LEADER 00000cam a2200781Ka 4500 
001    ocn820719943 
003    OCoLC 
005    20190405013913.4 
006    m     o  d         
007    cr cnu---unuuu 
008    121210s2012    enk     ob    001 0 eng d 
019    823710288|a832791465|a887742578 
020    9781139624978|q(electronic book) 
020    1139624970|q(electronic book) 
020    9781139017572|q(electronic book) 
020    1139017578|q(electronic book) 
020    9781139615679 
020    113961567X 
020    |z9781107007444 
020    |z1107007445 
020    |z9781283870436 
020    |z1283870436 
020    9781139611954 
020    113961195X 
024 8  ebc1099841 
035    (OCoLC)820719943|z(OCoLC)823710288|z(OCoLC)832791465
       |z(OCoLC)887742578 
037    418293|bMIL 
040    N$T|beng|epn|cN$T|dYDXCP|dEBLCP|dCDX|dOCLCO|dCAMBR|dDEBSZ
       |dIDEBK|dOCLCQ|dOCLCF|dN15|dE7B|dMEU|dUMI|dDEBBG|dOCLCQ
       |dCSJ|dOCLCQ|dLIP|dOCLCQ|dNJR|dOCLCQ|dCUY|dMERUC|dZCU|dICG
       |dOCLCQ|dTKN|dDKC 
049    RIDW 
050  4 QC174.17.P7|bF72 2012eb 
072  7 SCI|x067000|2bisacsh 
072  7 SCI|2eflch 
082 04 530.14|223 
084    SCI074000|2bisacsh 
090    QC174.17.P7|bF72 2012eb 
245 00 Fragmentation processes :|btopics in atomic and molecular 
       physics /|cedited by Colm T. Whelan, Old Dominion 
       University. 
264  1 Cambridge :|bCambridge University Press,|c2012. 
300    1 online resource 
336    text|btxt|2rdacontent 
337    computer|bc|2rdamedia 
338    online resource|bcr|2rdacarrier 
340    |gpolychrome|2rdacc 
347    text file|2rdaft 
504    Includes bibliographical references and index. 
505 0  Intro -- Contents -- Contributors -- Preface -- 1 Direct 
       and resonant double photoionization: from atoms to solids 
       -- 1.1 Introduction -- 1.2 Direct double photoionization -
       - 1.2.1 The He atom -- 1.2.2 The H2 molecule and the four-
       body problem -- 1.2.3 Direct DPI in solids and surfaces --
       1.3 Indirect double photoionization -- 1.3.1 Auger 
       photoelectron coincidence spectroscopy (APECS) applied to 
       molecules -- 1.3.2 Auger photoelectron coincidence 
       spectroscopy(APECS) applied to solids -- 1.3.3 
       Interference and coherence effects in indirect double 
       photoionization -- 1.4 Conclusions -- References -- 2 The 
       application of propagating exterior complex scaling to 
       atomic collisions -- 2.1 Introduction -- 2.2 Introduction 
       to exterior complex scaling -- 2.2.1 A one-dimensional 
       example -- 2.2.2 Numerical method: propagating exterior 
       complex scaling -- 2.3 Application of ECS to electron-
       hydrogen scattering -- 2.3.1 Extracting scattering 
       amplitudes from surface integrals -- 2.3.2 Propagating 
       exterior complex scaling considerations -- 2.4 Scattering 
       in electron-hydrogen system -- 2.5 Exterior complex 
       scaling for electron-helium scattering -- 2.5.1 Extracting
       scattering amplitudes -- 2.5.2 S-wave model for electron-
       helium scattering -- 2.6 Summary and outlook for the 
       future -- References -- 3 Fragmentation of molecular-ion 
       beams in intense ultrashort laser pulses -- 3.1 
       Introduction -- 3.2 Experimental method -- 3.2.1 Laser -- 
       3.2.2 Ion beam -- 3.2.3 Crossing the laser and ion beams -
       - 3.2.4 Coincidence beam-fragment measurements -- 3.2.5 
       Coincidence 3D momentum imaging of beam fragments -- 3.3 
       Benchmark molecules -- 3.3.1 One electron diatomic 
       molecule -- H2+ -- 3.3.2 Simplest polyatomic molecule -- 
       H3+ -- 3.4 Complex and/or unique molecular ions -- 3.4.1 
       Vibrationally cold molecular ions -- CO2+ -- 3.4.2 
       Vibrationally semi-cold molecular ions -- NO2+. 
505 8  3.4.3 Other complex molecular ions -- 3.5 Summary and 
       outlook -- References -- 4 Atoms with one and two active 
       electrons in strong laser fields -- 4.1 Introduction -- 
       4.2 Theoretical model -- 4.3 Two-photon double ionization 
       of helium -- 4.4 DC-assisted double photoionization of He 
       and H- -- 4.5 Strong-field ionization of lithium and 
       hydrogen -- 4.6 High harmonics generation -- 4.7 Time 
       delay in atomic photoionization -- References -- 5 
       Experimental aspects of ionization studies by positron and
       positronium impact -- 5.1 Introduction -- 5.2 Integral 
       cross sections for positron impact ionization -- 5.3 
       Differential cross sections for positron impact ionization
       -- 5.4 Positronium-induced fragmentation -- 5.5 
       Conclusions and outlook -- References -- 6 (e,2e) 
       spectroscopy spectroscopy using fragmentation processes --
       6.1 Introduction -- 6.2 Background -- 6.3 Theory -- 6.4 
       Electron momentum spectroscopy results -- 6.5 Low-energy 
       (e,2e) results -- 6.6 Conclusion -- References -- 7 A 
       coupled pseudostate approach to the calculation of ion-
       atom fragmentation processes -- 7.1 Introduction -- 7.2 
       Theory -- 7.2.1 The impact parameter method and extraction
       of the differential motion of the projectile -- 7.2.2 
       Extracting the differential motion of the ejected electron
       -- 7.3 Antiproton-induced ionization -- References -- 8 
       Electron impact ionization using (e,2e) coincidence 
       techniques from threshold to intermediate energies -- 8.1 
       Introduction -- 8.1.1 Description of the experimental 
       coincidence technique -- 8.1.2 (e,2e) experiments near 
       threshold -- 8.1.3 (e,2e) experiments from threshold to 
       intermediate energies -- 8.1.4 Summary -- 8.2 Experimental
       methods and techniques -- 8.2.1 Materials -- 8.2.2 Design 
       of the electron gun and analyzers -- 8.2.3 Example: the (e,
       2e) spectrometer in Manchester -- 8.2.4 Multi-detection --
       the COLTRIMS reaction microscope. 
505 8  8.3 Theoretical models -- 8.3.1 Near threshold -- 8.3.2 
       The intermediate energy regime -- 8.4 Atomic targets -- 
       8.4.1 Near-threshold measurements on helium -- 8.4.2 
       Measurements on helium at intermediate energies -- 8.4.3 
       Measurements on the noble gases in the perpendicular plane
       -- 8.5 Molecular targets -- 8.5.1 Measurements from H2 -- 
       8.5.2 Measurements from polyatomic molecules -- 8.6 
       Experiments from laser-aligned atoms -- 8.6.1 The laser 
       excitation process -- 8.6.2 Ionization from laser-excited 
       magnesium -- 8.7 Future work and conclusions -- References
       -- 9 (e,2e) processes on atomic inner shells -- 9.1 (e,2e)
       processes -- an overview -- 9.2 Non-relativistic theory --
       9.3 The distorted wave Born approximation -- 9.3.1 
       Geometries -- 9.3.2 The ionization of the 2p state of 
       argon -- 9.4 Inner-shell ionization of heavy metal targets
       at relativisticimpact energies -- 9.4.1 Relativistic, 
       distorted wave Born approximation -- 9.5 General features 
       of the cross section -- 9.5.1 Coplanar asymmetric-Ehrhardt
       -geometry -- 9.5.2 Coplanar symmetric-Pochat-geometry -- 
       9.6 Special features -- 9.6.1 Spin-dependent effects using
       unpolarized beams on unpolarized targets -- 9.6.2 
       Distortion effects -- References -- 10 Spin-resolved 
       atomic (e,2e) processes -- 10.1 Introduction -- 10.2 
       Experimental considerations -- 10.2.1 Definition of 
       measured and derived parameters -- 10.2.2 Generation of 
       spin-polarized electron beams -- 10.3 Low-Z targets and 
       low electron impact energies -- 10.4 High-Z targets and 
       low electron impact energies -- 10.5 High-Z targets and 
       high electron impact energies -- 10.6 Longitudinally 
       polarized electrons -- 10.7 Conclusion -- References -- 
       Index. 
520    "Revolutionary advances in experimental techniques and 
       spectacular increases in computer power over recent years 
       have enabled researchers to develop a much more profound 
       understanding of the atomic few-body problem. One area of 
       intense focus has been the study of fragmentation 
       processes. Covering the latest research in the field, this
       edited text is the first to provide a focussed and 
       systematic treatment of fragmentation processes, bringing 
       together contributions from a range of leading experts. As
       well as tackling the more established electron-impact 
       ionization processes, (e,2e), this book also guides the 
       reader through topics such as molecular fragmentation, ion
       -atom collisions and multi-photon processes. Combining a 
       broad range of topics with an equal mix of theoretical and
       experimental discussion, this is an invaluable text for 
       graduate students and researchers in atomic collisions, 
       laser physics and chemistry"--|cProvided by publisher. 
546    Text in English. 
588 0  Print version record. 
590    eBooks on EBSCOhost|bEBSCO eBook Subscription Academic 
       Collection - North America 
650  0 Few-body problem.|0https://id.loc.gov/authorities/subjects
       /sh85048000 
650  0 Ion-atom collisions.|0https://id.loc.gov/authorities/
       subjects/sh85067790 
650  0 Nuclear fragmentation.|0https://id.loc.gov/authorities/
       subjects/sh91006193 
650  7 Few-body problem.|2fast|0https://id.worldcat.org/fast/
       923539 
650  7 Ion-atom collisions.|2fast|0https://id.worldcat.org/fast/
       978605 
650  7 Nuclear fragmentation.|2fast|0https://id.worldcat.org/fast
       /1040171 
655  4 Electronic books. 
655  7 Electronic books.|2lcgft 
700 1  Whelan, Colm T.,|0https://id.loc.gov/authorities/names/
       n93067435|eeditor. 
776 08 |iPrint version:|tFragmentation processes.|dCambridge : 
       Cambridge University Press, 2012|z9781107007444|w(DLC)  
       2012035049|w(OCoLC)795763384 
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       db=nlebk&AN=508251|zOnline eBook via EBSCO. Access 
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856 42 |3Instructions for reading/downloading the EBSCO version 
       of this eBook|uhttp://guides.rider.edu/ebooks/ebsco 
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