SC-SM A-4 0- 0- 0 0- 0- 0 92-100- 83-100- 72-91 - 30-41 - 0-26 -31 NP-6 -7 loamy sand, sandy 100 100 95 45 loam 5-10 Fine sandy loam, SC A-4 0- 0- 0 0- 0- 0 92-100- 84-100- 61 -77- 29-39- 23-28 6-9 -12 sandy loam 100 100 81 43 -32 10-31 Sandy loam, fine SC-SM A-4 0- 0- 0 0- 0- 0 92-100- 84-100- 61 -77- 29-38- 21 -26 4-7 -10 sandy loam 100 100 81 42 -31 31 -46 Loamy sand, fine SM A-2-4 0- 0- 0 0- 0- 0 92-100- 84-100- 63-80- 22-31 - 0-19 -20 NP-3 -3 sand, sand 100 100 81 32 38 Custom Soil Resource Report Engineering Properties—Weld County, Colorado, Southern Part Map unit symbol and Pct. of Hydrolo Depth USDA texture Classification Pct Fragments Percentage passing sieve number— Liquid Plasticit soil name map gic limit y index unit group Unified AASHTO >10 3-10 4 10 40 200 inches inches In L -R-H L-,R-/-/ L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H 46-80 Loamy sand, fine SP-SM A-3 0- 0- 0 0- 0- 0 92-100- 85-100- 63-76- 5- 8- 12 0-0 -20 NP-0 -3 sand , sand 100 100 80 Vona 5 A 0-7 Sandy loam SC-SM A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 72-77- 33-39- 17-21 2-4 -6 -100 - 100 84 44 -24 7-12 Sandy loam SC A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 74-78- 37-44- 20-26 4-8 -9 -100 - 100 86 49 -28 12-15 Sandy loam SC A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 73-78- 36-43- 19-27 3-9 -11 -100 - 100 86 49 -29 15-35 Sandy loam, fine SC A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 84-93-1 35-42- 17-24 2-8 -11 sandy loam -100 - 100 00 55 -28 35-48 Loamy sand, loamy SM A-2-4 0- 0- 0 0- 0- 0 100- 100 100- 100 68-77- 20-24- 0-0 -26 NP-0 -9 fine sand , sandy -100 - 100 90 42 loam 48-80 Loamy sand, sandy CL A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 81 -92-1 37-53- 0-22 -26 NP-8 -9 loam, very fine -100 - 100 00 59 sandy loam 39 Custom Soil Resource Report Engineering Properties—Weld County, Colorado, Southern Part Map unit symbol and Pet of Hydrolo Depth USDA texture Classification Pet Fragments Percentage passing sieve number— Liquid Plasticit soil name map gic limit y index unit group Unified AASHTO '10 3-10 4 10 40 200 inches inches in L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H L-R-H 70—Valent sand , 3 to 9 percent slopes Valent 80 A 0-5 Sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 100- 100 74-77- 7- 9- 12 0-0 -19 NP-0 -3 -100 - 100 81 5-12 Sand, loamy sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 72-77- 6- 8- 14 0-0 -21 NP-0 -4 -100 100 83 12-30 Sand, loamy sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 72-77- 6- 8- 14 0-0 -20 NP-0 -4 -100 100 83 30-80 Sand, loamy sand SP-SM A-3 0- 0- 0 0- 0- 0 100-100 97-100- 72-77- 6- 8- 14 0-0 -20 NP-0 -4 -100 100 83 Dailey 10 A 0-14 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 100-100 100- 100 74-80- 23-31 - 0-21 -24 NP-2 -3 -100 - 100 85 34 14-80 Fine sand , loamy SP-SM A-3 0- 0- 0 0- 0- 0 100-100 95-97-1 67-75- 5- 8- 17 0-0 -19 NP-0 -3 sand, sand -100 00 84 Haxtun 5 C 0-5 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 100-100 92-100- 68-80- 22-31 - 0-22 -26 NP-3 -4 -100 100 85 34 5-12 Loamy sand, sandy SM A-2-4 0- 0- 0 0- 0- 0 100-100 92-100- 68-80- 22-31 - 0-22 -29 NP-3 -7 loam -100 100 88 39 12-17 Sandy loam, sandy SC A-6 0- 0- 0 0- 0- 0 100-100 92-100- 66-77- 32-39- 29-32 10- 12- 1 clay loam -100 100 86 49 -42 8 17-24 Sandy loam, sandy CL A-6 0- 0- 0 0- 0- 0 100-100 91 -100- 75-90- 38-50- 28-37 9-16-18 clay loam -100 100 97 56 -42 24-29 Loam, clay loam, CL A-6 0- 0- 0 0- 0- 0 100-100 91 -100- 74-90-1 41 -54- 28-39 9-17-23 sandy clay loam -100 100 00 67 -47 29-45 Sandy clay loam, CL A-7-6 0- 0- 0 0- 0- 0 100-100 91 -100- 76-93-1 53-73- 28-41 9-19-23 loam, clay loam -100 100 00 80 -47 45-60 Loam, sandy loam, CL A-4 0- 0- 0 0- 0- 0 100-100 92-100- 74-93-1 45-66- 0-26 -35 NP-9 sandy clay loam -100 100 00 71 -17 40 Custom Soil Resource Report Engineering Properties—Weld County, Colorado, Southern Part Map unit symbol and Pct. of Hydrolo Depth USDA texture Classification Pct Fragments Percentage passing sieve number— Liquid Plasticit soil name map gic limit y index unit group Unified AASHTO >10 3-10 4 10 40 200 inches inches In L-R-H L-R-H L-R-H L-R-H L-R-H L-J4-H L-R-H L-J4-H 60-80 Sandy loam, loam , SC-SM A-4 0- 0- 0 0- 0- 0 93-98-1 85-95-1 58-73- 26-37- 0-23 -35 NP-6 loamy sand 00 00 87 53 -17 Vona 5 A 0-7 Loamy sand SM A-2-4 0- 0- 0 0- 0- 0 100- 100 100- 100 72-78- 20-24- 0-18 -22 NP-2 -4 -100 - 100 85 30 7-14 Sandy loam, fine SC A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 70-77- 32-39- 19-25 3-8 -11 sandy loam -100 - 100 84 45 -29 14-20 Fine sandy loam, SC-SM A-4 0- 0- 0 0- 0- 0 100- 100 100- 100 71 -78- 32-40- 19-22 3-6 -11 sandy loam -100 - 100 85 45 -29 20-45 Sandy loam, fine SC-SM A-4 0- 0- 0 0- 0- 0 100- 100 92-100- 63-77- 27-40- 0-20 -26 NP-4 -9 sandy loam , loamy -100 100 86 46 sand 45-80 Loamy sand, loamy SM A-2-4 0- 0- 0 0- 0- 0 100-100 92-100- 63-78- 17-25- 0-0 -26 NP-0 -9 fine sand , sandy -100 100 86 36 loam 72—Vona loamy sand, 0 to 3 percent slopes Vona 85 A 0-6 Loamy sand SM A-2 0- 0- 0 0- 0- 0 100-100 100- 100 50-63- 15-23- - NP -100 - 100 75 30 6-28 Fine sandy loam, SC , SC- A-2, A-4 0- 0- 0 0- 0- 0 100-100 90-95-1 60-75- 30-38- 20-25 NP-5 sandy loam SM , SM -100 00 90 45 -30 -10 28-60 Sandy loam, loamy SC-SM, A-2, A-4 0- 0- 0 0- 0- 0 100-100 90-95-1 50-68- 15-28- 20-23 NP-3 -5 sand , loamy fine SM -100 00 85 40 -25 sand 41 Custom Soil Resource Report Particle Size and Coarse Fragments This table shows estimates of particle size distribution and coarse fragment content 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 . Total fragments is the content of fragments of rock and other materials larger than 2 millimeters in diameter on volumetric basis of the whole soil . Fragments 2-74 mm refers to the content of coarse fragments in the 2 to 74 millimeter size fraction . Fragments 75-249 mm refers to the content of coarse fragments in teh 75 to 249 millimeter size fraction . Fragments 250-599 mm refers to the content of coarse fragments in the 250 to 599 millimeter size fraction . Fragments >=600 mm refers to the content of coarse fragments in the greater than or equal to 600 millimeter size fraction . Reference: United States Department of Agriculture, Natural ResourcesConservation Service. National soil survey handbook, title 430-VI . (http://soils . usda .gov) 42 Custom Soil Resource Report Particle Size and Coarse Fragments—Weld County, Colorado, Southern Part Map symbol and Horizon Depth Sand Silt Clay Total fragments Fragments 2-74 Fragments 75-249 Fragments Fragments soil name mm mm 250-599 mm >=600 mm In L-RV-H L-RV-H L-RV-H Pct RV Pct RV Pct RV Pct RV Pct RV Pct Pct Pct 69—Valent sand , 0 to 3 percent slopes Valent A 0-5 88-96- 96 1 - 2- 6 2- 3- 6 — — — — — AC 5- 12 82-97- 98 1 - 2- 12 1 - 2- 8 0 0 — — — Cl 12-30 82-97- 98 1 - 2- 12 1 - 2- 8 0 0 — — — C2 30-80 82-97- 98 1 - 2- 12 1 - 2- 8 0 0 — — — r70 Valent sand , 3 to 9 percent slopes Valent A 0-5 88-96- 96 1 - 2- 6 2 3- 6 — — — — — AC 5- 12 80-97- 98 1 - 2- 12 1 - 2- 8 0 0 — — — Cl 12-30 80-97- 98 1 - 2- 12 1 - 2- 8 0 0 — — — C2 30-80 80-97- 98 1 - 2- 12 1 - 2 8 0 0 — — — 72—Vona loamy sand, 0 to 3 percent slopes Vona H1 0-6 -85- - 9- 3 6- 8 — — — — — H2 6-28 -67- -20- 8-13- 18 3 3 — — — H3 28-60 -67- -24- 3- 9- 15 3 3 — — — 43 Custom Soil Resource Report 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 . 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. 44 Custom Soil Resource Report 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 113- 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 KU 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 (LISLE) 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. 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. " 45 Custom Soil Resource Report Wind erod'ibility 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) 46 Custom Soil Resource Report Three values are provided to identify the expected Low (L) , Representative Value ( R) , and High (H ) . 47 Custom Soil Resource Report Physical Soil Properties—Weld County, Colorado, Southern Part Map symbol Depth Sand Silt Clay Moist Saturated Available Linear Organic Erosion Wind Wind and soil name bulk hydraulic water extensibility matter factors erodibility erodibility density conductivity capacity group index Kw Kf T in Pct Pct Pct g/cc micro m/sec Ire/Ire Pct Pct 69—Valent sand, 0 tO 3 percent slopes Valent 0-5 88-96- 96 1 - 2- 6 2- 3- 6 1 .60- 1 .63- 141 . 14-211 .50-2 0.04-0 .04-0.0 0. 1 - 0.2- 0 .5 0. 5- 0 .9- .02 .02 5 1 220 1 .66 82.00 5 2 .0 5-12 82-97- 98 1 - 2- 12 1 - 2- 8 1 .60- 1 .64- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .7 0. 1 - 0 .5- .02 .02 1 .69 2.00 1 1 .0 12-30 82-97- 98 1 - 2- 12 1 - 2- 8 1 . 58- 1 .62- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .6 0. 1 - 0 .2- .02 .02 1 .67 2.00 1 0 .5 30-80 82-97- 98 1 - 2- 12 1 - 2- 8 1 .60- 1 .64- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .6 0.0- 0 . 1 - .02 .02 1 .67 2.00 1 0.5 Dailey 0-16 77-80- 85 10- 17- 19 2- 4- 7 1 . 56- 1 .62- 42.34-91 .74-14 0.08-0 . 11 -0 . 1 0.2- 0. 3- 0 .7 1 .0- 2 .0- . 15 . 15 5 2 134 1 .69 1 . 14 1 3 .0 16-80 77-80- 95 4-16- 19 1 - 4- 7 1 . 51 - 1 .54- 42.34-91 .74-28 0.08-0 . 11 -0 . 1 0. 1 - 0.2- 0 .6 0. 1 - 0 .5- . 15 . 15 1 .58 2.00 1 1 .0 Julesburg lesbu rg 0-5 66-70- 86 4-22- 25 3- 8- 12 1 .43- 1 .48- 14. 11 -28.23- 141 0.07-0 . 14-0. 1 0.2- 0.8- 1 .2 2.0- 3 .0- .20 .20 3 3 86 1 .53 . 14 5 4 .0 5-10 55-67- 78 10- 19- 30 10- 14- 18 1 .47- 1 .53- 14. 11 -28.23-42. 0. 10-0 . 11 -0 . 1 0.9- 1 .4- 1 .9 1 .0- 1 .5- .20 .20 1 .59 34 4 2 .0 10-31 57-68- 77 10-20- 30 8-12- 16 1 .49- 1 .54- 14. 11 -28.23-42. 0. 10-0 . 11 -0 . 1 0.7- 1 .2- 1 .7 1 .0- 1 .5- .24 .24 1 .59 34 4 2.0 31 -46 77-78- 95 2-16- 20 1 - 6- 7 1 .48- 1 .55- 42.34-91 .74-28 0.04-0 .08-0. 1 0. 1 - 0. 5- 0 .6 0. 5- 0 .8- .24 .24 1 .62 2.00 1 1 .0 48 Custom Soil Resource Report Physical Soil Properties—Weld County, Colorado, Southern Part Map symbol Depth Sand Silt Clay Moist Saturated Available Linear Organic Erosion Wind Wind and soil name bulk hydraulic water extensibility matter factors erodibility credibility density conductivity capacity group index Kw Kf T In Pct Pct Pct g/cc micro m/sec fry/try Pct Pct 46-80 80-966- 08 1 - 1 - 15 1 - 3- 7 1 . 59- 1 .64- 42. 34-211 . 50-28 0 .04-0 .04-0. 1 0 . 1 - 0 .2- 0 .0 0. 5- 0 .8- .02 .02 1 . 70 2.00 1 1 .0 Vona 0-7 62-68- 75 17-24- 30 5- 8- 10 1 .48- 1 . 56- 14. 11 -28 .23-42. 0 . 12-0 . 12-0. 1 0 .4- 0 .8- 1 .0 0. 5- 1 .0- .20 .20 5 3 86 1 .63 34 3 1 .5 7- 12 60-62- 75 15-24- 30 8-14- 15 1 . 59- 1 .61 - 14. 11 -28 .23-42. 0 . 11 -0. 11 -0 . 1 0 .7- 1 .4- 1 .6 0. 5- 0 .5- .24 .24 1 .63 34 3 1 .0 12- 15 60-63- 75 15-21 - 30 8-16- 17 1 . 59- 1 .60- 14. 11 -28 .23-42. 0 . 11 -0. 11 -0 . 1 0 .6- 1 . 5- 1 . 7 0. 5- 0 .5- .24 .24 1 .62 34 3 1 .0 15-35 80-87- 75 10-20- 30 8-13- 17 1 . 55- 1 . 58- 14. 11 -28 .23-42. 0 . 10-0 . 11 -0 . 1 0 .4- 1 . 1 - 1 . 5 0. 0- 0 .4- .28 .28 1 .61 34 3 0 .5 35-48 60-85- 80 5-11 - 30 3- 4- 15 1 . 54- 1 .62- 14. 11 -91 . 74- 141 0 .08-0 . 11 -0 . 1 0 .0- 0 .2- 1 .2 0. 0- 0 .3- . 15 . 15 1 . 70 . 14 3 0 .5 48-80 60-64- 80 5-25- 30 3-11 - 15 1 . 52- 1 . 56- 14. 11 -28 .23- 141 0 .08-0 . 15-0. 1 0 .0- 0 .9- 1 .2 0. 0- 0 . 1 - .32 . 32 1 . 59 . 14 5 0 .5 49 Custom Soil Resource Report Physical Soil Properties-Weld County, Colorado, Southern Part Map symbol Depth Sand Silt Clay Moist Saturated Available Linear Organic Erosion Wind Wind and soil name bulk hydraulic water extensibility matter factors erodibility erodibility density conductivity capacity group index Kw Kf T in Pct Pct Pct g/cc micro m/sec Ire/Ire Pct Pct 70-Valent sand, 3 to 9 percent slopes Valent 0-5 88-96- 96 1 - 2- 6 2- 3- 6 1 .60- 1 .63- 141 . 14-211 .50-2 0.04-0 .04-0.0 0. 1 - 0.2- 0 .5 0. 5- 0 .9- .02 .02 5 1 220 1 .66 82.00 5 1 .0 5-12 80-97- 98 1 - 2- 12 1 - 2- 8 1 . 58- 1 .62- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .7 0. 1 - 0 .5- .02 .02 1 .65 2.00 1 1 .0 12-30 80-97- 98 1 - 2- 12 1 - 2- 8 1 .60- 1 .63- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .6 0. 1 - 0 .2- .02 .02 1 .66 2.00 1 0 .5 30-80 80-97- 98 1 - 2- 12 1 - 2- 8 1 . 59- 1 .63- 42.34-211 .50-28 0.04-0 .04-0. 1 0.0- 0. 1 - 0 .6 0.0- 0 . 1 - .02 .02 1 .67 2.00 1 0.5 Dailey 0-14 75-78- 90 5-17- 23 2- 5- 6 1 .61 - 1 .67- 42.34-91 .74-14 0.07-0 . 10-0. 1 0.2- 0. 5- 0 .6 1 .0- 2 .0- . 15 . 15 5 2 134 1 .73 1 . 14 1 3 .0 14-80 75-96- 98 0- 2- 20 1 - 2- 6 1 . 58- 1 .62- 42.34-211 .50-28 0.04-0 .04-0. 1 0. 1 - 0. 1 - 0 .5 0. 1 - 0 .5- .02 .02 1 .67 2.00 1 1 .0 Haxtun 0-5 75-78- 88 5-16- 20 2- 6- 8 1 . 55- 1 .60- 42.34-91 .74-14 0.07-0 .08-0. 1 0. 1 - 0.6- 0 .8 1 .0- 2 .0- .24 .24 5 2 134 1 .66 1 . 14 1 3 .0 5-12 65-78- 88 5-16- 30 2- 6- 12 1 .49- 1 .56- 14. 11 -91 . 74- 141 0.07-0 .08-0. 1 0.0- 0.6- 1 . 1 1 .0- 2 .0- .24 .24 1 .62 . 14 4 3 .0 12- 17 55-67- 75 10- 15- 28 17- 18- 26 1 .43- 1 .52- 423-28 .23-42 .3 0. 10-0 . 10-0. 1 1 .6- 1 .9- 3A 1 .0- 2 .0- .20 .20 1 .60 4 3 3.0 17-24 55-59- 75 10-18- 28 17-23- 26 1 .43- 1L48- 4 .23-9. 17-42.34 0. 10-0 . 12-0. 1 1 .4- 2.8- 3 .2 1 .0- 2 .0- .24 .24 1 .53 3 3.0 24-29 30-55- 60 10- 17- 45 20-28- 34 1 .41 - 1 .46- 1 .41 -2.82- 14. 11 0. 12-0 . 13-0. 1 1 .3- 3. 1 4 .0 0. 5- 1 .3- .24 .24 1 .51 7 2 .0 29-45 30-34- 60 10-36- 45 20-30- 34 1 .37- 1 .44- 1 .41 -2.82- 14. 11 0. 12-0 . 16-0. 1 1 .3- 3.3- 4 . 1 0. 5- 1 .3- .32 .32 1 .51 7 2 .0 45-60 40-44- 75 10-40- 45 8-16- 25 1 . 50- 1 .54- 4 .23-28 .23-42 .3 0. 10-0 . 14-0. 1 0.0- 1 .3- 2 .2 0.0- 0 .3- .43 .43 1 .59 4 7 0 .5 50 Custom Soil Resource Report Physical Soil Properties—Weld County, Colorado, Southern Part Map symbol Depth Sand Silt Clay Moist Saturated Available Linear Organic Erosion Wind Wind and soil name bulk hydraulic water extensibility matter factors erodibility credibility density conductivity capacity group index Kw Kf T In Pct Pct Pct g/cc micro m/sec fry/Ire Pct Pct 60-80 40-07- 85 5-19- 40 8-14- 25 1 .49- 1 .64- 4 .23-28 .23-141 . 0.07-0 . 11 -0 . 1 0.0- 0. 7- 2 .2 0.0- 0 .3- .24 .24 1 . 78 14 7 0 .5 Vona 0-7 75-85- 90 5-10- 20 3- 5- 8 1 .45- 1 .64- 42. 34-91 .74-14 0 .08-0 . 10-0. 1 0 .0- 0 .4- 0 .0 0. 5- 1 .0- . 15 . 15 5 2 134 1 . 71 1 . 14 1 1 .3 7- 14 55-67- 75 10-20- 30 8-13- 17 1 . 55- 1 . 59- 14. 11 -28 .23-42. 0 . 10-0 . 11 -0 . 1 0 .6- 1 . 3- 1 .6 0. 5- 0 .8- .24 .24 1 .61 34 4 1 .0 14-20 55-67- 75 10-23- 30 8-10- 17 1 . 55- 1 .65- 14. 11 -28 .23-42. 0 . 10-0 . 11 -0 . 1 0 .6- 1 .0- 1 .6 0. 3- 0 .5- .28 .28 1 .68 34 4 0 .8 20-45 60-67- 90 5-23- 30 3-10- 15 1 .45- 1 . 59- 14. 11 -28 .23- 141 0 .07-0 . 12-0. 1 0 .0- 0 .6- 1 .2 0. 0- 0 .3- .28 .28 1 .69 . 14 5 0 .5 45-80 00-84- 90 5-11 - 30 3- 5- 15 1 .45- 1 . 58- 14. 11 -91 . 74- 141 0 .07-0 . 10-0. 1 0 .0- 0 .2- 1 .2 0. 0- 0 . 1 - .20 .20 1 .61 . 14 4 0 .5 72—Vona loamy sand , 0 to 3 percent slopes Vona 0-6 -85- - !- 3- 0- 8 1 .45- 1 .53- 42.00-92 .00-14 0 .06-0 .07-0.0 0.0- 1 . 5- 2 .9 0. 5- 0 .8- . 15 . 15 5 2 134 1 .60 1 .00 8 1 .0 6-28 -67- -20- 8-13- 18 1 .40- 1 .45- 14. 11 -28 .00-42. 0. 12-0 . 13-0. 1 0.0- 1 .5- 2 .9 0. 5- 0 .8- .28 .28 1 . 50 33 4 1 .0 28-60 -67- -24- 3- 9- 15 1 .45-1 .50- 14.00-78.00-14 0.06-0 . 10-0. 1 0,0- 1 .5- 2 .9 0.0- 0.3 .28 .28 1 .55 1 .00 3 0.5 Remmit — — — — — Valent — — — ... — , . 51 Custom Soil Resource Report Soil Qualities and Features This folder contains tabular reports that present various soil qualities and features . The reports (tables) include all selected map units and components for each map u nit. Soil qualities are behavior and performance attributes that are not directly measured , but are inferred from observations of dynamic conditions and from soil properties . Example soil qualities include natural drainage, and frost action . Soil features are attributes that are not directly part of the soil . Example soil features include slope and depth to restrictive layer. These features can greatly impact the u se and management of the soil . soil Features This table gives estimates of various soil features . The estimates are used in land u se 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 ( Ks at) , 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 u ncoated 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 52 Custom Soil Resource Report 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 . 53 Custom Soil Resource Report Soil Features-Weld County, Colorado , Southern Part Map symbol and Restrictive Layer Subsidence Potential for frost Risk of corrosion soil name action Kind Depth to Thickness Hardness Initial Total Uncoated steel Concrete top Low-RV- Range Low- Low- High High High In In In In 69—Valent sands 0 to 3 percent slopes Valent — — 0 0 Low Low Low 70—Valent sand , 3 to 9 percent slopes Valent — — 0 0 Low Low Low 72—Vona loamy sand, 0 to 3 percent slopes Vona — — 0 — Low High Moderate 54 References American Association of State Highway and Transportation Officials (AASHTO) . 2004. Standard specifications for transportation materials and methods of sampling and testing . 24th edition . American Society for Testing and Materials (ASTM). 2005. Standard classification of soils for engineering purposes . ASTM Standard D2487-00 . Cowardin , L. M . , V. Carter, F. C . Golet, and E.T. LaRoe. 1979 . Classification of wetlands and deep-water habitats of the United States . U .S . Fish and Wildlife Service FWS/OBS-79/31 . Federal Register. July 13, 1994 . Changes in hydric soils of the United States . Federal Register. September 18 , 2002. Hydric soils of the United States . Hurt, G .W. , and L . M . Vasilas , editors. Version 6 .0 , 2006. Field indicators of hydric soils in the United States . National Research Council . 1995. Wetlands : Characteristics and boundaries . Soil Survey Division Staff. 1993. Soil survey manual . Soil Conservation Service . U . S . Department of Agriculture Handbook 18. http://www. nres . usda.gov/wps/portal! nres/detail/national/soils/?cid =nres142p2_054262 Soil Survey Staff. 1999. Soil taxonomy: A basic system of soil classification for making and interpreting soil surveys . 2nd edition . Natural Resources Conservation Service , U . S . Department of Agriculture Handbook 436 . http :// www. arcs . usd a.gov/wps/portal/nres/detail/national/soils/?cid=n res 142p2_053577 Soil Survey Staff. 2010. Keys to soil taxonomy. 11th edition . U . S . Department of Agriculture, Natural Resources Conservation Service. http:// www. arcs . usd a.gov/wps/portal/nres/detail/national/soils/?cid=n res 142p2_O5358O Tiner, R .W. , Jr. 1985 . Wetlands of Delaware. U . S. Fish and Wildlife Service and Delaware Department of Natural Resources and Environmental Control , Wetlands Section . United States Army Corps of Engineers , Environmental Laboratory. 1987 . Corps of Engineers wetlands delineation manual . Waterways Experiment Station Technical Report Y-87- 1 . United States Department of Agriculture, Natural Resources Conservation Service. National forestry manual . http://www. nres . usda.gov/wps/portal/nres/detail/soils/ home/?cid= arcs 142p2_O53374 United States Department of Agriculture, Natural Resources Conservation Service. National range and pasture handbook. http ://www.nres . usda .gov/wps/portal/arcs/ detail/national/land u s e/rang ep astu re/?cid =stel p rd b 10430 84 55 Custom Soil Resource Report UnitedStates Department of Agriculture, Natural Resources Conservation Service . National soil survey handbook, title 430-VI . http ://www.nrcs. usda .goviwpsiportali arcs/d etai I/soils/scientists/?cid = nres l 42 p2_054242 United States Department of Agriculture, Natural Resources Conservation Service. 2006. Land resource regions and major land resource areas of the United States, the Caribbean , and the Pacific Basin . U .S. Department of Agriculture Handbook 296 . http : //www. nres . usda . goviwpslportal/nres/detailinationallsoils/? cid =nrcs142p2_053624 res 142 p2_6 63624 United States Department of Agriculture, Soil Conservation Service . 1961 . Land capability classification. U .S . Department of Agriculture Handbook 210. http:// www. nrcs . usda.gov/InternetiFSE_DOCUMENTS/nrcs142p2_052290. pdf 56 Soil Map—Weld County, Colorado, Southern PartIn m (Platteville Terminal Site ) en 531300 531400 531500 531600 531700 531800 531900 5' 40° 12' 17" M is ! �• F .• : i,, . I 40° 12' 17" N . ,,;. ti 0 t ti r'_'" 1 1 • 1' , ' y, '*.• • r , Ira i r' • 41.I" ' yl It. . - - Ail' Teri }I'. �•� ). J�<tl� .. _ • / ri V••• I 'te r r 17/ 'L } ♦1 J J f.�1�F-1.)11&1/....C.410604, ..,' T �ti 7�• �c,��Iy�,,�, •r. <�''i• I ` f ti r 'Tir": •i a�.T1 f, 1.1 L • `' — v�{u`••' at' a.. yprk+ 'tt41�I JL- - w a , j. /�.♦� _-' a 1--5,7>4.", I„,. • ! . ' r - t -.... T -__ '_'7s3)'}[ -� . `�hn' 11 L_I:1},.---Y it--. . ,.� _t �— 1 .•�y, C. 1 .. ywll - r 1 1 X1 19116-sicr- at-es.= t �_ " 1 .Ti ,", ti j • v S! N - _ E r I. f • a . •.f• ■ " ' I. Via^ T n I • MI. .: tl_ - ,1 . 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Map Scale: 1 :5,440 if printed on A portrait (83' x 11") shed. `'f' Meters 6 N 0 50 100 200 300 i\A 0 I Feet 250 500 1000 1500 Map p -lion : Wab Mercator Corner coordinates: WG584 Edge tics: UTM Zone 13N WG584 USDA Natural Resources Web Soil Survey 11 / 12/2019 a Conservation Service National Cooperative Soil Survey Page 1 of 3 Soil Map—Weld County, Colorado, Southern Part (Platteville Terminal Site ) MAP LEGEND MAP INFORMATION Area of Interest (AOl) gi Spoil Area The soil surveys that comprise your AOI were mapped at Area of Interest (AOI0 1 :24,000 . Stony Spot Soils Very Stony Spot Warning : Soil Map may not be valid at this scale. Soil Map Unit Polygons Wet Spot Enlargement of maps beyond the scale of mapping can cause Lit,- Soil Map Unit Lines misunderstanding of the detail of mapping and accuracy of soil Other line placement. The maps do not show the small areas of p Soil Map Unit Points contrasting soils that could have been shown at a more detailed Special Point Features 4, a Special Line Features scale. Blowout Water Features ti4liStreams and Canals Please rely on the bar scale on each map sheet for map 312t Borrow Pit measurements. Transportation Clay Spot Rails Source of Map : Natural Resources Conservation Service -HetClosed Depression Web Soil Survey URL : omits Interstate Highways Coordinate System: Web Mercator (EPSG :3857) 'iti-r Gravel Pit US Routes Maps from the Web Soil Survey are based on the Web Mercator Gravelly Spot Major Roads projection , which preserves direction and shape but distorts distance and area. A projection that preserves area, such as the Landfill Local Roads Albers equal-area conic projection, should be used if more Lava Flow accurate calculations of distance or area are required . Background .r, Marsh or swamp Aerial Photography This product is generated from the USDA-NRCS certified data as of the version date(s) listed below. Mine or Quarry Soil Survey Area: Weld County, Colorado, Southern Part ii'', Miscellaneous Water Survey Area Data : Version 18, Sep 13, 2019 O Perennial Water Soil map units are labeled (as space allows) for map scales r .z Rock Outcrop 1 :50,000 or larger. Saline Spot Date(s) aerial images were photographed: Jul 17, 2015—Oct 2, 2017 Sandy Spot The orthophoto or other base map on which the soil lines were Severely Eroded Spot compiled and digitized probably differs from the background Sinkhole imagery displayed on these maps. As a result, some minor shifting of map unit boundaries may be evident. 'Ra Slide or Slip Sodic Spot USDA Natural Resources Web Soil Survey 11 / 12/2019 a Conservation Service National Cooperative Soil Survey Page 2 of 3 Soil Map—Weld County, Colorado, Southern Part Platteville Terminal Site Map Unit Legend Map Unit Symbol Map Unit Name Acres in AOI Percent of AOI 69 Valent sand, 0 to 3 percent 8 . 1 5.6% slopes 70 Valent sand, 3 to 9 percent 57 .6 40. 1 % slopes 72 Vona loamy sand, 0 to 3 77 .9 54.2% percent slopes Totals for Area of Interest 143.5 100.0% USDA Natural Resources Web Soil Survey 11 / 12/2019 r Conservation Service National Cooperative Soil Survey Page 3 of 3 Hello