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LEADER 00000cam a2200637Ma 4500 
001    ocn294759399 
003    OCoLC 
005    20160527041015.7 
006    m     o  d         
007    cr zn||||||||| 
008    080625s2008    enka    ob    001 0 eng d 
019    262555488|a646769001|a696629437 
020    1860949258|q(electronic book) 
020    9781860949258|q(electronic book) 
020    |z186094924X|q(Cloth) 
020    |z9781860949241 
035    (OCoLC)294759399|z(OCoLC)262555488|z(OCoLC)646769001
       |z(OCoLC)696629437 
040    CDX|beng|epn|cCDX|dOCLCQ|dN$T|dIDEBK|dE7B|dOCLCQ|dOCLCF
       |dOCLCQ|dM6U|dOCLCQ|dYDXCP|dSTF|dOCLCQ 
049    RIDW 
050  4 QC467|b.F766 2008eb 
072  7 SCI|x053000|2bisacsh 
082 04 535.84 22|222 
090    QC467|b.F766 2008eb 
100 1  Fröman, Nanny.|0https://id.loc.gov/authorities/names/
       n83828021 
245 10 Stark effect in a hydrogenic atom or ion :|btreated by the
       phase-integral method /|cNanny Fröman, Per Olof Fröman ; 
       with adjoined papers by A. Hökback and P.O. Fröman. 
264  1 London, UK :|bImperial College Press,|c[2008] 
264  4 |c©2008 
300    1 online resource (viii, 153 pages) :|billustrations 
336    text|btxt|2rdacontent 
337    computer|bc|2rdamedia 
338    online resource|bcr|2rdacarrier 
347    text file|2rdaft 
504    Includes bibliographical references and indexes. 
505 0  1. Introduction -- 2. Schrödinger equation, its seperation
       and its exact eigenfunctions. 2.1. Separation of the time-
       independent Schrd̈inger equation for the internal motion. 
       2.2. Properties of the eigenfunctions of the time-
       independent Schrödinger equation for the internal motion -
       - 3. Development in time of the probability amplitude for 
       a decaying state -- 4. Phase-integral method. 4.1. Phase-
       integral approximation generated from an unspecified base 
       function. 4.2. Connection formulas associated with a 
       single transition point -- 5. Derivation of phase-integral
       formulas for profiles, energies and half-widths of Stark 
       levels. 5.1. Positions of the Stark levels. 5.2. Formulas 
       for the calculation of dL/dE, dK[symbol]/dE and dK/dE. 
       5.3. Half-widths of the Stark intervals -- 6. Procedure 
       for transformation of the phase-integral formulas into 
       formulas involving complete elliptic integrals -- Adjoined
       papers by Anders Hökback and Per Olof Fröman -- 7. Phase-
       inegral quantities and their partial derivatives with 
       respect to [symbol] and [symbol] expressed in terms of 
       complete elliptic integrals. 7.1. The [symbol]-equation. 
       7.2. The [symbol]-equation in the sub-barrier case. 7.3. 
       The [symbol]-equation in the super-barrier case -- 8. 
       Numerical results. 
520    This book treats the Stark effect of a hydrogenic atom or 
       ion in a homogeneous electric field. It begins with a 
       thorough review of previous work in this field since 1926.
       After the Schrödinger equation has been separated with 
       respect to time dependence, centre of mass motion and 
       internal motion, followed by a discussion of its 
       eigenfunctions, the exact development in time of the 
       probability amplitude for a decaying state is obtained by 
       means of a formula analogous to the Fock-Krylov theorem. 
       From this formula one obtains by means of the phase-
       integral approximation generated from a particular base 
       function non-relativistic formulas for profiles, energies 
       and half-widths of the Stark levels. These formulas are 
       then transformed into formulas expressed in terms of 
       complete elliptic integrals. The formulas thus obtained 
       are used for the calculation of energies and half-widths 
       of 198 different Stark states, which are compared with the
       corresponding results obtained by other authors with the 
       use of other methods. An analysis of this material 
       indicates that the energy values obtained by the phase-
       integral method are at least as accurate as those obtained
       by other methods in more than half of the 198 cases. The 
       book presents one of the most comprehensive asymptotic 
       treatments of the Stark effect in atomic hydrogen that 
       have been published. 
588 0  Print version record. 
590    eBooks on EBSCOhost|bEBSCO eBook Subscription Academic 
       Collection - North America 
650  0 Stark effect.|0https://id.loc.gov/authorities/subjects/
       sh85127404 
650  0 Optical spectroscopy.|0https://id.loc.gov/authorities/
       subjects/sh2006002572 
650  0 Quantum theory.|0https://id.loc.gov/authorities/subjects/
       sh85109469 
650  0 Schrödinger equation.|0https://id.loc.gov/authorities/
       subjects/sh85118495 
650  7 Stark effect.|2fast|0https://id.worldcat.org/fast/1131630 
650  7 Optical spectroscopy.|2fast|0https://id.worldcat.org/fast/
       1739874 
650  7 Quantum theory.|2fast|0https://id.worldcat.org/fast/
       1085128 
650  7 Schrödinger equation.|2fast|0https://id.worldcat.org/fast/
       1108121 
655  4 Electronic books. 
700 1  Fröman, Per Olof.|0https://id.loc.gov/authorities/names/
       n83828022 
700 1  Hökback, A. 
776 08 |iPrint version:|aFröman, Nanny.|tStark effect in a 
       hydrogenic atom or ion.|dLondon, UK : Imperial College 
       Press, ©2008|w(DLC)  2008299745 
856 40 |uhttps://rider.idm.oclc.org/login?url=http://
       search.ebscohost.com/login.aspx?direct=true&scope=site&
       db=nlebk&AN=236108|zOnline eBook. Access restricted to 
       current Rider University students, faculty, and staff. 
856 42 |3Instructions for reading/downloading this eBook|uhttp://
       guides.rider.edu/ebooks/ebsco 
901    MARCIVE 20231220 
948    |d201606016|cEBSCO|tebscoebooksacademic|lridw 
994    92|bRID