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Advances in Atomic, Molecular, and Optical Physics

Advances in Atomic, Molecular, and Optical Physics (eBook)

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2003 | 1. Auflage
628 Seiten
Elsevier Science (Verlag)
978-0-08-047177-8 (ISBN)
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This series, established in 1965, is concerned with recent developments in the general area of atomic, molecular and optical physics. The field is in a state of rapid growth, as new experimental and theoretical techniques are used on many old and new problems.

Topics covered include related applied areas, such as atmospheric science, astrophysics, surface physics and laser physics. Articles are written by distinguished experts who are active in their research fields.

The articles contain both relevant review material and detailed descriptions of important recent developments.
This series, established in 1965, is concerned with recent developments in the general area of atomic, molecular and optical physics. The field is in a state of rapid growth, as new experimental and theoretical techniques are used on many old and new problems. Topics covered include related applied areas, such as atmospheric science, astrophysics, surface physics and laser physics. Articles are written by distinguished experts who are active in their research fields. The articles contain both relevant review material and detailed descriptions of important recent developments.

Front Cover 1
Advances in Atomic, Molecular, and Optical Physics, Volume 49 4
Copyright Page 5
Contents 6
Contributors 10
Chapter 1. Applications of Optical Cavities in Modern Atomic, Molecular, and Optical Physics 12
I. Introduction 13
II. Mode Structure and Relevant Characteristics of Fabry–Perot Cavities 18
III. Cavity Enhancement: A Simple Physics Picture 20
IV. Weak Absorption Measured by Field-Phase (Frequency-Domain) 26
V. Weak Absorption Measured by Field Decay (Time-Domain) 44
VI. From Optical Frequency Metrology to Ultrafast Technology 51
VII. Quantum Dynamics 70
VIII. Concluding Remarks on Cavity Enhancement 87
IX. Acknowledgements 89
X. References 89
Chapter 2. Resonance and Threshold Phenomena in Low-Energy Electron Collisions with Molecules and Clusters 96
I. Introduction 96
II. Theory 103
III. Experimental Aspects 124
IV. Case Studies 134
V. Conclusions and Perspectives 202
VI. Acknowledgements 207
VII. References 207
Chapter 3. Coherence Analysis and Tensor Polarization Parameters of (y ey) Photoionization Processes in Atomic Coincidence Measurements 228
I. Introduction 229
II. Theory 234
III. Different Experimental Setups 251
IV. Angular Distribution and Electron–Photon Polarization 265
V. Analysis of a Special Case J0 = 0.J = 1/2 Transitions 274
VI. Experimental Approaches and Results 283
VII. Conclusion and Outlook 292
VIII. Acknowledgments 294
IX. Appendix A: Expansion of Dipole Matrix Elements 294
X. Appendix B: Contraction of B Coefficients 297
XI. Appendix C: Reduction of A Coefficients 299
XII. References 300
Chapter 4. Quantum Measurements and New Concepts for Experiments with Trapped Ions 304
I. Overview 304
II. Spin Resonance with Single Yb+ Ions 311
III. Elements of Quantum Measurements 316
IV. Impeded Quantum Evolution: the Quantum Zeno Effect 326
V. Quantum State Estimation Using Adaptive Measurements 343
VI. Quantum Information 354
VII. References 379
Chapter 5. Scattering and Reaction Processes in Powerful Laser Fields 384
I. Scattering Processes 384
II. Reactions 433
III. Coherent Control 501
IV. Final Comments 526
V. Acknowledgments 527
VI. References 7
Chapter 6. Hot Atoms in the Terrestrial Atmosphere 544
I. Introduction 544
II. Terrestrial Neutral Atmosphere and Ionosphere 546
III. Sources of Hot Atoms 549
IV. Sinks of Hot Atoms 554
V. Thermalization of Hot Atoms in Collision with Bath Gases 556
VI. Hot Atoms and Space Vehicle Glow 573
VII. Large NO Densities at 105 km 589
VIII. References 592
Index 596
Contents of Volumes in this Serial 626

Applications of Optical Cavities in Modern Atomic, Molecular, and Optical Physics


Jun Ye1 ye@jila.colorado.edu; Theresa W. Lynn2    1 JILA, National Institute of Standards and Technology and University of Colorado, Boulder, Colorado 80309-0440, USA
2 Norman Bridge Laboratory of Physics, Room 12-33, California Institute of Technology, Pasadena, California 91125, USA

Publisher Summary


This chapter discusses applications of optical cavities in modern atomic, molecular, and optical physics. For many contemporary physics experiments, the use of an optical cavity has become a powerful tool for enhancement in detection sensitivities, nonlinear interactions, and quantum dynamics. Indeed, an optical cavity allows one to extend the interaction length between matter and field, to build up the optical power, to impose a well-defined mode structure on the electromagnetic field, to enable extreme nonlinear optics, and to study manifestly quantum mechanical behavior associated with the modified vacuum structure and/or the large field associated with a single photon confined to a small volume. Experimental activities that have benefited from the use of optical cavities appear in such diverse areas as ultra-sensitive detection for classical laser spectroscopy, nonlinear optical devices, optical frequency metrology and precision measurement, and cavity quantum electrodynamics (cavity QED). One of the important themes in laser spectroscopy is to utilize an extended interaction length between matter and field inside a high finesse cavity for increased detection sensitivity. Two key ingredients are needed to achieve the highest sensitivity possible in detection of atomic and molecular absorptions: enhancement of the absorption signal and elimination of technical noise. The chapter discusses exploration of quantum dynamics associated with the enhanced interaction between atoms and cavity field; where the structure of the cavity enables a large field amplitude associated with single intracavity photons, the system dynamics can become manifestly quantum and nonlinear.

I Introduction


For many contemporary physics experiments, the use of an optical cavity has become a powerful tool for enhancement in detection sensitivities, nonlinear interactions, and quantum dynamics. Indeed, an optical cavity allows one to extend the interaction length between matter and field, to build up the optical power, to impose a well-defined mode structure on the electromagnetic field, to enable extreme nonlinear optics, and to study manifestly quantum mechanical behavior associated with the modified vacuum structure and/or the large field associated with a single photon confined to a small volume. Experimental activities that have benefited from the use of optical cavities appear in such diverse areas as ultra-sensitive detection for classical laser spectroscopy, nonlinear optical devices, optical frequency metrology and precision measurement, and cavity quantum electrodynamics (cavity QED). Of course the most important application of optical cavities is in laser physics itself. However, in this article we will concentrate on the various applications of external optical cavities (independent from lasers) that take advantage of the common physical properties associated with resonator physics.

One of the important themes in laser spectroscopy is to utilize an extended interaction length between matter and field inside a high finesse cavity for an increased detection sensitivity. Two key ingredients are needed to achieve the highest sensitivity possible in detection of atomic and molecular absorptions: enhancement of the absorption signal and elimination of technical noise. While the absorption signal is enhanced by an optical cavity, it is important also to take measures to avoid technical noise; the sharp resonances of the cavity can introduce additional noise through frequency-to-amplitude noise conversion. Cavity vibration and drifts can also contribute noise beyond the fundamental, quantum-noise limit. In this article (Sections IV and V), we will discuss the application of various modulation techniques combined with suitable experimental configurations that let one benefit from the signal enhancement aspect of a cavity, at the same time suppressing the technical noise in the detection process. Such achievement has enabled studies of molecular vibration dynamics of weak transitions.

Another important theme is the application of optical frequency metrology for precision measurements. Section VI addresses the role of optical cavities in this context. Certainly the use of an optical cavity for laser frequency stabilization is critical for the development of super-stable optical local oscillators. The extreme quality factor (1015) associated with some “forbidden” optical transitions in cold and trapped samples of atoms and ions demands a similar or even higher quality factor on the optical probe source to take full advantage of the system coherence. Although the advent of femtosecond-laser-based optical frequency combs has to a certain degree reduced the utility of cavity-based frequency reference systems, stable optical cavities continue to provide important services in laser laboratories; either the cavity modes themselves provide optical frequency markers or a cavity helps enhance optical to microwave frequency coupling via an intracavity modulator. And one of the most important applications of optical cavities is still for laser frequency stabilization, with the scope now extended to cover ultrafast lasers as well. In fact, cavity-based ultra-sensitive detection of atomic/molecular absorptions represents an important approach to produce accurate and precise frequency references throughout the visible and near-infrared wavelength regions. We also note that some of the most demanding work in precision measurement is now associated with cavity-enhanced Michelson interferemetry to search for gravitational waves or violation of relativity laws.

A third theme that will be covered in this article (Section VII) is the exploration of quantum dynamics associated with the enhanced interaction between atoms and cavity field; where the structure of the cavity enables a large field amplitude associated with single intracavity photons, the system dynamics can become manifestly quantum and nonlinear. A high cavity finesse suppresses the dissipation rate associated with photon decay while a well-defined spatial mode of the cavity output field (associated with cavity decay) permits recovery of information about the intracavity dynamics with high quantum efficiency. Although cavities in the optical domain have not significantly influenced the atomic radiative properties in a direct manner, the enhanced coherent interactions between them present an ideal platform to study open quantum systems.

Before addressing these topics in detail, we begin with some broad comments and historical context in the remainder of this introduction. Section II is devoted to description and characterization of the optical cavities themselves, while Section III gives some simple physical arguments for the cavity enhancement effect that is crucial for applications ranging from classical spectroscopy to cavity QED.

A Signal Enhancement and Optical Field Buildup Inside a Cavity


Improving sensitivity for spectroscopy on an atomic or molecular sample by placing it inside an optical resonator is a well-known technique and is most commonly explained in terms of the multipass effect. In fact, it was realized in the early days of laser development that a laser cavity was useful for absorption enhancement [1], owing to the multipass effect and the delicate balance between the laser gain and intracavity absorption [2,3]. However, in most recent implementations, it is often preferable to separate the absorber from the laser, in order to extend the experimental flexibility and to characterize better working parameters. Kastler first suggested that a Fabry-Perot cavity be employed for the sensitivity of its transmission to small variations in absorption within the cavity [4]. The external cavity approach has since been applied to record both linear and high-resolution nonlinear molecular spectra [57]. In particular, enhancement cavities in the form of cavity ring down spectroscopy [8,9] have been extensively applied in the field of physical chemistry to study molecular dynamics and reaction kinetics.

While we defer a detailed discussion of cavity enhancement effects to Section III, here we make a quick note of the advantages associated with an optical resonator. The well-known multipass effect leads to an enhancement of the effective absorption length by a factor of 2F/π, where F is the cavity finesse. Additionally, the intracavity optical power is built up relative to the input power via constructive interference, which allows for the study of nonlinear interactions even with low-power laser sources. An often taken-for-granted benefit in practice is that although the intracavity interaction is powered by a high field amplitude, the cavity reduces the output power to a reasonable level acceptable for subsequent photo-detectors. Alternatively, high intracavity power can be extracted using high-speed optical switching devices; this forms the basis of a cavity-based optical amplifier to be discussed in Section VI.D. Additionally, the geometrical self-cleaning and mode matching of the optical waves inside a cavity is important both for eliminating pointing-direction related noise and for...

Erscheint lt. Verlag 21.11.2003
Mitarbeit Herausgeber (Serie): Benjamin Bederson, Herbert Walther
Sprache englisch
Themenwelt Sachbuch/Ratgeber
Naturwissenschaften Physik / Astronomie Angewandte Physik
Naturwissenschaften Physik / Astronomie Astronomie / Astrophysik
Naturwissenschaften Physik / Astronomie Atom- / Kern- / Molekularphysik
Naturwissenschaften Physik / Astronomie Festkörperphysik
Naturwissenschaften Physik / Astronomie Optik
Technik
ISBN-10 0-08-047177-3 / 0080471773
ISBN-13 978-0-08-047177-8 / 9780080471778
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