Electromagnetic Radiation: Atomic, Molecular, and Optical Physics

Electromagnetic Radiation: Atomic, Molecular, and Optical Physics (eBook)

Atomic, Molecular, And Optical Physics: Electromagnetic Radiation
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1997 | 1. Auflage
406 Seiten
Elsevier Science (Verlag)
978-0-08-086019-0 (ISBN)
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Combined with Volumes 29A and 29B, this volume is a comprehensive treatment of the key experimental methods of atomic, molecular, and optical physics, as well as an excellent experimental handbook for the field. Thewide availability of tunable lasers in the past several years has revolutionized the field and lead to the introduction of many new experimental methods that are covered in these volumes. Traditional methods are also included to ensure that the volumes will be a complete reference source for the field.
Combined with Volumes 29A and 29B, this volume is a comprehensive treatment of the key experimental methods of atomic, molecular, and optical physics, as well as an excellent experimental handbook for the field. Thewide availability of tunable lasers in the past several years has revolutionized the field and lead to the introduction of many new experimental methods that are covered in these volumes. Traditional methods are also included to ensure that the volumes will be a complete reference source for the field.

Front Cover 1
Atomic, Molecular, and Optical Physics: EIectromagnetic Radiation 4
Copyright Page 5
Contents 6
Contributors 12
Preface 14
Volumes in Series 16
Chapter 1. Laser-Produced Plasmas as Short-Wavelength Incoherent Optical Sources 20
1.1. Introduction 20
1.2. Black-Body Radiators 25
1.3. Laser-Produced Plasmas 26
1.4. Practical Considerations 32
References 37
Chapter 2. Synchrotron Radiation 42
2.1. Introduction 42
2.2. Synchrotron Radiation Characteristics 43
2.3. Light Monochromatization 52
2.4. Applications 59
References 61
Chapter 3. Continuous Wave Dye Lasers 64
3.1. Introduction 64
3.2. Basic Dye Laser Principles 65
3.3. Simple CW Dye Laser Theory 69
3.4. Actual CW Dye Lasers 75
3.5. Alignment of a CW Dye Laser 90
References 92
Chapter 4. Semiconductor Diode Lasers 96
4.1. Introduction 96
4.2. General Characteristics of Diode Lasers 96
4.3. Extended-Cavity Lasers 103
4.4. Electronics 108
4.5. Optical Coatings on Laser Facets 114
4.6. Diode Laser Frequency Noise and Stabilization 116
4.7. Extending Wavelength Coverage 118
References 119
Chapter 5. Frequency Stabilization of Tunable Lasers 122
5.1. Introduction 122
5.2. Optical Frequency References 125
5.3. Transducers 140
5.4. Loop Filter 143
5.5. Design Examples 145
5.6. Summary 153
References 153
Chapter 6. Pulsed Lasers 156
6.1. Introduction 156
6.2. Pulsed Lasers 157
6.3. Buyer's Guide 169
6.4. Builder's Guide 172
6.5. Summary 188
References 188
Chapter 7. Techniques for Modelocking Fiber Lasers 190
7.1. Introduction 190
7.2. Cavity Building 190
7.3. Modelocking 194
7.4. Diagnostics 207
References 209
Chapter 8. Characterization of Short Laser Pulses 212
8.1. Introduction 212
8.2. Spatial Characterization and Focusing 215
8.3. Conventional Detectors for nsec to psec Pulses 217
8.4. Streak Camera 218
8.5. Autocorrelation and Cross-Correlation Techniques 222
8.6. Special Techniques for the VUV and X-Ray Regions 242
References 246
Chapter 9. Nonlinear Optical Frequency Conversion Techniques 250
9.1. Introduction 250
9.2. Second-Harmonic Generation 252
9.3. Sum- and Difference-Frequency Generation 266
9.4. Third-Harmonic Generation and Four-Wave Mixing 271
9.5. Optical Parametric Amplifiers (OPAs) and Oscillators (OPOs) 274
9.6. Raman Shifters 285
9.7. Up-Conversion Lasers 287
References 289
Chapter 10. Optical Wavelength Standards 298
10.1. Introduction 298
10.2. Basic Scheme of an Optical Wavelength Standard 299
10.3. Iodine-Stabilized Lasers 307
10.4. Wavelength Standards Utilizing Narrow Resonances of Laser-Cooled Absorbers 313
10.5. Optical Frequency Measurement 322
10.6. Conclusions 326
References 326
Chapter 11. Precise Wavelength Measurement of Tunable Lasers 330
11.1. Introduction 330
11.2. The .-Meter (Scanning Michelson Interferometer) 331
11.3. The Fizeau Wavemeter 350
11.4. Plane-Parallel Interferometers with CCD Readout 356
11.5. Summary and Outlook 357
References 358
Chapter 12. Optical Materials and Devices 362
12.1. Introduction 362
12.2. Optical Materials and Performance 362
12.3. Optical Components 366
12.4. Polarization-Controlling Components 372
12.5. Passive Optical Devices 377
References 385
Chapter 13. Guided-Wave and Integrated Optics 388
13.1. Introduction 388
13.2. Optical Waveguides 388
13.3. Fibers 390
13.4. Guided-Wave Integrated Optics 400
13.5. Concluding Points 411
References 412
Index 416

1

Laser-Produced Plasmas as Short-Wavelength Incoherent Optical Sources


James F. Young    Department of Electrical and Computer Engineering, Rice University, Houston, Texas

1.1 Introduction


Incoherent sources are useful experimental tools that have long been used throughout the optical spectrum, subject to availability. Recent technological advances have extended the available range into the vacuum ultraviolet and soft x-ray range through the use of laser-produced plasmas. This chapter will concentrate on the description of these new sources. Traditional vacuum ultraviolet sources and appropriate experimental techniques in this spectral range have been discussed in detail previously [1]. Conventional sources in other spectral regions—from the infrared, through the visible, to the ultraviolet quartz absorption edge at about 160 nm—have also been reviewed [2].

Figure 1 shows a typical configuration of a laser-produced plasma. A pulsed high-power laser is focused to a small spot on a metal target. Asmall, hot, radiating plasma or spark is formed that is characterized by very high densities of electrons and ions, very large density gradients, and very high temperatures. The parameters can be comparable to those in stellar interiors. Much of the work on laser-produced plasmas was motivated by the laser inertial confinement fusion program, and therefore concentrated on low-atomic-number targets irradiated at extremely high power densities, perhaps 1015 W cm−2; interest was focused on shock wave formation, ablation rates, and radiation above l keV [3, 4]. Researchers in other fields, however, realized that laser-produced plasmas could be produced at much lower laser fluences, and therefore with smaller, practical lasers, and yet still provide unique sources of short-wavelength radiation [518]. Laser-produced plasmas can be used as a point source to illuminate a separate sample, but often, as shown in Fig. 1, a gas of the atoms to be irradiated surrounds the plasma, eliminating collection optics. The combination of a laser-produced plasma and a surrounding gas that can be photoionized also represents a unique pulsed source of hot electrons that can be used to excite optically forbidden transitions [19, 20]. Even a modest pumping laser can produce an effective electron current density of > 105 A-cm−2 with a subnanosecond rise time.

Fig. 1 Schematic of a laser-produced plasma light source. In this geometry the plasma radiation illuminates atoms that are near, but outside, the heated plasma, and the resulting excited levels are measured with a probe laser.

The experimental appeal of laser-produced plasma light sources results from their combination of simplicity and unique characteristics. The physical reality of a typical source is not far different from the schematic in Fig. 1, yet it constitutes a radiation source with a bandwidth and spectral intensity that is difficult to match even at national facilities. The emission from a laser-produced plasma depends on both the laser and the target parameters, but can have a broad smooth spectrum that is often characterized as a black-body radiator with a temperature from 10 eV to several keV. Figure 2 shows a comparison between measured radiant energy spectra from an Au target and calculated black-body radiation spectral profiles. The agreement is reasonably good, but the black-body temperature of a laser-produced plasma, although useful, should be used only qualitatively. The conversion efficiency from input laser energy to total energy radiated by a plasma can vary from a few percent to more than 60%, as shown in Fig. 3 [21]. These data also show the advantages of short-wavelength pump lasers. The time behavior of the plasma temperature and radiation generally follows that of the driving laser pulse, at least down to about 10-pstime scales, providing a unique tool for time-resolved studies [2225].

Fig. 2 Radiant energy spectra from an Au target illuminatedby a 100-psec 530-nm pulse focused to 4 × 1014 W cm−2. The dashed lines show black-body radiation spectral profiles for the indicated temperatures. From reference [51]. Reprinted with permission from the American Institute of Physics.
Fig. 3 X-ray conversion efficiency for an Au target illuminated at a power density of 7 × 1013 W cm−2 at three wavelengths. The four curves represent measurements in different spectral bands. From reference [21]. Reprinted with permission from the American Institute of Physics.

Before reviewing the characteristics of black-body radiators and summarizing the physics of laser-heated plasmas, it is helpful to present some typical numbers to place laser-produced plasmas in a physical context. High focused light intensities are required to initiate and sustain a plasma. While densities of 1015 W cm−2 and higher have been used to produce high x-ray yields, typical values for laboratory sources are 1011 to 1013 W cm−2. Thus, for a focal spot of 50 pm diameter, a peak laser power of ~10 MW is required, and pump lasers having a short pulse length must be used to keep the energies practical. The Nd laser fundamental wavelength of 1064 nm plus its harmonics (see Fig. 3) are common choices for the driving radiation because of the commercial availability of the laser. Early fusion work studied CO2 laser-driven plasmas extensively because of the economy and scalability of CO2 lasers, but the long wavelength and generally longer pulse lengths reduce plasma heating efficiency. Typically, a plasma heated by 1064 nm radiation will have a spectral radiance 10 to 30 times greater than one heated by 10.6-μm radiation for the same input energy [26, 27]. This difference is illustrated particularly clearly by the data shown in Fig. 4. Excimer lasers are potentially important sources for laser-produced plasmas, but currently the large beam divergence and long pulse lengths of standard commercial lasers are major problems [28].

Fig. 4 Spectral radiance at 50 nm as a function of pump input energy for 1064 nm () and 10.6 nm (). The solid curves are theoretical calculations. From reference [27]. Reprinted with permission from the Optical Society of America.

Although Nd Q-switched lasers with pulse lengths up to 10 nsec are used to heat plasmas, Nd mode-locked lasers with pulse lengths of about 100 psec are used more often. Minimum required pulse energies are therefore in the range of 1 to 200 mJ. The recent commercial availability of such sources with high repetition rates has made laser-produced plasmas practical experimental light sources. U1-trashort subpicosecond pulse length laser systems based on dye or Tixapphire gain media have been used to produce plasmas with unique characteristics [2934]. The plasmas produced by very short high-intensity pump pulses are fundamentally different from those produced by more conventional pump sources, which are discussed here. For example, Fig. 5 shows the high-energy spectrum radiated by a plasma heated by a 0.5-TW 120-fsec pulse focused to a density greater than 10l8 W cm−2. Hard x-ray radiation extending beyond 1 MeV was observed. The spectrum was taken through 19 mm of lead to avoid saturating the detector. The physics of plasma formation and heating under such conditions are quite different from that presented here and are still an active area of research.

Fig. 5 Pulse height spectrum of radiation from a tantalum target irradiated with a 40-mJ 120-fsec pulse of 807 nm radiationfocused to 1018 W cm−2 From reference [32]. Reprinted with permission from the IEEE.

1.2 Black-Body Radiators


For many experimental applications, for example, absorption spectroscopy, a source with a broad bandwidth and a flux that is reasonably independent of wavelength is required. The meaning of the vague qualifiers "broad" and "reason-ably" vary widely, of course, with the specific application. The prototype incoher ent broadband source is the black-body radiator with a spectral radiance given by Planck's law:

λ,=T=A/λ5expB/λTWcm−2sr−1nm−1,

  (1)

where the constants A and B are given by

=2hc2=3.97×1020nm5,

and

=chk=1240nmeV,

h is Planck's constant, c is the velocity of light, and k is Boltzmann's constant. The numerical values above and those elsewhere in this chapter assume wavelengths, λ, in nm, and temperatures, T, in units of electron volts, T (eV) = T (K)/11605.

Although the dependence of the black-body spectral radiance on source temperature (Eq. 1) is quite familiar, it is worth repeating that, as the temperature is raised, not only does the peak emission shift to shorter wavelengths, but the emission at every wavelength also increases. Thus, for such sources hotter is always...

Erscheint lt. Verlag 23.7.1997
Mitarbeit Herausgeber (Serie): F. B. Dunning, Randall G. Hulet
Chef-Herausgeber: Marc De Graef, Thomas Lucatorto
Sprache englisch
Themenwelt Naturwissenschaften Physik / Astronomie Atom- / Kern- / Molekularphysik
Naturwissenschaften Physik / Astronomie Optik
Naturwissenschaften Physik / Astronomie Quantenphysik
Technik
ISBN-10 0-08-086019-2 / 0080860192
ISBN-13 978-0-08-086019-0 / 9780080860190
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