X-Rays and Extreme Ultraviolet Radiation Principles and Applications DAVID ATTWOOD UniversityofCalifornia,Berkeley ANNE SAKDINAWAT SLACNationalAcceleratorLaboratory Illustrationsby LINDA GENIESSE UniversityPrintingHouse,CambridgeCB28BS,UnitedKingdom OneLibertyPlaza,20thFloor,NewYork,NY10006,USA 477WilliamstownRoad,PortMelbourne,VIC3207,Australia 4843/24,2ndFloor,AnsariRoad,Daryaganj,Delhi-110002,India 79AnsonRoad,#06-04/06,Singapore079906 CambridgeUniversityPressispartoftheUniversityofCambridge. ItfurtherstheUniversity’smissionbydisseminatingknowledgeinthepursuitof education,learningandresearchatthehighestinternationallevelsofexcellence. www.cambridge.org Informationonthistitle:www.cambridge.org/9781107062894 (cid:2)C CambridgeUniversityPress2016 Thispublicationisincopyright.Subjecttostatutoryexception andtotheprovisionsofrelevantcollectivelicensingagreements, noreproductionofanypartmaytakeplacewithoutthewritten permissionofCambridgeUniversityPress. Firstpublished2016 PrintedintheUnitedKingdombyClays,StIvesplc AcatalogrecordforthispublicationisavailablefromtheBritishLibrary LibraryofCongressCataloginginPublicationdata Names:Attwood,DavidT.,author.|Sakdinawat,Anne,author.|Geniesse,Linda,illustrator. Title:X-raysandextremeultravioletradiation:principlesandapplications/DavidAttwood (UniversityofCalifornia,Berkeley),AnneSakdinawat(SLACNationalAcceleratorLaboratory); illustrationsbyLindaGeniesse. Othertitles:Softx-raysandextremeultravioletradiation Description:Secondedition.|Cambridge,UnitedKingdom;NewYork,NY:Cambridge UniversityPress,2016.|Earliereditionpublishedundertitle:Softx-raysandextreme ultravioletradiation.|Includesbibliographicalreferencesandindex. Identifiers:LCCN2016035981|ISBN9781107062894(hardback;alk.paper)| ISBN1107062896(hardback;alk.paper) Subjects:LCSH:Grenzrays.|Ultravioletradiation. Classification:LCCQC482.G68A882016|DDC539.7/222–dc23 LCrecordavailableathttps://lccn.loc.gov/2016035981 ISBN978-1-107-06289-4Hardback Additionalresourcesforthispublicationatwww.cambridge.org/xrayeuv CambridgeUniversityPresshasnoresponsibilityforthepersistenceoraccuracy ofURLsforexternalorthird-partyinternetwebsitesreferredtointhispublication, anddoesnotguaranteethatanycontentonsuchwebsitesis,orwillremain, accurateorappropriate. X-RaysandExtremeUltravioletRadiation With this fully updated second edition, you will gain a detailed understanding of the physics and applications of modern x-ray and extreme ultraviolet (EUV) radiation sources. Taking into account the most recent improvements in capabilities, coverage isexpandedtoincludenewchaptersonfreeelectronlasers(FELs),laserhighharmonic generation(HHG),x-rayandEUVoptics,andnanoscaleimaging,acompletelyrevised chapter on spatial and temporal coherence, and extensive discussion of the generation andapplicationsoffemtosecondandattosecondtechniques.Youwillbeguidedstepby stepthroughthemathematicsofeachtopic,withover300figures,50referencetables, and600equationsenablingeasyunderstandingofkeyconcepts.Homeworkproblems, asolutionsmanualforinstructors,andlinkstoYouTube lecturesaccompany thebook online. Thisisthe“go-to”guideforgraduatestudents,researchers,andindustrypractitioners lookingtograspthefundamentalsofx-rayandEUVinteractionwithmatter,orexpand theirknowledgeofthisrapidlygrowingfield. David Attwood is Professor Emeritus at the University of California, Berkeley. He is a co-founder of the Applied Science and Technology PhD program at Berkeley, and a Fellow of the American Physical Society and the Optical Society of America. He has publishedover100scientificpapersandco-editedseveralbooks. AnneSakdinawatisascientistattheSLACNationalAcceleratorLaboratory,whereshe leadsascientificallymotivatedimagingandnanofabricationgroupco-locatedatStan- fordUniversity.SheistherecipientoftheinternationalMeyer-IlseAwardforadvances inx-raymicroscopy,andaUSDepartmentofEnergyEarlyCareerAward. ToProfessorsStanleyGoldstein andNathanMarcuvitz,andtoEllie Contents PrefacetotheSecondEdition pagexiii AcknowledgmentsfortheSecondEdition xiv PrefacetotheFirstEdition xv AcknowledgmentsfortheFirstEdition xviii 1 Introduction 1 1.1 TheX-RayandExtremeUltravioletRegionsoftheElectromagnetic Spectrum 1 1.2 BasicAbsorptionandEmissionProcesses 5 1.3 AtomicEnergyLevelsandAllowedTransitions 11 1.4 Scattering,Diffraction,andRefractionofElectromagneticRadiation 20 References 24 HomeworkProblems 26 2 RadiationandScatteringatEUVandX-RayWavelengths 27 2.1 Maxwell’sEquationsandtheWaveEquation 27 2.2 CalculatingScatteredFields 30 2.3 RadiatedPowerandPoynting’sTheorem 37 2.4 ScatteringCross-Sections 41 2.5 ScatteringbyaFreeElectron 42 2.6 ScatteringbyBoundElectrons 45 2.7 ScatteringbyaMulti-ElectronAtom 48 References 58 HomeworkProblems 59 3 WavePropagationandRefractiveIndexatX-RayandEUVWavelengths 60 3.1 TheWaveEquationandRefractiveIndex 61 3.2 PhaseVariationandAbsorptionofPropagatingWaves 66 3.3 ReflectionandRefractionatanInterface 71 3.4 TotalExternalReflectionofX-RaysandEUVRadiation 74 3.5 ReflectionCoefficientsatanInterface 77 3.6 Brewster’sAngle 86 viii Contents 3.7 FieldPenetrationintoaLossyMediumNeartheCriticalAngle 88 3.8 Determinationofδandβ:TheKramers–KronigRelations 97 3.9 EnhancedReflectivityfromPeriodicStructures 101 References 107 HomeworkProblems 109 4 CoherenceatShortWavelengths 110 4.1 ConceptsofSpatialandTemporalCoherence 111 4.2 SpatialandSpectralFiltering 119 4.3 ExamplesofExperimentsthatRequireCoherence 121 4.4 ThevanCittert–ZernikeTheorem 126 4.5 Young’sDoubleSlitInterferenceTechnique 135 4.6 SpatialandTemporalCoherence,andTruePhaseCoherence 137 4.7 DiffractionofRadiationbyaCoherentlyIlluminatedPinhole Aperture 139 4.8 SimilaritiesbetweentheDiffractionofPartiallyCoherentand CoherentRadiationbyaCircularAperture 144 References 145 HomeworkProblems 147 5 SynchrotronRadiation 148 5.1 Introduction 149 5.2 CharacteristicsofBendingMagnetRadiation 153 5.3 CharacteristicsofUndulatorRadiation 161 5.4 UndulatorRadiation:CalculationsofRadiatedPower,Brightness,and Harmonics 167 5.5 TheScaleofHarmonicMotion 200 5.6 SpatialandSpectralFilteringofUndulatorRadiation 205 5.7 TheTransitionfromUndulatortoWigglerRadiation 215 5.8 WigglerPowerandFlux 220 References 223 HomeworkProblems 226 6 X-RayandEUVFreeElectronLasers 227 6.1 TheFreeElectronLaser 228 6.2 EvolutionfromUndulatorRadiationtoFreeElectronLasing 231 6.3 TheFELEquationsandCharacteristicParameters 237 6.4 FirstFELLasingExperimentsatEUVandX-RayWavelengths 247 6.5 SpatialandTemporalCoherenceofX-RayFELRadiation 251 6.6 SeededandSelf-SeededFELs 256 6.7 Pump-ProbeCapabilities 261 6.8 CurrentFELFacilities,Parameters,andCapabilities 265 Contents ix 6.9 ScientificApplicationsofCoherent,Intense,andShortDuration(fs/as) EUVandX-RayFELRadiation 266 References 270 HomeworkProblems 278 7 LaserHighHarmonicGeneration 279 7.1 TheBasicProcessofHighHarmonicGeneration(HHG) 279 7.2 ElectronTunneling,Trajectories,ReturnEnergies,andtheEfficiencyof HighHarmonicGeneration 281 7.3 SpatialandTemporalCoherenceofHighHarmonicRadiation 293 7.4 IR/EUVDephasingandtheEffectivePropagationPathLengthforHHG 295 7.5 AttosecondDurationEUV/SoftX-RayPulses 300 7.6 AttosecondProbingofDynamicalProcessesinAtoms,Molecules, Nanoparticles,andSolids 306 References 310 HomeworkProblems 314 8 PhysicsofHotDensePlasmas 315 8.1 Introduction 316 8.2 ShortandLongRangeInteractionsinPlasmas 318 8.3 BasicParametersforDescribingaPlasma 321 8.4 Microscopic,Kinetic,andFluidDescriptionsofaPlasma 324 8.5 NumericalSimulations 362 8.6 DensityGradients:UVandEUVProbingofPlasmas 367 8.7 X-RayEmissionfromaHotDensePlasma 371 8.8 AnApplication:EUVEmittingPlasmaforComputerChipLithography 390 References 395 HomeworkProblems 402 9 ExtremeUltravioletandSoftX-RayLasers 403 9.1 BasicProcesses 404 9.2 Gain 411 9.3 RecombinationLasingwithHydrogen-LikeCarbonIons 416 9.4 CollisionallyPumpedNeon-LikeandNickel-LikeLasers 421 9.5 CompactEUVLasers 431 9.6 SpatiallyCoherentEUVandSoftX-RayLasers 436 References 440 HomeworkProblems 445 10 X-RayandExtremeUltravioletOptics 446 10.1 Introduction 446 10.2 ReflectiveX-RayOptics 448 x Contents 10.3 MultilayerMirrors 455 10.4 CapillaryOptics 464 10.5 TransmissionGratings 467 10.6 TheFresnelZonePlateLens 469 10.7 ReflectionGratings 498 10.8 CrystalOptics 499 10.9 CompoundRefractiveLenses 501 References 505 HomeworkProblems 513 11 X-RayandEUVImaging 514 11.1 Introduction 514 11.2 SpatialResolutionandContrast 518 11.3 ProjectionImaging 524 114 ScanningX-RayMicroscopy 537 11.5 Full-FieldX-RayMicroscopy 541 11.6 DiffractiveImagingTechniques 548 11.7 OpticalSystemforEUVLithography 557 References 559 HomeworkProblems 566 AppendixA:UnitsandPhysicalConstants 567 A.1 TheInternationalSystemofUnits(SI) 567 A.2 PhysicalConstants 569 AppendixB:ElectronBindingEnergies,PrincipalK-andL-ShellEmission Lines,andAugerElectronEnergies 570 AppendixC:AtomicScatteringFactors,AtomicAbsorptionCoefficients,and SubshellPhotoionizationCross-Sections 578 AppendixD:MathematicalandVectorRelationships 592 D.1 VectorandTensorFormulas 592 D.2 SeriesExpansions 593 D.3 TrigonometricRelationships 594 D.4 DefiniteIntegrals 595 D.5 FunctionsofaComplexVariable 596 D.6 FourierTransformsandFourierTransformPairs 599 D.7 TheDiracDeltaFunction 600 D.8 TheCauchyPrincipalValueTheorem 600 AppendixE:SomeIntegrationsink,ω-Space 602 AppendixF:LorentzSpace-TimeTransformations 607 F.1 FrequencyandWavenumberRelations 608 F.2 AngularTransformations 611 Contents xi F.3 TheLorentzContractionofLength 612 F.4 TimeDilation 613 F.5 TransformingdP(cid:3)/d(cid:5)(cid:3)todP/d(cid:5) 614 AppendixG:SomeFELAlgebra 617 G.1 SlowandFastPhaseforEnergyTransfer,θ andθ 617 s f G.2 TheOne-DimensionalWaveEquation 618 AppendixH:IonizationRatesofNobleGasAtomsasaFunctionofLaser IntensityandPulseDurationat800nmWavelength 620 Index 622