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Cluster knockout reactions

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Abstract

Cluster knockout reactions are expected to reveal the amount of clustering (such as that of α, d and even of heavier clusters such as12C, 16O etc.) in the target nucleus. In simple terms, incident medium high-energy nuclear projectile interacts strongly with the cluster (present in the target nucleus) as if it were existing as a free entity. Theoretically, the relatively softer interactions of the two outgoing particles with the residual nucleus lead to optical distortions and are treated in terms of distorted wave (DW) formalism. The long-range projectile–cluster interaction is accounted for, in terms of the finite range (FR) direct reaction formalism, as against the more commonly adopted zero-range (ZR) distorted wave impulse approximation (DWIA) formalism. Comparison of the DWIA calculations with the observed data provide information about the momentum distribution and the clustering spectroscopic factor of the target nucleus. Interesting results and some recent advancements in the area of (α, 2 α) reactions and heavy cluster knockout reactions are discussed. Importance of the finite-range vertex and the final-state interactions are brought out.

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Authors and Affiliations

  1. Nuclear Physics Division, Bhabha Atomic Research Centre, Mumbai, 400 085, India

    ARUN K JAIN & B N JOSHI

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  1. ARUN K JAIN
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  2. B N JOSHI
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Correspondence to ARUN K JAIN.

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JAIN, A.K., JOSHI, B.N. Cluster knockout reactions. Pramana - J Phys 82, 697–704 (2014). https://doi.org/10.1007/s12043-014-0721-x

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