激光光谱学（第3版）

作者: [德] 德姆特勒德（Demtroder W.）著

出版社: 世界图书出版公司

出版时间: 2008-08

版次: 1

ISBN: 9787506291880

定价: 139.00

装帧: 精装

开本: 24开

纸张: 胶版纸

页数: 987页

正文语种: 英语

分类: 自然科学

1 张插图图片

26人买过

　　系统介绍了现代激光光谱学中的基本理论，方法和应用。《激光光谱学》选题丰富，阐述清楚深刻，注重实际应用，已经成为一本经典的激光光谱学研究生教材和参考用书。此次影印的是最新的第三版。在前两版的基础上，作者做了全面的修订和增补，介绍了激光光谱学最新的实验技术和理论进展，例如：外腔中的倍频，可调控的窄带紫外光源，更灵敏的检测技术，可调谐飞秒和分飞秒激光器（X光区域和阿秒范围），可控原子分子激发，相干物质波，还有更多在化学分析，医疗诊断和工程等方面的应用。适合从事激光光谱学研究的物理学家和化学物理学家以及众多的工程人员学习和参考。
　　《激光光谱学》特色：（1）内容非常丰富，涵盖了激光光谱学中众多分支，并附有全面的参考文献。（2）把重要的概念和公式用边框括起来，方便读者查阅。
　　读者对象：适用于物理，化学和材料专业的高年级本科生、研究生和相关专业的科研人员和工程师。
　　目次：简介;光的吸收和发散；非线性光谱；激光拉曼光谱；束中的激光光谱；光泵谱和双共振技术；时间分辨的激光光谱；相干光谱；碰撞过程中的激光光谱；激光光谱新进展；激光光谱的应用；参考文献；主题索引。　　德姆特勒德，德国凯泽斯劳滕大学教授，著名激光光谱学专家。创建了高分辨率激光光谱技术及其在原子分子理学中的应用这一研究领域。1995年获得由德国物理学会和物理研究所颁发的马克思—博恩奖。2000年获得洪堡基金会颁发的海森堡奖。 1.Introduction
2.AbsorptionandEmissionofLight
2.1CavityModes
2.2ThermalRadiationandPlancksLaw
2.3Absorption，Induced，andSpontaneousEmission
2.4BasicPhotometricQuantities
2.5PolarizationofLight
2.6AbsorptionandEmissionSpectra
2.7TransitionProbabilities
2.8CoherencePropertiesofRadiationFields
2.9CoherenceofAtomicSystems
Problems

3.WidthsandProfilesofSpectralLines
3.1NaturalLinewidth
3.2DopplerWidth
3.3CollisionalBroadeningofSpectralLines
3.4Transit-TimeBroadening
3.5HomogeneousandInhomogeneousLineBroadening
3.6SaturationandPowerBroadening
3.7SpectralLineProfilesinLiquidsandSolids
Problems

4.SpectroscopicInstrumentation
4.1SpectrographsandMonochromators
4.2Interferometers
4.3ComparisonBetweenSpectrometersandInterferometers
4.4AccurateWavelengthMeasurements
4.5DetectionofLight
4.6Conclusions
Problems

5.LasersasSpectroscopicLightSources
5.1FundamentalsofLasers
5.2LaserResonators
5.3SpectralCharacteristicsofLaserEmission
5.4ExperimentalRealizationofSingle-ModeLasers
5.5ControlledWavelengthTuningofSingle-ModeLasers
5.6LinewidthsofSingle-ModeLasers
5.7TunableLasers
5.8NonlinearOpticalMixingTechniques
5.9GaussianBeams
Problems

6.Doppler-LimitedAbsorptionandFluorescenceSpectroscopywithLasers
6.1AdvantagesofLasersinSpectroscopy
6.2High-SensitivityMethodsofAbsorptionSpectroscopy
6.3DirectDeterminationofAbsorbedPhotons
6.4IonizationSpectroscopy
6.5OptogalvanicSpectroscopy
6.6Velocity-ModulationSpectroscopy
6.7LaserMagneticResonanceandStarkSpectroscopy
6.8Laser-InducedFluorescence
6.9ComparisonBetweentheDifferentMethods
Problems

7.NonlinearSpectroscopy
7.1LinearandNonlinearAbsorption
7.2SaturationofInhomogeneousLineProfiles
7.3SaturationSpectroscopy
7.4PolarizationSpectroscopy
7.5MultiphotonSpectroscopy
7.6SpecialTechniquesofNonlinearSpectroscopy
7.7Conclusion
Problems

8.LaserRamanSpectroscopy
8.1BasicConsiderations
8.2ExperimentalTechniquesofLinearLaserRamanSpectroscopy
8.3NonlinearRamanSpectroscopy
8.4SpecialTechniques
8.5ApplicationsofLaserRamanSpectroscopy
Problems

9.LaserSpectroscopyinMolecularBeams
9.1ReductionofDopplerWidth
9.2AdiabaticCoolinginSupersonicBeams
9.3FormationandSpectroscopyofClustersandVanderWaalsMoleculesinColdMolecularBeams
9.4NonlinearSpectroscopyinMolecularBeams
9.5LaserSpectroscopyinFastIonBeams
9.6ApplicationsofFIBLAS
9.7SpectroscopyinColdIonBeams
9.8CombinationofMolecularBeamLaserSpectroscopyandMassSpectrometry
Problems

10.OpticalPumpingandDouble-ResonanceTechniques
10.1OpticalPumping
10.2Optical-RFDouble-ResonanceTechnique
10.3Optical-MicrowaveDoubleResonance
10.4Optical-OpticalDoubleResonance
10.5SpecialDetectionSchemesofDouble-ResonanceSpectroscopy
Problems

11.Time-ResolvedLaserSpectroscopy
11.1GenerationofShortLaserPulses
11.2MeasurementofUltrashortPulses
11.3LifetimeMeasurementwithLasers
11.4Pump-and-ProbeTechnique
Problems

12.CoherentSpectroscopy
12.1Level-CrossingSpectroscopy
12.2Quantum-BeatSpectroscopy
12.3ExcitationandDetectionofWavePacketsinAtomsandMolecules
12.4OpticalPulse-TrainInterferenceSpectroscopy
12.5PhotonEchoes
12.6OpticalNutationandFree-InductionDecay
12.7HeterodyneSpectroscopy
12.8CorrelationSpectroscopy
Problems

13.LaserSpectroscopyofCollisionProcesses
13.1High-ResolutionLaserSpectroscopyofCollisionalLineBroadeningandLineShifts
13.2MeasurementsofInelasticCollisionCrossSectionsofExcitedAtomsandMolecules
13.3SpectroscopicTechniquesforMeasuringCollision-InducedTransitionsintheElectronicGroundStateofMolecules
13.4SpectroscopyofReactiveCollisions
13.5SpectroscopicDeterminationofDifferentialCollisionCrossSectionsinCrossedMolecularBeams
13.6Photon-AssistedCollisionalEnergyTransfer
13.7PhotoassociationSpectroscopyofCollidingAtoms
Problems

14.NewDevelopmentsinLaserSpectroscopy
14.1OpticalCoolingandTrappingofAtoms
14.2SpectroscopyofSingleIons
14.3OpticalRamsey-Fringes
14.4AtomInterferometry
14.5TheOne-AtomMaser
14.6SpectralResolutionWithintheNaturalLinewidth
14.7AbsoluteopticalFrequencyMeasurementandOpticalFrequencyStandards
14.8Squeezing

15.ApplicationsofLaserSpectroscopy
15.1ApplicationsinChemistry
15.2EnvironmentalResearchwithLasers
15.3ApplicationstoTechnicalProblems
15.4ApplicationsinBiology
15.5MedicalApplicationsofLaserSpectroscopy
15.6ConcludingRemarks
References
SubjectIndex
内容简介:
　　系统介绍了现代激光光谱学中的基本理论，方法和应用。《激光光谱学》选题丰富，阐述清楚深刻，注重实际应用，已经成为一本经典的激光光谱学研究生教材和参考用书。此次影印的是最新的第三版。在前两版的基础上，作者做了全面的修订和增补，介绍了激光光谱学最新的实验技术和理论进展，例如：外腔中的倍频，可调控的窄带紫外光源，更灵敏的检测技术，可调谐飞秒和分飞秒激光器（X光区域和阿秒范围），可控原子分子激发，相干物质波，还有更多在化学分析，医疗诊断和工程等方面的应用。适合从事激光光谱学研究的物理学家和化学物理学家以及众多的工程人员学习和参考。
　　《激光光谱学》特色：（1）内容非常丰富，涵盖了激光光谱学中众多分支，并附有全面的参考文献。（2）把重要的概念和公式用边框括起来，方便读者查阅。
　　读者对象：适用于物理，化学和材料专业的高年级本科生、研究生和相关专业的科研人员和工程师。
　　目次：简介;光的吸收和发散；非线性光谱；激光拉曼光谱；束中的激光光谱；光泵谱和双共振技术；时间分辨的激光光谱；相干光谱；碰撞过程中的激光光谱；激光光谱新进展；激光光谱的应用；参考文献；主题索引。
作者简介:
　　德姆特勒德，德国凯泽斯劳滕大学教授，著名激光光谱学专家。创建了高分辨率激光光谱技术及其在原子分子理学中的应用这一研究领域。1995年获得由德国物理学会和物理研究所颁发的马克思—博恩奖。2000年获得洪堡基金会颁发的海森堡奖。
目录:
1.Introduction
2.AbsorptionandEmissionofLight
2.1CavityModes
2.2ThermalRadiationandPlancksLaw
2.3Absorption，Induced，andSpontaneousEmission
2.4BasicPhotometricQuantities
2.5PolarizationofLight
2.6AbsorptionandEmissionSpectra
2.7TransitionProbabilities
2.8CoherencePropertiesofRadiationFields
2.9CoherenceofAtomicSystems
Problems

3.WidthsandProfilesofSpectralLines
3.1NaturalLinewidth
3.2DopplerWidth
3.3CollisionalBroadeningofSpectralLines
3.4Transit-TimeBroadening
3.5HomogeneousandInhomogeneousLineBroadening
3.6SaturationandPowerBroadening
3.7SpectralLineProfilesinLiquidsandSolids
Problems

4.SpectroscopicInstrumentation
4.1SpectrographsandMonochromators
4.2Interferometers
4.3ComparisonBetweenSpectrometersandInterferometers
4.4AccurateWavelengthMeasurements
4.5DetectionofLight
4.6Conclusions
Problems

5.LasersasSpectroscopicLightSources
5.1FundamentalsofLasers
5.2LaserResonators
5.3SpectralCharacteristicsofLaserEmission
5.4ExperimentalRealizationofSingle-ModeLasers
5.5ControlledWavelengthTuningofSingle-ModeLasers
5.6LinewidthsofSingle-ModeLasers
5.7TunableLasers
5.8NonlinearOpticalMixingTechniques
5.9GaussianBeams
Problems

6.Doppler-LimitedAbsorptionandFluorescenceSpectroscopywithLasers
6.1AdvantagesofLasersinSpectroscopy
6.2High-SensitivityMethodsofAbsorptionSpectroscopy
6.3DirectDeterminationofAbsorbedPhotons
6.4IonizationSpectroscopy
6.5OptogalvanicSpectroscopy
6.6Velocity-ModulationSpectroscopy
6.7LaserMagneticResonanceandStarkSpectroscopy
6.8Laser-InducedFluorescence
6.9ComparisonBetweentheDifferentMethods
Problems

7.NonlinearSpectroscopy
7.1LinearandNonlinearAbsorption
7.2SaturationofInhomogeneousLineProfiles
7.3SaturationSpectroscopy
7.4PolarizationSpectroscopy
7.5MultiphotonSpectroscopy
7.6SpecialTechniquesofNonlinearSpectroscopy
7.7Conclusion
Problems

8.LaserRamanSpectroscopy
8.1BasicConsiderations
8.2ExperimentalTechniquesofLinearLaserRamanSpectroscopy
8.3NonlinearRamanSpectroscopy
8.4SpecialTechniques
8.5ApplicationsofLaserRamanSpectroscopy
Problems

9.LaserSpectroscopyinMolecularBeams
9.1ReductionofDopplerWidth
9.2AdiabaticCoolinginSupersonicBeams
9.3FormationandSpectroscopyofClustersandVanderWaalsMoleculesinColdMolecularBeams
9.4NonlinearSpectroscopyinMolecularBeams
9.5LaserSpectroscopyinFastIonBeams
9.6ApplicationsofFIBLAS
9.7SpectroscopyinColdIonBeams
9.8CombinationofMolecularBeamLaserSpectroscopyandMassSpectrometry
Problems

10.OpticalPumpingandDouble-ResonanceTechniques
10.1OpticalPumping
10.2Optical-RFDouble-ResonanceTechnique
10.3Optical-MicrowaveDoubleResonance
10.4Optical-OpticalDoubleResonance
10.5SpecialDetectionSchemesofDouble-ResonanceSpectroscopy
Problems

11.Time-ResolvedLaserSpectroscopy
11.1GenerationofShortLaserPulses
11.2MeasurementofUltrashortPulses
11.3LifetimeMeasurementwithLasers
11.4Pump-and-ProbeTechnique
Problems

12.CoherentSpectroscopy
12.1Level-CrossingSpectroscopy
12.2Quantum-BeatSpectroscopy
12.3ExcitationandDetectionofWavePacketsinAtomsandMolecules
12.4OpticalPulse-TrainInterferenceSpectroscopy
12.5PhotonEchoes
12.6OpticalNutationandFree-InductionDecay
12.7HeterodyneSpectroscopy
12.8CorrelationSpectroscopy
Problems

13.LaserSpectroscopyofCollisionProcesses
13.1High-ResolutionLaserSpectroscopyofCollisionalLineBroadeningandLineShifts
13.2MeasurementsofInelasticCollisionCrossSectionsofExcitedAtomsandMolecules
13.3SpectroscopicTechniquesforMeasuringCollision-InducedTransitionsintheElectronicGroundStateofMolecules
13.4SpectroscopyofReactiveCollisions
13.5SpectroscopicDeterminationofDifferentialCollisionCrossSectionsinCrossedMolecularBeams
13.6Photon-AssistedCollisionalEnergyTransfer
13.7PhotoassociationSpectroscopyofCollidingAtoms
Problems

14.NewDevelopmentsinLaserSpectroscopy
14.1OpticalCoolingandTrappingofAtoms
14.2SpectroscopyofSingleIons
14.3OpticalRamsey-Fringes
14.4AtomInterferometry
14.5TheOne-AtomMaser
14.6SpectralResolutionWithintheNaturalLinewidth
14.7AbsoluteopticalFrequencyMeasurementandOpticalFrequencyStandards
14.8Squeezing

15.ApplicationsofLaserSpectroscopy
15.1ApplicationsinChemistry
15.2EnvironmentalResearchwithLasers
15.3ApplicationstoTechnicalProblems
15.4ApplicationsinBiology
15.5MedicalApplicationsofLaserSpectroscopy
15.6ConcludingRemarks
References
SubjectIndex

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激光光谱学（第3版）

内容简介:

作者简介:

目录: