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182  1$6z01$an
200 1 $aGeografia della Comunità europea$fJohn Cole, Francis Cole
210   $aMilano$cF. Angeli$d1995
215   $a238 p.$d23 cm
225 | $aGeografia e società$v57
300   $aTrad. di Romano Gasperoni.
410  0$1001CFI0000130$12001 $aGeografia e società$v57
500 10$a˜ The œgeography of the European community$3RML0052173$9CFIV022228$92779485
606   $aPaesi della comunità europea$xGeografia economica$2FIR$3RMLC385182$9I
676   $a330.940$9$v21
700  1$aCole$b, John P.$f <1928-2020>$3CFIV022228$4070$01204443
701  1$aCole$b, Francis$3TO0V150267$4070$0133064
790  1$aCole$b, J. P.$3IEIV232120$zCole, John P. <1928-2020>
790  1$aCole$b, John Peter$3MILV155403$zCole, John P. <1928-2020>
790  1$aCole$b, John$3MILV155404$zCole, John P. <1928-2020>
801  3$aIT$bIT-01$c20160623
850   $aIT-FR0017          
899   $aBiblioteca umanistica Giorgio Aprea$bFR0017          
912   $aRML0052172
950  0$aBiblioteca umanistica Giorgio Aprea$d 52CIS       9/793$e 52VM 0000646055  VM                        barcode:00041027. - Inventario:17080 FLSVM$fA $h20061116$i20121204
977   $a 52
996   $aGeography of the European community$92779485
997   $aUNICAS

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101 0 $aeng
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181   $ctxt$2rdacontent
182   $cc$2rdamedia
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200 10$aThree-particle physics and dispersion relation theory /$fA.V. Anisovich, V.V. Anisovich, M.A. Matveev, V.A. Nikonov, Petersburg Nuclear Physics Institute, Russian Academy of Science, Russia, J. Nyiri, Institute for Particle and Nuclear Physics, Wigner RCP, Hungarian Academy of Sciences, Hungary, A.V. Sarantsev, Petersburg Nuclear Physics Institute, Russian Academy of Science, Russia
210   $a[Hackensack] New Jersey $cWorld Scientific$dc2013
210  1$aNew Jersey :$cWorld Scientific,$d[2013]
210  4$dc2013
215   $a1 online resource (xvi, 325 pages) $cillustrations
225 0 $aGale eBooks.
300   $aDescription based upon print version of record.
311   $a981-4478-80-6 
320   $aIncludes bibliographical references.
327   $aPreface; References; Contents; 8.4.5 Overlapping of baryon resonances; 1. Introduction; 1.1 Non-relativistic three-nucleon and three-quark systems; 1.1.1 Description of three-nucleon systems; 1.1.2 Three-quark systems; 1.2 Dispersion relation technique for three particle systems; 1.2.1 Elements of the dispersion relation technique for two-particle systems; 1.2.2 Interconnection of three particle decay amplitudes and two-particle scattering ones in hadron physics; 1.2.3 Quark-gluon language for processes in regions I, III and IV; 1.2.4 Spectral integral equation for three particles
327   $a1.2.5 Isobar models1.2.5.1 Amplitude poles; 1.2.5.2 D-matrix propagator for an unstable particle and the K matrix amplitude; 1.2.5.3 K-matrix and D-matrix masses and the amplitude pole; 1.2.5.4 Accumulation of widths of overlapping resonances; 1.2.5.5 Loop diagrams with resonances in the intermediate states; 1.2.5.6 Isobar model for high energy peripheral production processes; 1.2.6 Quark-diquark model for baryons and group theory approach; 1.2.6.1 Quark-diquark model for baryons; References; 2. Elements of Dispersion Relation Technique for Two-Body Scattering Reactions
327   $a2.2.2 Scattering amplitude and energy non-conservation in the spectral integral representation2.2.3 Composite system wave function and its form factors; 2.2.4 Scattering amplitude with multivertex representation of separable interaction; 2.2.4.1 Generalization for an arbitrary angular momentum state, L = J; 2.3 Instantaneous interaction and spectral integral equation for two-body systems; 2.3.1 Instantaneous interaction; 2.3.1.1 Coordinate representation; 2.3.1.2 Instantaneous interaction - transformation into a set of separable vertices
330   $aThe necessity of describing three-nucleon and three-quark systems have led to a constant interest in the problem of three particles. The question of including relativistic effects appeared together with the consideration of the decay amplitude in the framework of the dispersion technique. The relativistic dispersion description of amplitudes always takes into account processes connected with the investigated reaction by the unitarity condition or by virtual transitions; in the case of three-particle processes they are, as a rule, those where other many-particle states and resonances are produc
606   $aParticles (Nuclear physics)
606   $aDispersion relations
615  0$aParticles (Nuclear physics)
615  0$aDispersion relations.
676   $a539.725
700   $aAnisovich$b A. V.$01506880
702   $aAnisovich$b V. V$g(Vladimir Vladislavovich),
702   $aMatveev$b M. A.
702   $aNikonov$b V. A.
702   $aNyiri$b J$g(Julia),$f1939-
702   $aSarantsev$b A. V.
801  0$bMiFhGG
801  1$bMiFhGG
906   $aBOOK
912   $a9910779565403321
996   $aThree-particle physics and dispersion relation theory$93737291
997   $aUNINA