Curtis D. Pollman Donald M. Axelrad Darren G. Rumbold  Editors Mercury and the Everglades. A Synthesis and Model for Complex Ecosystem Restoration Volume III – Temporal Trends of Mercury in the Everglades, Synthesis and Management Implications Mercury and the Everglades. A Synthesis and Model for Complex Ecosystem Restoration (cid:129) (cid:129) Curtis D. Pollman Donald M. Axelrad Darren G. Rumbold Editors Mercury and the Everglades. A Synthesis and Model for Complex Ecosystem Restoration – Volume III Temporal Trends of Mercury in the Everglades, Synthesis and Management Implications Editors CurtisD.Pollman DonaldM.Axelrad AquaLuxLucis,Inc InstituteofPublicHealth Gainesville,FL,USA FloridaA&MUniversity Tallahassee,FL,USA DarrenG.Rumbold CoastalWatershedInstitute FloridaGulfCoastUniversity FortMyers,FL,USA ISBN978-3-030-55634-1 ISBN978-3-030-55635-8 (eBook) https://doi.org/10.1007/978-3-030-55635-8 ©SpringerNatureSwitzerlandAG2020 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpartofthe materialisconcerned,specificallytherightsoftranslation,reprinting,reuseofillustrations,recitation, broadcasting,reproductiononmicrofilmsorinanyotherphysicalway,andtransmissionorinformation storageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilarmethodology nowknownorhereafterdeveloped. Theuseofgeneraldescriptivenames,registerednames,trademarks,servicemarks,etc.inthispublication doesnotimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexemptfromtherelevant protectivelawsandregulationsandthereforefreeforgeneraluse. The publisher, the authors, and the editorsare safeto assume that the adviceand informationin this bookarebelievedtobetrueandaccurateatthedateofpublication.Neitherthepublishernortheauthorsor theeditorsgiveawarranty,expressedorimplied,withrespecttothematerialcontainedhereinorforany errorsoromissionsthatmayhavebeenmade.Thepublisherremainsneutralwithregardtojurisdictional claimsinpublishedmapsandinstitutionalaffiliations. ThisSpringerimprintispublishedbytheregisteredcompanySpringerNatureSwitzerlandAG. Theregisteredcompanyaddressis:Gewerbestrasse11,6330Cham,Switzerland “TheEarlyIbisGetstheCrayfish”byBrianGarrett Preface Ifyouwanttograbtheworldandrunit Iseethatyouwillnotsucceed. Theworldisaspiritualvessel,whichcan’tbecontrolled—LaoTzu1 Thisbookistheculminationofmorethana4-yearefforttosynthesizeessentially 30 years of research into the mercury (Hg) problem in the Everglades. For Hg to enter food webs in aquatic ecosystems such as the Everglades, two things are required: first, of course, is a source of Hg; second is that the Hg in the aquatic ecosystemneedstobe either presentasorconvertedtothemethylatedform.Once Hg is methylated, it can enter the base of aquatic food web and then increasingly bioaccumulate by trophic transfer. This biogeochemical cycling of Hg is complex and involves multiple processes and variables. This cycling with respect to methyl Hg(MeHg)productioncanalsobeprofoundlyinfluencedbyanthropogenicdistur- bances.Formanyotherwisepristineaquaticecosystems,disturbancemanifestingin elevatedbiotaHgconcentrationsrelatesprimarilytochangesinatmosphericinputs of Hg. For the Everglades, however, such disturbance includes not only anthropo- genicimpactsonatmosphericHgcyclinganddeposition,butalsodirectimpactson thehydrologyandwaterchemistryofthesystem. Thisbookisultimatelydevotedtounderstandingthenatureandevolutionofthe Hg problem in the Everglades and the attendant role played by anthropogenic disturbance. Our hope is that synthesizing much of the vast amount of extant research in the Everglades itself can lead to informed approaches and policies by key decision makers toward mitigating the problem. These objectives accordingly are embodied in the sequential exposition of the three volumes comprising this synthesis. VolumeIpresentedanoverviewoftheEvergladesfromaphysicalandecological perspective and how anthropogenically driven disturbance has changed the system 1Lao Tzu (n.d.) Tao Te Ching. Translated by Charles Muller (2005) Barnes and Noble Books, NewYork,NY. vii viii Preface spatially, hydrologically, and ecologically over the past approximately 140 years. Therootsofthisdisturbancelayinincreasingdevelopmentinsouth Florida which broadenedovertimeandledtomoreconcertedeffortstobothconvertnaturalhabitat to agricultural and urban land uses and manage the resultant remnant Everglades hydrologically.ThesheermagnitudeoftheseeffortswasintimatedbyShelton2,who in1957wroteaboutthe“largestlow-levelpumpingstationeverconstructed”aspart ofan“enormousfloodcontrolandwaterconservationproject”hetoutedas“oneof the greatest examples in America of what man’s intelligence and vision can do in convertingtheerraticforcesofnatureintosolidassetsforthevegetableandanimal kingdom.” While disturbance is an important theme in understanding the mercury problemintheEverglades,theproblemwouldbemootwithoutsourcesofmercury enteringthesystem.AtmosphericdepositionofHgistheoverwhelmingpathwayfor Hg entering the Everglades,3 and Volume I thus includes chapters on atmospheric cycling of Hg and how key aspects of its cycling serve to exacerbate atmospheric inputstotheEverglades.VolumeIalsoincludeschaptersonthechangingtemporal relationshipbetweenlocalandlargerscalesourcescontributingtotheEvergladesHg problem and the implications of this current relationship for mitigation through controllingemissionsources. Volume II has two parts, with the first part providing greater context regarding how direct disturbance in the Everglades has or likely has contributed to the Hg problem.ThefoundationforthisassessmentliesinunderstandinghowHgentering theEvergladesistransformed and entersthe aquatic food web, which inturn links trophictransferofHginterrestrialwildlifetoHginputstothemarsh.Thisbiogeo- chemical cycling is critical with respect to how strongly Hg in the Everglades bioaccumulates—the importance of which cannot be overstated. As mentioned earlier, Hg must be present as methyl Hg (MeHg) for it to enter aquatic food webs; since external inputs of Hg to the Everglades are greatly dominated by inorganicHgratherthanMeHg,thisHginturnmustbemethylatedforittobecome problematic. As we saw in Volume II, two water chemistry variables—sulfate and dissolvedorganiccarbon—emergeasplayingkeyrolesinthemethylationofHgin theEverglades.Inaddition,bothofthesevariables—which,alongwithHg,George AikenoftheU.S.GeologicalSurveyidentifiedasthe“biogeochemicalaxisofevil” responsible for the global Hg problem—also are profoundly influenced by 2SheltonWR(1957)LandoftheEverglades.TropicalSouthernFlorida.DepartmentofAgriculture, StateofFlorida,Tallahassee,FL. 3AtkesonTD,AxelradD,PollmanCD,KeelerG(2003)Integratingatmosphericmercurydeposi- tionandaquaticcyclingintheFloridaEverglades:anapproachforconductingatotalmaximum daily load analysis for an atmospherically derived pollutant. Integrated Summary. Final report submittedtoUSEPA.FloridaDepartmentofEnvironmentalProtection,Tallahassee,FL. StoberQJ,ThorntonK,JonesR,RichardsJ,IveyC,WelchR,MaddenM,TrexlerJ,GaiserE, ScheidtD,RathbunS(2001)SouthFloridaEcosystemAssessment:PhaseI/II—Evergladesstressor interactions: hydropatterns, eutrophication, habitat alteration, and mercury contamination (sum- mary). EPA 904-R-01-002. USEPA Region 4 Science & Ecosystem Support Division, Water ManagementDivision,andOfficeofResearchandDevelopment. Preface ix disturbancewithintheEverglades.ThesecondpartofVolumeIIinturnpresentsa series of chapters elucidating how Hg bioaccumulates in the Everglades, the mag- nitudeofthatbioaccumulation,andtheresultantecologicalandhumanhealthrisks. Asthelastofthreevolumescomprisingthissynthesis,thisvolumeisdevotedto the overarching question of how the Hg problem can be mitigated or managed. Similar to theother two volumes, Volume III is organized into two parts. The first partincludesthefollowingchapters: Chapter1:TrendsinAtmosphericDepositionofMercury Chapter2:TemporalChangesinMercuryConcentrationsinEvergladesBiota Chapter3:LegacyMercury Chapter4:SimulatingMercuryCyclingintheFloridaEverglades:ACaseStudy Chapter5:TemporalChangesintheMercurySignalintheEverglades:ASynthesis The first two chapters focus on trends observed for two key components of the Everglades Hg problem—trends in atmospheric deposition and trends in aquatic biota and terrestrial wildlife Hg concentrations. The analysis evaluated various datasets for possible long-term and short-term trends. Long-term trends were assessed in Hg accumulation rates in sediment cores (ca.1800–2010) and Hg concentrations in the scapular feathers of wading birds, including museum speci- mens(ca.1910–2010).Analysesofshort-termtrendsincludethoseinwetdeposition ofatmosphericHg(ca.1984–2016)andbiota,includingprimarilyfish(ca.1980to 2016).Chapter3focusesontheimportantmanagementquestionofHgoriginating from historical or previous inputs (so-called legacy Hg) and residing in different environmental pools (e.g., Everglades sediments) that can still contribute to Hg biogeochemicalcyclingandtheimplicationsthatlegacyHgposesforremediation. Chapter4presentsananalysisoflikelydriverscontributingtothetemporaldynam- ics in largemouth bass Hg concentrations using the deterministic Everglades Mer- cury Cycling Model (E-MCM). Because they use a priori functional, mechanistic relationships in a dynamic modeling framework, models such as E-MCM are consideredtobemorestronglyindicativeofcauseandeffectthanempiricalmodels (e.g., linear regression models). While the E-MCM has the ability to be applied acrosstheEvergladesasaseriesofspatiallydiscretecells,itisquitedataintensive. Asaresult,themodelwasappliedtosite3A-15withinWaterConservationArea3A because the site was identified during the early days of the South Florida Mercury Science Program (see Preface to Volume I for a discussion of the evolution of the SFMSP)asaHg“hot-spot”ofconsiderableinterest;thisinterestledtoanumberof intensive studies led by the U.S. Geological Survey and others4 that produced 4USGS (2018) USGS SOFIA Data Exchange. https://sofia.usgs.gov/projects/index.php?project_ url¼evergl_merc Aiken GR, Gilmour CC, Krabbenhoft DP, Orem W (2011) Dissolved organic matter in the Florida Everglades: implications for ecosystem restoration. Crit Rev Environ Sci Technol 41 (S1):217–248. KrabbenhoftDP(1996)MercurystudiesintheFloridaEverglades.U.S.GeologicalSurveyFact SheetFS-166–196. x Preface sufficientbiogeochemicaldataforparameterizingandcalibratingtheE-MCM.The part then concludes with a chapter synthesizing key results from the first four chapters. Severalkeypointsemergefromthefirstpartchapters.Firstistheparadigmthat changes in atmospheric deposition of Hg have contributed to changes in biota Hg concentrations and the trends in atmospheric deposition had a local emissions component. Second is that the magnitude of biota Hg concentration changes— bothlongtermandshortterm—exceedsinferredchangesinatmosphericdeposition. Theimplicationofthisresultisthatsomeothervariablechangingovertimeisacting inadditiontochangesinatmosphericdepositiontodrivebiotaHgtemporaldynam- ics. The third key point is that trends in biota Hg vary across the Everglades landscape;thisfactisimportantinassessingtheroleofchangesinwaterchemistry ascausativeandtheattendantimplicationsofsuchchangesfromamercurymitiga- tionperspective.AfourthkeypointrelatestotheimpactoflegacyHgontherateand magnitude of recovery of the Everglades from atmospheric Hg input mitigation. Legacy Hg has two spatial components—large or global scale and local scale. Understanding the very different dynamics these two components expectedly will impose on the Everglades over time has profound implications with respect to Hg mitigationsuccess. The second part of this volume speaks to the question of trying to mitigate the Everglades problem from a quantitative and philosophical perspective. It contains twochaptersthattouchuponthisquestion: Chapter6:StructuralEquationModelforMercuryCyclingintheEverglades Chapter7:MercuryMitigationManagementStrategiesandLikelyOutcomes The first chapter of this final part uses structural equation modeling (SEM) to identify thebiogeochemical variablesthat moststronglycontributetothemethyla- tionofHgandtrophictransferofMeHgtoGambusia5withintheEvergladesmarsh. SEMoffersseveral advantagesoverother modeling approachesfortheEverglades Hgproblem.First,unliketheE-MCM,themodelcanbeappliedacrosstheentirety of the Everglades Protection Area (EvPA) with existing data. Second, similar to mechanisticmodeling,SEMreliesonaprioriconstructsorpathways.Fittingofthe SEM establishes whether the model pathways are statistically significant and sup- portable;SEMisthusconsideredtobemoreinformativewithrespecttocauseand Gilmour CC, Riedel GS, Ederington MC, Bell JT, Benoit JM, Gill GA, Stordal MC (1998) Methylmercury concentrations and production rates across a trophic gradient in the northern Everglades.Biogeochemistry40:327–345. HurleyJP, Krabbenhoft DP, Cleckner LB, OlsonML, AikenGR, Rawlik RS (1998) System controlsontheaqueousdistributionofmercuryinthenorthernFloridaEverglades.Biogeochem- istry40:293–310. 5GambusiaisquiteusefulasanindicatorspeciesbecauseitisbothubiquitousintheEverglades marshandhasarelativelyshortlifespan(~1year).Moreover,Gambusiaindividualsarelesswidely rangingthanlargerfishoccupyinghighertrophiclevelniches.Asaresult,GambusiaHgconcen- trationdynamicsshouldmorecloselyreflectbothsmallerspatialandshortertemporaldynamicsin Hgbiogeochemicalcycling. Preface xi effect than typical regression models. Moreover, unlike conventional regression modeling,SEMallowsforindirectrelationshipsbetweenvariableswheretheeffect of a particular variable A on a response variable C is mediated by the direct interaction of A with a third variable B that in turn interacts directly with C. With respect to Hg biogeochemical cycling, this ability to model indirect effects is importantbecause,forexample,theeffectsofdissolvedorganiccarbonandsulfate onGambusiaHgconcentrationsaremediatedthroughtheeffects ofboth variables onMeHgconcentrations. TheSEMinChap.6alsolaysthepredicateforconductingscenariomodelingfor mitigating the Everglades Hg problem. From a management perspective, it is extremely useful for such modeling to include a quantitative assessment of the uncertainty inherent in the predictions. One such approach that increasingly is gaining broader use is the application of marginal analyses. Marginal analyses are used to isolate the effects of single predictive parameter included as part of a multivariate model by holding the other predictive parameters at fixed levels and allowingthepredictiveparameterofinteresttovaryacrossaspecifiedrangeduring thepredictiveanalysis.Thisallowsfortheconstructionofconfidenceintervalsinthe predicted values of the response variable (e.g., Gambusia Hg concentrations) as a function of the predictive variable of interest (e.g., sulfate). Chapter 7 thus uses marginal analyses coupled with a “reduced form” generalized linear model abstracted from the SEM developed in Chap. 6 to evaluate the effects of reducing sulfate on predicted Gambusia Hg concentrations in each of the major hydrologic unitswithintheEvPA.Therationaleforrecommendingandthusfocusingonsulfate alone rather than including other variables as the foundation of a strategy for mitigatingtheEvergladesHgproblemisdelineatedasthechapterbeginsandreflects broad support for the causative role of sulfate across multiple lines of evidence coupledwiththefactthatsulfateconcentrationsaregreatlyelevatedacrossmuchof theEvPA. Intheverylate1970s/early1980swhenmonitoringoffishtissueHgconcentra- tionswasfirstinitiated,anongoinganddireHgproblemintheEvergladesbecame immediatelymanifest.FishtissueHgconcentrationsintheEvergladeswereamong the highest recorded in otherwise pristine systems worldwide (which by their very natureareparticularlysensitivetotheinsultsofatmosphericinputsofHg)coupled withprofoundimpactstoterrestrialwildlifeincludingwadingbirdsandtheendan- gered Floridapanther.The storysince then, however,providesaglimmer ofhope. Sincetheearly1980swhentheywereatpeakrecordedlevels,biotaHgconcentra- tions throughout much—albeit not all—of theEvPA declined by upwards to 75%. The variability in spatial and temporal dynamics of biota Hg concentrations in the Everglades further indicates that substantial reductions in biota Hg concentrations canoccurrapidlyandthatvariationsinbiogeochemistryareamajorcauseofthese dynamics.Thisfactbringsusbacktothethemeofdisturbance.Keyamongthewater chemistry variables controlling Hg methylation is sulfate, the occurrence of which within the Everglades is overwhelmingly a product of disturbance. If we have the will,thisdisturbancecanbereversed,andthebenefitsofreducedHgconcentrations intheEvergladesshouldbereapedquickly.