Hydrology Waterinitsdifferentformshasalwaysbeenasourceofwonder,curiosityandpractical concernforhumanseverywhere.Thistextbookpresentsacoherentintroductiontomany of the concepts and relationships needed to describe the distribution and transport of waterinthenaturalenvironment. Continental water transport processes take place above, on and below the Earth’s surface,andconsequentlythebookissplitintofourmainparts.PartIdealswithwaterin theatmosphere.PartIIintroducesthetransportofwateronthesurface.Waterbelowthe surfaceisthesubjectofPartIII.PartIVisdevotedtoflowphenomenaatthebasinscale andstatisticalconceptsusefulintheanalysisofhydrologicdata.Finally,thebookcloses with a brief history of ideas concerning the hydrologic cycle. Hydrologic phenomena aredealtwithatspatialandtemporalscalesatwhichtheyoccurinnature.Thephysics andmathematicsnecessarytodescribethesephenomenaareintroducedanddeveloped, andreaderswillrequireaworkingknowledgeofcalculusandbasicfluidmechanics. Hydrology–AnIntroductionisatextbookthatcoversthefundamentalprinciplesof hydrology,basedonthecoursethatWilfriedBrutsaerthastaughtatCornellUniversity forthepast30years.Thebookwillbeinvaluableasatextbookforentry-levelcourses in hydrology directed at advanced seniors and graduate students in physical science andengineering.Inaddition,thebookwillbemorebroadlyofinteresttoprofessional scientistsandengineersinhydrology,environmentalscience,meteorology,agronomy, geology,climatology,oceanology,glaciologyandotherEarthsciences. Wilfried Brutsaert is William L. Lewis Professor of Engineering at Cornell University.Inalongandprestigiouscareerintheresearchandteachingofhydrology, Professor Brutsaert has received many awards and honors, including: the Hydrology AwardandRobertE.HortonMedal,AmericanGeophysicalUnion;President,Hydrology Section, American Geophysical Union, from 1992 to 1994, Fellow of the American GeophysicalUnionandAmericanMeteorologicalSociety;theRayK.LinsleyAward, AmericanInstituteofHydrology;WalterB.LangbeinLecturer,AmericanGeophysical Union; International Award, Japan Society of Hydrology & Water Resources; Jule G. Charney Award, American Meteorological Society. He is a member of the National AcademyofEngineeringandhaspublishedtwopreviousbooks,Evaporationintothe Atmosphere:Theory,HistoryandApplications(D.ReidelPublishingCompany,1982), andGasTransferatWaterSurfaces(withG.H.Jirka,D.ReidelPublishingCompany, 1984).Hehasauthoredandco-authoredmorethan170journalarticles. H Y D R O L O G Y AN INTRODUCTION WILFRIED BRUTSAERT CornellUniversity cambridgeuniversitypress Cambridge,NewYork,Melbourne,Madrid,CapeTown,Singapore,Sa˜oPaulo, Delhi, Mexico City CambridgeUniversityPress TheEdinburghBuilding,CambridgeCB28RU,UK PublishedintheUnitedStatesofAmericabyCambridgeUniversityPress,NewYork www.cambridge.org Informationonthistitle:www.cambridge.org/9780521824798 (cid:2)C W.Brutsaert2005 Thispublicationisincopyright.Subjecttostatutoryexception andtotheprovisionsofrelevantcollectivelicensingagreements, noreproductionofanypartmaytakeplacewithout thewrittenpermissionofCambridgeUniversityPress. Firstpublished2005 8th printing 2013 Printedand bound in the United Kingdom by the MPG Books Group AcatalogrecordforthispublicationisavailablefromtheBritishLibrary ISBN978-0-521-82479-8Hardback CambridgeUniversityPresshasnoresponsibilityforthepersistenceoraccuracyofURLsforexternal orthird-partyinternetwebsitesreferredtointhispublication,anddoesnotguaranteethatanycontent onsuchwebsitesis,orwillremain,accurateorappropriate.Informationregardingprices,travel timetablesandotherfactualinformationgiveninthisworkarecorrectatthetimeoffirstprintingbut CambridgeUniversityPressdoesnotguaranteetheaccuracyofsuchinformationthereafter. CONTENTS Foreword page ix Noteonthetext xii 1 Introduction 1 1.1 Definitionandscope 1 1.2 Thehydrologiccycle 2 1.3 Someestimatesoftheglobalwaterbalance 3 1.4 Methodologiesandprocedures 7 1.5 Conservationlaws:theequationsofmotion 12 References 18 Problems 19 PartI Waterintheatmosphere 2 Wateraloft:fluidmechanicsoftheloweratmosphere 23 2.1 Watervaporinair 23 2.2 Hydrostaticsandatmosphericstability 28 2.3 Turbulenttransportofwatervapor 34 2.4 Theatmosphericboundarylayer 36 2.5 Turbulencesimilarity 41 2.6 Surfaceboundarycondition:theenergybudgetconstraint 55 References 72 Problems 76 3 Precipitation 79 3.1 Formationofprecipitation 79 3.2 Majorprecipitationweathersystems 82 3.3 Precipitationdistributionontheground 92 3.4 Interception 100 3.5 Reliabilityofoperationalprecipitationmeasurements 106 References 111 Problems 116 contents vi 4 Evaporation 117 4.1 Evaporationmechanisms 117 4.2 Masstransferformulations 118 4.3 Energybudgetandrelatedformulations 123 4.4 Waterbudgetmethods 142 4.5 Evaporationclimatology 148 References 151 Problems 156 PartII Wateronthesurface 5 Wateronthelandsurface:fluidmechanicsoffreesurfaceflow 161 5.1 Freesurfaceflow 161 5.2 Hydraulictheory:shallowwaterequations 163 5.3 Frictionslope 167 5.4 Generalconsiderationsandsomefeaturesoffreesurfaceflow 174 References 194 Problems 196 6 Overlandflow 198 6.1 Thestandardformulation 198 6.2 Kinematicwaveapproach 201 6.3 Lumpedkinematicapproach 210 References 213 Problems 213 7 Streamflowrouting 216 7.1 Twoextremecasesoflargefloodwavepropagation 217 7.2 Alumpedkinematicapproach:theMuskingummethod 224 7.3 EstimationoftheMuskingumparameters 232 References 241 Problems 242 PartIII Waterbelowthesurface 8 Waterbeneaththeground:fluidmechanicsinporousmaterials 249 8.1 Porousmaterials 249 8.2 Hydrostaticsofpore-fillingwaterinthepresenceofair 251 8.3 Watertransportinaporousmaterial 268 8.4 Fieldequationsofmassandmomentumconservation 287 References 298 Problems 303 contents vii 9 Infiltrationandrelatedunsaturatedflows 307 9.1 Generalfeaturesoftheinfiltrationphenomenon 307 9.2 Infiltrationintheabsenceofgravity:sorption 310 9.3 Infiltrationcapacity 326 9.4 Raininfiltration 332 9.5 Catchment-scaleinfiltrationandother“losses” 343 9.6 Capillaryriseandevaporationatthesoilsurface 346 References 357 Problems 361 10 Groundwateroutflowandbaseflow 366 10.1 Flowinanunconfinedriparianaquifer 366 10.2 Freesurfaceflow:afirstapproximation 377 10.3 Hydraulicgroundwatertheory:asecondapproximation 382 10.4 Linearizedhydraulicgroundwatertheory:athirdapproximation 398 10.5 Kinematicwaveinslopingaquifers:afourthapproximation 415 10.6 Catchment-scalebaseflowparameterizations 416 References 431 Problems 433 PartIV Flowsatthecatchmentscaleinresponsetoprecipitation 11 Streamflowgeneration:mechanismsandparameterization 441 11.1 Riparianareasandheadwaterbasins 441 11.2 Stormrunoffmechanismsinriparianareas 443 11.3 Summaryofmechansimsandparameterizationoptions 457 References 461 12 Streamflowresponseatthecatchmentscale 465 12.1 Stationarylinearresponse:theunithydrograph 465 12.2 Identificationoflinearresponsefunctions 472 12.3 Stationarynonlinearlumpedresponse 493 12.4 Non-stationarylinearresponse 498 References 501 503 Problems 13 Elementsoffrequencyanalysisinhydrology 509 13.1 Randomvariablesandprobability 509 13.2 Summarydescriptorsofaprobabilitydistributionfunction 511 13.3 Someprobabilitydistributionsfordiscretevariables 519 13.4 Someprobabilitydistributionsforcontinuousvariables 523 13.5 Extensionofavailablerecords 543 References 550 Problems 553 contents viii 14 Afterword–ashorthistoricalsketchoftheoriesaboutthewater circulationonEarth 557 14.1 Earliestconcepts:theatmosphericwatercycle 557 14.2 Greekantiquity 559 14.3 TheLatinera 566 14.4 Fromphilosophytosciencebyexperimentation 572 14.5 Closingcomments 585 References 586 Appendix Someusefulmathematicalconcepts 590 A1 Differentiationofanintegral 590 A2 Thegeneralresponseofalinearstationarysystem 590 A3 Thegeneralresponseofanonlinearsystem 597 References 598 Index 599 FOREWORD Waterinitsdifferentformshasalwaysbeenasourceofwonder,curiosityandpractical concern for humans everywhere. The goal of this book is to present a coherent intro- duction to some of the concepts and relationships needed to describe the distribution and transport of water in the natural environment. Thus it is an attempt to provide a more thorough understanding, and to connect the major paradigms that bear upon the hydrologiccycle,thatisthenever-endingcirculationofwateroverthecontinentsofthe Earth. Continental water transport processes take place above, on and below the Earth’s landsurfaces.Accordingly,inPartI,waterisconsideredasitpassesthroughthelower atmosphere; this part consists of a general description of atmospheric transport in Chapter 2, followed by the application of these concepts to precipitation and evapo- rationinChapters3and4,respectively.InPartII,watertransportontheEarth’ssurface is dealt with; this part consists of a general description of the hydraulics of free sur- faceflowinChapter5,whichisthenappliedtooverlandrunoffandstreamflowrouting in rivers in Chapters 6 and 7, respectively. Water below the surface is the subject of Part III; again, a general introduction to flow in porous materials in Chapter 8 is followed by applications to phenomena involving infiltration and capillary rise in Chapter 9, and groundwater drainage and baseflow in Chapter 10. Part IV is devoted toflowphenomena,mostlyfluvialrunoff,inresponsetoprecipitationatthecatchment andriverbasinscales,whichresultfromthecombinationofflowsbothaboveandbelow theEarth’ssurface,alreadytreatedatsmallerscalesseparatelyinPartsIIandIII.Various interactionsoftheseflowphenomenaandthemajorparadigmsregardingthesubscale mechanismsaredescribedinChapter11.Thisisfollowedbyatreatmentoftheavailable parameterizations in Chapter 12. In Chapter 13 the fourth part of the book concludes withabriefdescriptionofsomeofthemorecommonstatisticalconceptsthatareuseful intheanalysisofhydrologicdata.Finally,asanafterword,Chapter14closesthebook withabriefhistoryoftheideasonthewatercycle,whichoverthecenturiesevolvedto our present understanding; Santayana’s dictum may be a bit worn by now, but several recent reinventions of the hydrologic wheel could have been avoided, if the past had beenbetterremembered. Thesetransportphenomenainthehydrologiccycleonlandaretreatedatspatialand temporalscales,atwhichtheyarecommonlyencounteredineverydaylifeandatwhich theyaretractablewithpresentlyavailabledata.Hydrologyisaphysicalscience,andthe languageofphysicsismathematics.Accordingly,plausibleassumptionsareintroduced andthemathematicalformulationsandparameterizationsarederived,whichdescribethe