Nuclear multifragmentation, percolation, and the fisher droplet model: common features of reducibility and thermal scaling

Elliott JB; Moretto LG; Phair L; Wozniak GJ; Albergo S; Bieser F; Brady FP; Caccia Z; Cebra DA; Chacon AD; Chance JL; Choi Y; Costa S; Gilkes ML; Hauger JA; Hirsch AS; Hjort EL; Insolia A; Justice M; Keane D; Kintner JC; Lindenstruth V; Lisa MA; Matis HS; McMahan M; McParland C

Elliott JB; Moretto LG; Phair L; Wozniak GJ; Albergo S; Bieser F; Brady FP; Caccia Z; Cebra DA; Chacon AD; Chance JL; Choi Y; Costa S; Gilkes ML; Hauger JA; Hirsch AS; Hjort EL; Insolia A; Justice M; Keane D; Kintner JC; Lindenstruth V; Lisa MA; Matis HS; McMahan M; McParland C.

Affiliation

Elliott JB; Nuclear Science Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA.

Phys Rev Lett ; 85(6): 1194-7, 2000 Aug 07.

Article in En | MEDLINE | ID: mdl-10991510

ABSTRACT

ABSTRACT

It is shown that the Fisher droplet model, percolation, and nuclear multifragmentation share the common features of reducibility (stochasticity in multiplicity distributions) and thermal scaling (one-fragment production probabilities are Boltzmann factors). Barriers obtained, for cluster production on percolation lattices, from the Boltzmann factors show a power-law dependence on cluster size with an exponent of 0.42+/-0.02. The EOS Collaboration Au multifragmentation data yield barriers with a power-law exponent of 0.68+/-0.03. Values of the surface energy coefficient of a low density nuclear system are also extracted.

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Database: MEDLINE Type of study: Prognostic_studies Language: En Year: 2000 Type: Article

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Database: MEDLINE Type of study: Prognostic_studies Language: En Year: 2000 Type: Article