ANALYSIS OF HYDROLOGICAL EROSION RISK FOR THE ST. MARY BASIN, MONTANA, USASilvia VittozziMaster di 2° Livello in “GIS e telerilevamento per la pianificazione Geoambientale”UNIVERSITA’ DEGLI STUDI DI ROMA “ROMA TRE”30 Giugno, 2008

THE PURPOSE OF RESEARCHIS TO ESTIMATE THE MOST EXPOSED AREAS TO SOIL EROSION IN THE UPPER ST. MARY BASIN, MONTANA, USA12/10/20092

WATERTON-GLACIER INTERNATIONAL PEACE PARKSource: www.wikipedia.org3

HydrologySaskatchewan River watershed. Source:www.wikipedia.orgSt. Mary River Km 200Oldman River Km 362South Saskatchewan Km 1,392 kilometersUpper Old Man River watershed; in the South of the map, the affluent St. Mary river. Source: www.uoguelph.ca12/10/20094

THE SOILIsbasicforall life’s form.Encloseselements: biologicalmineralIs a naturalresourceitneed long timetobecreated (geologicalages!)Itneedtobeconserved12/10/20095

Soilerosionby waterRAINFALL causesrills and sheeterosionFonte: Marco AcutisDiProVe, marco.acutis@unimi.it, www.acutis.it12/10/20096

SOIL LOSS CAUSED BY WATERDepend on:amount and intensity of rainfall and runoff.land cover which reduce the direct forces of rainfallsusceptibility to erosion (texture, composition,…)topography of the landscape as described by slope length, steepness and shape.Artificial conservation practices (terracing, canalizations) and land use.THE GISIS A POWERFUL TOOL WHICH CAN MANAGE TOGETHER ALL THESE ELEMENTS 12/10/20097

DEM resolution 10 mFonte : USGS12/10/20098

Mosaic of Natural-Color Aerial Photos, 2005These photos are in MrSID format and Montana State Plane coordinates, units meters, datum NAD83. Source: U.S. Farm Services Agency National Agricultural Imagery Program (NAIP).12/10/20099

20 %Subalpine fir Engelmann Spruce15 % Cliff/Talus Sparse Vegetation16%Dwarf-shrub/Herbaceous Complex Dry - MesicSource photos: USGS-NPS, 200712/10/200910

USLE= UNIVERSAL SOIL LOSS EQUATIONLong terms (annual)In a determinate areaIn this case: Upper St. Mary watersheedA standard methodtomapthe potentialrisk and erodibilityofsoil12/10/200911

USLEItwasconceived:In USA In 1978 Wischmeier and Smith (USDA)For the field. Subsequently was applied also at not only agricoltural areas12/10/200912

USLEA = R * K * LS * C * PA = potentialmeanannualsoil lossR FACTOR = rainfallfactorK FACTOR = soilerodibilityfactorLS FACTOR = topographicfactorC FACTOR = land cover factorP FACTOR = conservationpractices (terracing)12/10/200913

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THE USLE MAPIt show:The PotentialerosionThe areaswhere rise RILL EROSION and SHEET EROSION UNITA’ In English Units: tons /hectar/yearDATUM: NAD8312/10/200916

Shape file ottenutodallaclassificazione del data set: Vegetation Map - Waterton-Glacier International Peace Park Vegetation Mapping Project. USGS-NPS 1999 Glacier National Park- 12/10/200917

MEASURE UNITSConversion of USLE factor values to U.S. customary measure units. Source: Wall et al, 2002.12/10/200918

DATA SOURCES ofrainfall data:United States Mean Annual R-factor, 1971-2000 spatial gridUnitàdimisura : (100’s ft-tons in h-1 ac-1 yr-1) * 10 DATUM : WGS72 PRISM Group (Parameter-elevation Regressions on Independent Slopes Model) climate mapping 12/10/200919

Unitàdimisura : (100’s ft-tons in h-1 ac-1 yr-1) * 10

DATUM : WGS72

PRISM Group (Parameter-elevation Regressions on Independent Slopes Model) climate mapping

DATA SOURCES soilUSDA State Soil Geographic (STATSGO) Data Base for MontanaCoverageNAD1927 12/10/200920

Coverage

NAD1927

LS FACTORLUNGHEZZA DEL VERSANTE (length)È un indice espresso sulla base di una condizione standard di: 9 ° di pendenza e 22 m di lunghezza= Distanza compresa tra il punto in cui si origina lo scorrimento ed il punto in cui si ha una deposizione di materiale trasportato, per una diminuzione della pendenza.PENDENZA del versante (stepness)è espressa in GRADIDefinition of slope length (Renard, et al. 1987)12/10/200921

Metodo Shulze (1995)Formula per calcolare la lunghezza:L =where: 22.1 = misura standard dellalunghezza del versantem = = esponenterelativo al rapportoerosionedaflusso e da rainfallWhere:β = Where:SD = slope in degreeʎ = - 3.0S + 100 for S < 25%ʎ = 25 for S ≥ 25% where: S = slope gradient in percent12/10/200922

Metodo Shulze (1995)ʎ = A A = con (S ≥ 25,25,(5*(-3))+100)β = B3B3 = B1/B2B1 = sin (SD div deg)B2 = 0.0896(3*(pow(B1,0.8)) + 0.56)m = MM = B3/(1+B3)L = pow(A/22.1,M) LENGTHFormula per calcolare la lunghezza del versante: procedimento con rastercalculator:12/10/200923

Metodo Shulze (1995)St = 10.8 sin (SD div deg) + 0.03 for S < 9%St = 16.8 sin (SD div deg) – 0.50 for S ≥ 9%St = 3.0 [sin(SD div deg)]0.8 + 0.56 for slope lengths < 5mCon raster calculator:S2 = con (SD < 9,(10.8*B1) + 0.03,(16.8*B1) – 0.5)S3 = con (L < 5,(3*(pow(B1,0.8)) + 0.56,S2) STEEPNESS Dopodichèsicalcolal’indice del fattoretopograficomoltiplicando la lunghezza per la pendenza del versante:LS = S3 * L SL FACTORFormula per calcolare la pendenza del versante secondo queste condizioni:12/10/200924

DATA SOURCES LanduseUSGS-NPS 1999 Glacier National Park Vegetation Map - Waterton-Glacier International Peace Park Vegetation Mapping Project. Shape file, NAD 83 .12/10/200925

CANOPY = Copertura vegetativa che non è in contatto col suoloAltezza di cadutaPercentuale di suolo ricoperto dalla canopy12/10/200926

= Copertura vegetativa che non è in contatto col suolo

Altezza di caduta

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C-factor for permanent pasture and woodland Source: Wischmeier and Smith, 1978.12/10/200928

C Factor per territoriallostatonaturale e foresteSource: Wischmeier and Smith, 1978.12/10/200929