Abstract
The theoretical approach to a sequential heavy ion double charge exchange reaction is presented. A brief introduction into the formal theory of second-order nuclear reactions and their application to Double Single Charge Exchange (DSCE) reactions by distorted wave theory is given, thereby completing the theoretical background to our recent work. Formally, the DSCE reaction amplitudes are shown to be separable into superpositions of distortion factors, accounting for initial and final state ion–ion interactions, and nuclear matrix elements. A broad space is given to the construction of nuclear DSCE response functions on the basis of polarization propagator theory. The nuclear response tensors resemble the nuclear matrix elements of 2νββ decay in structure but contain in general a considerable more complex multipole and spin structure. The QRPA theory is used to derive explicit expressions for nuclear matrix elements (NMEs). The differences between the NME of the first and the second interaction vertexes in a DSCE reaction is elucidated. Reduction schemes for the transition form factors are discussed by investigating the closure approximation and the momentum structure of form factors. DSCE unit strength cross sections are derived.
Highlights
The study of higher-order nuclear processes is a very demanding field of research, especially when they are driven by hadronic interactions
The theory is focused on collisional double charge exchange (DCE) reactions mediated by a sequence of two consecutive charge-transforming single charge exchange (SCE) events due to the exchange of isovector mesons
A scheme was introduced for the separation of target and projectile nuclear matrix elements (NMEs), which was achieved by a recoupling from the t-channel to an s-channel formulation, presented here for the first time
Summary
The study of higher-order nuclear processes is a very demanding field of research, especially when they are driven by hadronic interactions. That approach is not suitable for investigations and/or extraction of DBD nuclear matrix elements (NME) from cross sections The latter are connecting the two SCE-type vertices within the same nucleus, while the standard reaction theoretical approach is directed towards the description of the pair of vertices excited in the projectile and target in the first or the second steps of the DCE reaction. A change from the conventional t-channel formulation to an appropriate s-channel formulation is required, not to the least as a necessary prerequisite for establishing the connection to the NME entering DBD theory Keeping this goal in mind, the program of this paper is a purely theoretical one, namely to recast the second-order DSCE reaction amplitude into an s-channel representation. Certain coefficients resulting from the recoupling of angular momenta are found in Appendix A
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