Remote sensing and atmospheric ozone: human activities versus natural variability/ (Record no. 177125)
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000 -LEADER | |
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fixed length control field | 09105nam a2200145Ia 4500 |
020 ## - INTERNATIONAL STANDARD BOOK NUMBER | |
International Standard Book Number | 9783642103339 |
040 ## - CATALOGING SOURCE | |
Transcribing agency | CUS |
082 ## - DEWEY DECIMAL CLASSIFICATION NUMBER | |
Classification number | 621.3678 |
Item number | CRA/R |
100 ## - MAIN ENTRY--PERSONAL NAME | |
Personal name | Cracknell ,Arthur P. |
245 #0 - TITLE STATEMENT | |
Title | Remote sensing and atmospheric ozone: human activities versus natural variability/ |
Statement of responsibility, etc. | Arthur P. Cracknell |
260 ## - PUBLICATION, DISTRIBUTION, ETC. (IMPRINT) | |
Place of publication, distribution, etc. | Heidelberg: |
Name of publisher, distributor, etc. | Springer-Verlag, |
Date of publication, distribution, etc. | c2012. |
300 ## - PHYSICAL DESCRIPTION | |
Extent | xli, 662 p |
505 ## - FORMATTED CONTENTS NOTE | |
Formatted contents note | <br/>1 Tbe traditional measurement of ozone concentration in the atmosphere. . 1<br/>1.1 Introduction 1<br/>1.1.1 Observations of the total ozone column 4<br/>1.2 Ground-based instrumentation for TOC observations 5<br/>1.2.1 The Dobson ozone spectrophotometer 7<br/>1.2.2 Intercomparison of Dobson spectrophotometers 10<br/>1.2.3 Interference of SO2 and NO2 in Dobson TOC measure<br/>ments 19<br/>1.2.4 Influence of stray light on Dobson TOC measurements . 24<br/>1.3 Brewer Spectrophotometer 34<br/>1.4 Filter ozonometers M-83/124/134 37<br/>1.5 Secondary ground-based instrumentation for TOC observations . 39<br/>1.5.1 System for Analysis of Observation at Zenith (SAOZ) . . 42<br/>1.5.2 MICROTOPS II (Total Ozone Portable Spectrometer) . 42<br/>1.5.3 High-Resolution Visible/Ultraviolet Absorption Spectroscopy<br/>1.5.4 Fourier transform spectrometer (FTS) 43<br/>1.5.5 System for the Monitoring of Stratospheric Compounds<br/>(SYMOCS) 46<br/>1.5.6 Star Pointing Spectrometer (SPS) 46<br/>1.5.7 MDR-23 (a Russian "commercial device) 46<br/>vi Contents<br/>1.5.8 Scanning spcc from clcr (EVA) 47<br/>1.5.9 Solar IR spcclroradiomctcr 47<br/>1.5.10 Ground-based UV radiometer (GUV) 47<br/>1.5.1 1 Spectrometer Ozonometer PION 48<br/>1.5.12 spectrometer for Atmospheric TRAcers Monitoring<br/>(SPATRAM) 48<br/>1.6 Observations of ozone vertical profile (OVP) 50<br/>1.6.1 Primary ground-based instrumentation for OVP observa<br/>tions 50<br/>1.6.2 Dobson Umkehr measurements and inversion 51<br/>1.6.3 Brewer Umkehr measurements 54<br/>1.6.4 Secondary ground-based instrumentation for OVP obser<br/>observations 55<br/>1.6.5 Lidar 55<br/>1.6.6 Microwave radiometry 56<br/>1.6.7 Ground-based Millimeter wave Ozone Spectrometer<br/>(GROMOS) 57<br/>1.6.8 Stratospheric Sounding by Infrared Heterodyne<br/>Spectroscopy (SIRHS) 57<br/>1.6.9 Ground-based microwave radiometers 58<br/>1.6.10 Ground-based infrared solar spectroscopy 59<br/>1.6.1 1 Stratospheric Ozone Monitoring Radiometer (SOMORA) 59<br/>1.7 Airborne instrumentation for OVP observations 61<br/>1.7.1 Electrochemical ozonesondes 01<br/>1.7.2 Optical ozonesondes 04<br/>1.7.3 Other balloon instrumentation 07<br/>1.7.4 Aircraft instrumentation 71<br/>1.8 Surface ozone measurements 77<br/>1.8.1 Chemiluminescence method 77<br/>1.8.2 Electrochemical potassium iodide method 77<br/>1.8.3 UV absorption method 77<br/>Satellite systems for studies of atmospheric ozone 79<br/>2.1 Satellite remote sounding of TOC 82<br/>2.2 Direct absorption measuring instruments ' ' "<br/>2.2.1 TIROS Operational Vertical Sounder (TOVS); GOES . . 83<br/>2.2.2 Laser Heterodyne Spectrometer (LHS)/Tunable Diode<br/>LHS (TDLHS)<br/>2.2.3 OZON-MIR<br/>2.3 Indirect absorption measuring instruments 86<br/>2.3.1 Total Ozone Mapping Spectrometer (TOMS) 86<br/>2.3.2 Ozone Monitoring Instrument (OMI) 90<br/>2.3.3 Advanced Earth Observing Satellite (ADEOS I93<br/>23.4 Solar Backscattered Ultraviolet Radiometer (SBUV) . . . 93<br/>2.3.5 Global Ozone Monitoring Experiment (GOME) 96<br/>2.3.6 ESA ENVISAT. GOMOS 98<br/>2.3.7 The Ozone Mapping and Profiler Suite (OMPS) and the<br/>NPOESS 99<br/>2.3.8 Ozone Dynamics Ultraviolet Spectrometer (ODUS) . . . 101<br/>2.3.9 Ozone Layer Monitoring Experiment (OLME) 101<br/>2.3.10 Interferometric Monitor for Greenhouse Gases (IMG) . 101<br/>2.3.11 Infrared Atmospheric Sounding Interferometer 102<br/>2.4 Observed variability in total ozone column 102<br/>2.4.1 Latitudinal variation of TOC 102<br/>2.4.2 Longitudinal variation of TOC 106<br/>2.5 Satellite instrumentation for OVP observations 106<br/>2.5.1 Direct-absorption measuring instruments 107<br/>2.5.2 Scattering-measuring instruments 116<br/>2.5.3 Emission-measuring instruments 118<br/>2.5.4 Summary of ozone-monitoring satellites 130<br/>2.6 Observed variability in vertical ozone distribution 130<br/>2.6.1 EASOE 141<br/>2.6.2 SESAME 142<br/>2.6.3 THESEO 142<br/>2.6.4 SOLVE 142<br/>2.6.5 ORACLE-O3 143<br/>2.6.6 SC0UT-03 144<br/>2.6.7 Match 144<br/>2.6.8 ARC IONS 145<br/>Intercomparisons between various atmospheric ozone datasets 149<br/>3.1 Introduction 149<br/>3.2 Total ozone measurements over Athens: intercomparison between<br/>Dobson, TOMS (version 7), SBUY, and other satellite measure<br/>ments 152<br/>3.3 Geophysical validation of MIPAS-ENVISAT operational ozone<br/>data 161<br/>3.3.1 Introduction to MIPAS 161<br/>3.3.2 MIPAS ozone data 163<br/>3.3.3 Comparison of MIPAS data with WMO/GAW ground-<br/>based measurements 164<br/>3.4 Comparison of MIPAS data with stratospheric balloon and<br/>aircraft measurements 190<br/>3.4.1 MIPAS-B2 190<br/>3.4.2 FIRS-2 and IBEX 193<br/>3.4.3 SPIRALE 198<br/>3.4.4 MIPAS-STR, SAFIRE-A, and FOZAN on board the<br/>M-55 Geophysica aircraft 200<br/>3.4.5 ASUR 207<br/>Contents vn<br/>viii Contents<br/>3.5 Comparison with satellite measurements 208<br/>3.5.1 Comparison of MIPAS data with SAGE II profiles . 211<br/>3.5.2 Comparison with POAM III O3 profiles 213<br/>3.5.3 Comparison with Odin-SMR O3 profiles 216<br/>3.5.4 Comparison with ACE-FTS O3 profiles 220<br/>3.5.5 Comparison with HALO O3 profiles 223<br/>3.5.6 Comparison with GOME O3 profiles 229<br/>3.5.7 Comparison with SCI AM ACHY and GOMOS 231<br/>3.6 Comparison of MIPAS data with ECMWF assimilated fields. . . 234<br/>3.7 Summary of MIPAS comparisons —<br/>3 8 Other intercomparisons between various ozone-monitoring<br/>systems<br/>3 8 I TOMS GOME, GOMOS, and SCIAMACHY data . . . -45<br/>3.8.2 MLS data ;<br/>3.8.3 SAGE data<br/>3.8.4 TES data<br/>3.8.5 ACE and lASI data <br/>3.8.6 Ozonesonde intercomparisons<br/><br/>4 The dynamics of atmospheric ozone<br/>4.1 Total ozone trends ~<br/>4.2 Ozone vertical profile variability. • • • • • ~ _<br/>4.3 General features of ozone global distribution -<br/>4.3.1 Stratosphere troposphere exchange<br/>4.3.2 Low-ozone pockets •<br/>4.4 The non-linear nature of ozone variability; detrended fluctuation<br/>analysis (DFA) ' '<br/>4.4.1 Long-memory processes in global ozone and temperature<br/>variations "<br/>4.4.2 Long-term memory dynamics of total ozone content . . .<br/>4.4.3 Scaling behavior of the global tropopause . • •<br/>4.4.4 Scaling properties of air pollution at the surface; surface<br/>ozone (SOZ)<br/>4.5 Impacts of the solar eclipse of March 29. 2006 on surface ozone<br/>and related air pollutants<br/>4.6 Long-term coupling between TOC and tropopause properties . . .^27<br/>4.6.1 Occurrence frequency of tropopause height . . _ _ _ • ' '<br/>4.6.2 Association between tropopause properties and TO<br/>4.6.3 The tropopause; summary<br/>5 The Montreal Protocol<br/>5 1 Introduction , f'.<br/>5.2 The proposition by Molina and Rowland of human releases of<br/>CFCs being responsible for ozone depletion '<br/>5.3 The science from 1974 to 1985. .<br/>339<br/>5.4 The Ozone Hole 351<br/>5.5 The role of remote sensing in the lead-up to the Montreal<br/>Protocol 358<br/>5.6 The NOZE and AAGE expeditions 358<br/>5.7 Theories of the Ozone Hole 363<br/>5.8 Diplomacy, 1974-1989; formulation and ratification of the<br/>Montreal Protocol 366<br/>5.9 Reasons for the success in reaching international agreement in<br/>Montreal 368<br/>5.10 Ratification of the Montreal Protocol 372<br/>6 The study of atmospheric ozone since 1987 379<br/>6.1 Introduction 379<br/>6.2 The reduction of ozone-destroying chemicals in the atmosphere<br/>6.2.1 Ozone depletion potential (ODP)<br/>6.2.2 Equivalent Effective Stratospheric Chlorine (EESC). . .<br/>6.3 Ground-based and ozonesonde data on ozone depletion<br/>6.4 Piecewise linear trends in ozone depletion<br/>6.5 Recovery of the ozone layer; the polar regions<br/>6.5.1 Sudden stratospheric warmings<br/>6.5.2 Observation of sudden stratospheric warmings detected in<br/>deep underground muon data 417<br/>6.5.3 The role of the diffusion of gases in ice or an amorphous<br/>binary mixture in the polar stratosphere and the upper<br/>troposphere 420<br/>6.5.4 Experimental studies of the Antarctic ozone hole and<br/>ozone loss in the Arctic 425<br/>6.5.5 Antarctic ozone hole predictability; use of natural time<br/>series 441<br/>6.6 Long-term monitoring of the ozone layer 448<br/>6.6.1 Measurement of TOG and the OVP 452<br/>6.6.2 The use of models to predict ozone concentration . . . . 454<br/>6.6.3 Ozonesonde networks 469<br/>6.6.4 Trends in TOG and tropopause properties 474<br/>6.7 Scientific assessment of ozone depletion 2010 478<br/>7 Atmospheric ozone and climate 485<br/>7.1 Introduction 485<br/>7.2 Radiative-forcing calculations 492<br/>7.2.1 Estimates of changes in RF from pre-industrial times to<br/>the present 492<br/>7.2.2 Detailed studies of changes in RF in recent decades . . . 497<br/>7.2.3 Contribution of the transport sector 515<br/>7.3 Ozone-induced climatic impacts 517<br/>7.3.1 The health impacts of changes in ozone concentration . . 543<br/>7.4 Conclusions on iropo-stralosphcric variabiiily 544<br/>7.4.1 Stratospheric ozone dynamics and its determining factors 545<br/>7.4.2 Tropospheric processes 546<br/>7.5 New climate research aspects deduced from global ozone<br/>dynamics research and remote sensing 547<br/>7.5.1 Climate modeling and atmospheric ozone 547<br/>7.5.2 Role of phase transitions in climate system dynamics. . . 549<br/>7.5.3 Nambu dynamics and ozone climate modeling 550<br/>7.5.4 Dissipation-induced instabilities in ozone and climate<br/>fields •<br/>7 5 5 Deterministic, chaotic, or stochastic ozone climate time<br/>series<br/>7.6 WMO/UNEP Scientific Assessment 2010 554<br/> |
942 ## - ADDED ENTRY ELEMENTS (KOHA) | |
Koha item type | General Books |
Withdrawn status | Lost status | Damaged status | Not for loan | Home library | Current library | Shelving location | Date acquired | Full call number | Accession number | Date last seen | Date last checked out | Koha item type |
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Central Library, Sikkim University | Central Library, Sikkim University | General Book Section | 29/08/2016 | 621.3678 CRA/R | P32127 | 24/07/2023 | 03/07/2023 | General Books |