E-Book, Englisch, Band 231, 588 Seiten
Reihe: NATO Science Series II: Mathematics, Physics and Chemistry
Di Bartolo / Forte Advances in Spectroscopy for Lasers and Sensing
2006
ISBN: 978-1-4020-4789-3
Verlag: Springer Netherlands
Format: PDF
Kopierschutz: 1 - PDF Watermark
E-Book, Englisch, Band 231, 588 Seiten
Reihe: NATO Science Series II: Mathematics, Physics and Chemistry
ISBN: 978-1-4020-4789-3
Verlag: Springer Netherlands
Format: PDF
Kopierschutz: 1 - PDF Watermark
This volume presents the Proceedings of 'New Development in Optics and Related Fields,' held in Italy in June, 2005. This meeting was organized by the International School of Atomic and Molecular Spectroscopy of the 'Ettore Majorana' Center for Scientific Culture. The purpose of this Institute was to provide a comprehensive and coherent treatment of the new techniques and contemporary developments in optics and related fields.
Autoren/Hrsg.
Weitere Infos & Material
1;CONTENTS;7
2;PREFACE;20
3;LIST OF PAST INSTITUTES;23
4;SPECTROSCOPY OF PHOTONIC ATOMS: A MEANS FOR ULTRA-SENSITIVE SPECIFIC SENSING OF BIO-MOLECULES;26
5;LASER SOURCES FOR HIGH RESOLUTION SENSING;44
6;RELAXATION AND DECOHERENCE: WHAT’S NEW?;58
7;CHALLENGES FOR CURRENT SPECTROSCOPY: DETECTION OF SECURITY THREATS;88
8;SOURCES FOR THREAT DETECTION;98
9;Yb3+ 2 APPROACH IN SOLID-STATE LASER-TYPE CRYSTALS-DOPED CaF FLUORIDE AS AN EXAMPLE OF OUR RESEARCH;108
10;TERAHERTZ SENSING AND MEASURING SYSTEMS;128
11;ULTRAFAST SPECTROSCOPY OF BIOLOGICAL SYSTEMS;144
12;LUMINESCENCE SPECTROSCOPY OF SOLIDS: LOCALIZED SYSTEMS;154
13;LASER SPECTROMETERS FOR ATMOSPHERIC ANALYSIS;182
14;SENSITIVE DETECTION TECHNIQUES IN LASER SPECTROSCOPY;212
15;LUMINESCENCE SPECTROSCOPY OF SOLIDS: DELOCALIZED SYSTEMS;232
16;LASER INDUCED BREAKDOWN SPECTROSCOPY (LIBS);254
17;OPTICAL SPECTROSCOPY OF SEMICONDUCTOR QUANTUM STRUCTURES;280
18;ZnO REDISCOVERED – ONCE AGAIN!?;302
19;COHERENT SPECTROSCOPY OF SEMICONDUCTOR NANOSTRUCTURES;320
20;DYNAMICS OF UPCONVERSION IN LASER CRYSTALS;358
21;WAVEGUIDE FABRICATION METHODS IN DIELECTRIC SOLIDS;360
22;SPECTRAL PROPERTIES OF FILMS;376
23;BASIC PHYSICS OF SEMICONDUCTOR LASERS;390
24;JUDD-OFELT THEORY: PRINCIPLES AND PRACTICES;428
25;PERIODIC DIELECTRIC AND METALLIC PHOTONIC STRUCTURES;460
26;COOLING AND TRAPPING OF ATOMS;484
27;NON-LINEAR PROPAGATION OF FEMTOSECOND TERAWATT LASER PULSES IN AIR AND APPLICATIONS;486
28;SPECTROSCOPY OF THE GAP STATES IN Ge BASED ON ITS NEUTRON e TRANSMUTATION DOPING KINETICS;508
29;INTERDISCIPLINARY LECTURES THE STATUS OF UNIFIED THEORIES OF FUNDAMENTAL INTERACTIONS;524
30;ANGULAR MOMENTUM OF THE HUMAN BODY;538
31;CLIMATE CHANGE AND GLOBAL SECURITY;540
32;SEMINARS;564
32.1;UV-LASER IRRADIATION OF AMORPHOUS SIO2: GENERATION AND CONVERSION OF POINT DEFECTS AND POST-IRRADIATION PROCESSES ;564
32.2;MAGNETO-OPTICAL SPECTROSCOPY AND SPIN INJECTION;566
32.3;NEW CRYSTALS OF SARCOSINE COMPLEXES: STRUCTURE, VIBRATIONAL SPECTRA AND PHASE TRANSITIONS;566
32.4;SCATTERING STATE SPECTROSCOPY AS A PROBE OF CHEMICAL REACTION DYNAMICS AND NON-RADIATIVE ENERGY TRANSFER: LI(NP) + M SYSTEM;567
32.5;OPTICAL AND ELECTRICAL INVESTIGATION OF THE PHOTOREFRACTIVE PROPERTIES OF HAFNIUM-DOPED CONGRUENT LITHIUM NIOBATE SINGLE CRYSTALS.;568
32.6;EFFECT OF THE COMPOSITION ON SPECTROSCOPIC AND STRUCTURE OF TM3+: TEO2-PBF2 GLASSES;568
32.7;FOURIER TRANSFORM INFRARED SPECTROSCOPY ON ZN1-XMNXSE EPILAYERS;569
32.8;FEMTOSECOND LASER DISSECTION OF NEURONS IN C. ELEGANS;570
32.9;ULTRAFAST DYNAMICS OF METALLIC THIN FILMS;570
33;POSTERS;571
33.1;RAMAN SCATTERING OF MG2SI PRODUCED BY IBS ;571
33.2;OPTICAL PROPERTIES OF FEW AND SINGLE ZNO NANOWIRES;571
33.3;INVESTIGATIONS OF A FADOF SYSTEM AS AN EDGE-FILTER RECEIVER FOR A BRILLOUIN-LIDAR FOR REMOTE SENSING OF THE OCEAN TEMPERATURE;571
33.4;RAMAN STUDY OF THE EFFECT OF THE ANNEALING ON ION-BEAM
SYNTHESIZED ß-FESI2 LAYERS;572
33.5;AVOIDING THERMAL EFFECTS IN Z-SCAN MEASUREMENT BY HIGH REPETITION RATE LASERS;572
33.6;TOWARDS CONTROL OF PHOTODYNAMICS BY FEMTOSECOND POLARISATION SHAPING AND COINCIDENCE VELOCITY MAP IMAGING;573
33.7;LABORATORY FREQUENCY METROLOGY AND THE SEARCH FOR A TEMPORAL
VARIATION OF THE FINE STRUCTURE CONSTANT a ON A COSMOLOGICAL
TIME SCALE;574
33.8;DIPOLE STRENGTHS OF THE PHOTOSYNTHETIC PIGMENTS AND CAROTENOIDES FROM BACTERIA PROSTECOCHLORIS AESTUARI;574
33.9;PERSISTENT LUMINESCENCE OF LU2O3 :TB CERAMICS;575
33.10;SPECTROSCOPIC MONITORING OF THE FORMATION OF DISPERSED MANGANESE OXIDE ON ALUMINA SURFACE;575
33.11;TRANSIENT LOCAL STRUCTURE OF SOLVATED TRANSITION METAL COMPLEXES PROBED BY PICOSECOND TIME-RESOLVED XAFS;576
33.12;STRUCTURAL AND LUMINESCENCE PROPERTIES OF EUROPIUM DOPED BA1-XSRX R TIO3 NANOCRYSTALLITES PREPARED BY DIFFERENT METHODS;577
33.13;WAVEGUIDE STRUCTURES WRITTEN WITH FS-LASER PULSES ABOVE THE CRITICAL SELF-FOCUSING THRESHOLD IN SIO2-PBO BASED GLASSES;578
33.14;THE LATTICE RESPONSE OF QUANTUM SOLIDS TO AN IMPULSIVE LOCAL PERTURBATION;578
33.15;APPLICATION OF IN-PLANE TRANSPORT IN GAAS-BASED NANOSTRUCTURES FOR BROAD BAND AND SELECTIVE THZ SENSING;579
33.16;MICROSTRUCTURE AND PROPERTIES OF PERIODIC MULTILAYER THIN-FILM STRUCTURES WITH NANOCRYSTALS;580
33.17;STRUCTURAL AND OPTICAL STUDIES OF ERBIUM DOPED NANOCRYSTALLINE SILICON THIN FILMS PRODUCED BY R.F. SPUTTERING;580
33.18;THIN FILMS PRODUCED BY R.F. SPUTTERING MICROSTRUCTURE AND THERMAL FEATURES OF A-SI:H AND NC-SI:H;581
33.19;CONFOCAL MICROSCOPY FOR INVESTIGATIONS ON LITHIUM FLUORIDE COLOUR CENTERS;582
33.20;CAVITY RING-DOWN SPECTROSCOPY AS A DETECTOR IN LIQUID CHROMATOGRAPHY;582
33.21;OPTOELECTRONIC DEVICES USING FEMTOSECOND LASER MICROSTRUCTURED SILICON;583
34;INDEX;585
TERAHERTZ SENSING AND MEASURING SYSTEMS (p. 103)
JOHN W. BOWEN
Cybernetics
The University of Reading
Whiteknights, Reading
RG6 4EU, United Kingdom
cybjb@cyber.reading.ac.uk,
1. Introduction
The terahertz (THz) region of the electromagnetic spectrum extends from 100 GHz to 10 THz, a wavelength range of 3 mm to 30 µm. While it is the last part of the electromagnetic spectrum to be fully explored, systems operating in this frequency range have a multitude of applications, in areas ranging from astronomy and atmospheric sciences to medical imaging and DNA sequencing.
As the terahertz range lies between the microwave and infrared parts of the spectrum, techniques from both of these neighbouring regions may be extended, specially adapted and at these frequencies has traditionally been difficult and expensive because of the low power available from sources and the precision machining required in their fabrication. Recently, new techniques based on the generation and detection of terahertz radiation using ultra-fast pulsed lasers have been developed and these have led to exciting advances in terahertz imaging and spectroscopy. The output frequencies of quantum cascade lasers have also been steadily moving down into the terahertz range and may lead to compact solid-state terahertz sources in the near future.
This paper will cover techniques for the generation, detection and analysis of terahertz radiation. After a discussion of quasi-optical techniques for the design of terahertz systems, the operation of three exemplar terahertz systems will be explained. Following a summary of terahertz sources and detectors, an overview of the operation of terahertz systems for a wide range of sensing and measuring applications will be given.
2. Waveguides versus Quasi-optics
At microwave frequencies, systems are often based around hollow metal pipe waveguides, typically of rectangular or circular cross-section, which provide a means of controlled propagation of the radiation. This approach may be carried over into the terahertz region, although, School of Systems Engineering
hybridised for the generation, detection and analysis of terahertz radiation. However, operation as the frequency increases, the skin depth in metals decreases and obtaining a surface finish on the inside walls of the waveguide sufficient to keep propagation loss at an acceptable level becomes increasingly difficult. Exacerbating this is the fact that the cross-sectional dimensions of a single-moded (i.e. dispersionless) waveguide must be reduced as the frequency is increased. This makes hollow metal waveguide difficult and expensive to manufacture for the terahertz region using conventional machining techniques. Terahertz hollow metal waveguide structures fabricated using thick resist photolithographic micro-machining [1] have been demonstrated to frequencies as high as 1.6 THz, but the fabrication technique is still in its infancy. The use of other types of transmission line have been explored, for example dielectric waveguide and planar transmission lines such as microstrip, but losses confine their use to the lower frequency end of the terahertz range, most having an upper usable frequency of about 150 GHz.
As an alternative, many systems operating at terahertz frequencies make use of optical components, such as lenses and reflectors, to control and manipulate beams travelling through free-space. The advantages of this approach in comparison to waveguide-based systems include: lower loss, wider (multi-octave) bandwidth, easier fabrication and, therefore, lower cost. However, unlike optical systems in the visible part of the spectrum, where optical components typically have lateral dimensions which are tens of thousands times the wavelength, practical size constraints limit the size of terahertz optical components to only a few tens of wavelengths. Therefore, diffraction becomes a significant aspect of propagation and must be taken into account in the design of optical systems, particularly as optical components often have to be used in the transition region between the near- and far-fields. Optical systems operating in this regime, where geometrical optics ceases to hold, are termed quasi-optical. Some of the sources and detectors used at terahertz frequencies are small compared to the wavelength and so, in order to efficiently couple power between them and a well directed freespace beam, it is necessary to use an antenna. Often, the best performance is achieved when the source or detector is mounted inside a hollow metal waveguide and a horn antenna is used to launch a beam through a quasi-optical system. Therefore, while quasi-optical propagation is to be preferred over long runs of waveguide, it is quite common for systems to include some short lengths of waveguide as well as quasi-optics.
