Investigating Groundwater INTERNATIONAL CONTRIBUTIONS TO HYDROGEOLOGY 29 Series Editor: Dr. Nick S. Robins Editor-in-Chief IAH Book Series, British Geological Survey, Wallingford, UK INTERNATIONAL CONTRIBUTIONS TO HYDROGEOLOGY Investigating Groundwater Ian Acworth University of New South Wales, Australia CRCPress/BalkemaisanimprintoftheTaylor&FrancisGroup,aninformabusiness ©2019Taylor&FrancisGroup,London,UK TypesetbyApexCoVantage,LLC Allrightsreserved.Nopartofthispublicationortheinformationcontainedherein maybereproduced,storedinaretrievalsystem,ortransmittedinanyformorbyany means,electronic,mechanical,byphotocopying,recordingorotherwise,without writtenpriorpermissionfromthepublishers. Althoughallcareistakentoensureintegrityandthequalityofthispublicationand theinformationherein,noresponsibilityisassumedbythepublishersnortheauthorfor anydamagetothepropertyorpersonsasaresultofoperationoruseofthispublication and/ortheinformationcontainedherein. LibraryofCongressCataloging-in-PublicationData Appliedfor Publishedby: CRCPress/Balkema Schipholweg107C,2316XC,Leiden e-mail:[email protected] www.crcpress.com–www.taylorandfrancis.com ISBN:978-1-138-54249-5(hbk) ISBN:978-1-351-00852-5(ebk) Contents Foreword ix Acknowledgements xi 1 Groundwater environments 1 1.1 Early human movements based upon groundwater availability 1 1.2 Geological time span and types of rock 6 1.3 Groundwater in Australia 10 1.4 Groundwater in fractured rocks 20 1.5 Groundwater in basalt terrains 26 1.6 Groundwater in unconsolidated surficial deposits 34 1.7 Groundwater in limestone and chalk systems 36 1.8 Groundwater on oceanic islands 45 1.9 Groundwater terminology 47 2 Surface water and the atmosphere 51 2.1 Introduction 51 2.2 Properties of water 61 2.3 Radiation 63 2.4 Atmospheric and ocean circulations of water 72 2.5 Meteorological measurements 82 2.6 Rainfall 90 2.7 Streamflow measurement 99 2.8 Evaporation measurement 113 2.9 Estimates of evaporation from open water 115 2.10 Evapotranspiration estimates 117 3 Recharge, discharge and surface water groundwater connectivity 129 3.1 Introduction 129 3.2 Groundwater recharge 130 3.3 Recharge estimates 133 3.4 Groundwater discharge 149 vi Contents vi 3.5 Connectivity of surface water and groundwater 151 3.6 Groundwater dependent ecosystems 158 4 Physical properties of soil and the hydraulic head 167 4.1 Physical properties of soil 167 4.2 Water content 170 4.3 Water potential 174 4.4 Hydraulic head 178 4.5 Signal analysis techniques 191 4.6 Sea water intrusion in coastal aquifers 193 5 Hydraulic conductivity and Darcy’s Law 197 5.1 Introduction to Darcy’s Law 197 5.2 Limitations of the Darcian approach 205 5.3 Flow in fractured rocks 207 5.4 Relationship between grain-size distribution and hydraulic conductivity 208 5.5 Laboratory measurement of hydraulic conductivity 213 5.6 Field measurement of hydraulic conductivity 215 6 Transport equations and steady-state flow 219 6.1 Transport equations 219 6.2 Groundwater transport 220 6.3 Steady-State Flow 225 6.4 Numerical solution to the steady-state flow equation 226 6.5 Analogies to groundwater flow 233 7 Aquifer storage and abstraction impacts 237 7.1 Water storage in the unsaturated zone 237 7.2 Confined aquifer storage 237 7.3 Effective stress in a saturated system 242 7.4 Undrained response to natural loading 250 7.5 Derivation of specific storage from records of hydraulic head in confined aquifers 255 7.6 Derivation of specific storage – A linear poroelastic approach 260 8 Geophysical investigation techniques: seismic 263 8.1 Introduction to seismic methods 263 8.2 Cross-hole seismic method 276 8.3 Surface refraction methods 286 8.4 Seismic Refraction: Delay-time or plus-minus method 295 9 Geophysical investigation techniques: electrical 309 9.1 Electrical methods 309 9.2 Complex conductivity 314 vii Contents vii 9.3 Electrical potential theory 320 9.4 Continuous separation traversing (CST) 325 9.5 Vertical electrical sounding (VES) 327 9.6 Electrical conductivity imaging (ECI) 329 9.7 Induced potential (IP) measurements 333 9.8 Modelling of ECI data 335 9.9 Examples of ECI application: Black cotton soils 341 9.10 Coastal groundwater studies 346 9.11 ECI over fractured rock 351 9.12 IP Measurements 351 9.13 Electromagnetic profiling 352 10 Geophysical investigation techniques: gravity 361 10.1 Gravity Theory 361 10.2 Earth tides 368 10.3 General field procedures for a gravity survey of an area 368 10.4 Gravity corrections to g 371 obs 10.5 Modeling gravity data 374 10.6 Analysing gravity anomalies 374 10.7 Applications of the gravity method 375 11 Geophysical investigation techniques: heat 381 11.1 Introduction 381 11.2 Geothermal heat flow 381 11.3 Underground heat storage in the soil 384 11.4 Thermal imagery 384 11.5 Field measurement of temperature 388 11.6 Thermal properties 390 11.7 Fourier’s Law and differential equations for heat flow 391 11.8 Heat as a tracer 396 12 Drilling and sampling techniques 401 12.1 Cable-tool (percussion) drilling 401 12.2 Rotary Methods 402 12.3 Sampling methods 416 13 Geophysical logging 425 13.1 Introduction 425 13.2 Caliper logs 428 13.3 Verticality logs 430 13.4 Fluid property logs 432 13.5 Fundamentals of nuclear geophysics 436 13.6 Neutron logs 442 13.7 Resistivity and electromagnetic logging 446 13.8 Logging via pushed or hammered sondes 451 13.9 Log interpretation 456 viii Contents viii 14 Hydrochemistry and groundwater isotopes 459 14.1 Introduction 459 14.2 Basic aquatic chemistry 461 14.3 Origin of solutes 468 14.4 Geochemical modelling 471 14.5 Example of hydrochemical analysis 472 14.6 Isotopes 475 14.7 Example: Use of radioactive and stable isotopes in a sand aquifer at Hat Head, NSW 482 14.8 Example: The use of stable isotopes of water from the Maules Creek Catchment in northern NSW 487 14.9 Carbon isotopes 495 14.10 Chlorine-36 499 15 Well hydraulics, radial flow modelling and single well tests 501 15.1 Introduction 501 15.2 Review of definitions 501 15.3 Groundwater flow equations 507 15.4 Analytical solution methods to the radial flow equation 508 15.5 Numerical Solutions to the Radial Flow Equation 517 15.6 Radial Flow Model Results 532 15.7 Non-Darcy flow close to an abstraction well 534 15.8 Specific capacity 548 15.9 Interpretation of step-test data 551 A The international system of units – SI 561 Bibliography 565 Index 581 SERIES IAH International Contributions to Hydrogeology (ICH) 585 Foreword Hydrogeology covers many different aspects of science and engineering and has been taught internationally in both Geology Schools and Engineering Schools, each perhaps withanappropriatebias.Soilscientists,biologists,microbiologists,geophysicists,chemists, organic chemists, botanists and water engineers are all concerned to some degree with the movement of water through semi-pervious membranes, and a wide and diverse literature has developed which is all, to some degree, relevant to the study of hydrogeology. Fully understanding hydrogeology requires that the reader is aware of all the different branches of science and engineering and sufficiently skilled that they can understand the way in which some of the important concepts have been defined in parallel using completely dif- ferentconceptsanddefinitions.Comprehensionisfurthercomplicatedbythewidelydiffer- enteducationsthatareaderbringstothetext.Forthisreasonalargenumberofimagesand figures are included in this book in the firm belief that a picture really is worth a thousand words! Thesubjectareaislargeandnoonebookcanhopetocoverallaspectsofthisfield.Some rationalebehindthechoiceforwhattoincludeandwhathasbeenleftoutisthereforeappro- priate.ThematerialhasbeendevelopedinAustraliawiththeuseofmanyAustralianexam- ples.Althoughthemethodsandapplicationshaveageneralapplicability,someappreciation of the Australian environment is useful, and this is presented in the first chapter. It is now appreciated that many groundwater resources are of considerable age; however, there is little understanding of theprevailing climate that occurred in Australia at thetime ground- waterwasrecharged.AustraliaisunlikeEuropeanandNorthAmericanenvironmentswhere soil and water were very significantly changed and reset during the last ice age. A brief review of climate change is therefore also presented in the first chapter. There can be littleappreciationofthedifferentaquifertypesinwhichgroundwateroccurs,sotheremain- derofthechapterpresentsareviewoftheoccurrenceofgroundwaterindifferentgeological environments. Chapter2isconcernedwithsurfacewaterprocesses.Itisincludedasthehydrogeologist, particularlyfromageologicalbackground,isfrequentlyunawareoftheimportantprocesses andmeasuringtechniquesrequiredtoestimaterainfall,evaporation,evapotranspirationand runoff.Thesearethemajorfluxesofwaterthatoccuratthesurfaceoftheearthandground- water recharge is difficult (or impossible) to predict without the ability to quantify these fluxes. Chapter 3 reviews the interconnectivity of surface water and groundwater which leads to a discussion on groundwater recharge processes and calculations. Chapters 4 to 7 cover basic hydrogeological concepts, while Chapters 8 to 11 provide detail of appropriate geophysical techniques. The narrative then moves to subsurface