Xiaodong Li, Qijun Liu, Gongyi Li, Yihe Li and Zengyong Chu
National University of Defense Technology, China
Scientific Tracks Abstracts: J Astrophys Aerospace Technol
For an element, some isotopes are stable and some are not. Quantum theory rationizes â??magic numberâ? and explains some of the reasons. For a comprhensive and visual understanding, one may need a model to directly explain the comlexity. Based on the newly proposed nuclear structure model of â??folding ring plus extra nucleonâ?, one can derive the following conclusions: 1) For nuclei, if the number of proton (P) is larger than that of neutron (N), they must be unstable (except 3He, which is not a ring). 2) If extra N besides ZP+ZN ring can attach to at least 2 ring Pâ??s with suitable geometrical arrangement based on the model, the nuclide will be stable. The extra N bridges 2 ring Pâ??s to stabilize some less stable rings (like 9Be). 3) Any ring with a free P2N2 fragment will release an ?±-particle along with another smaller ring (like 8Be, which splits into two 4Heâ??s). 4) Odd Z elements are generally less stable than those of even Z, because the odd Z ring must be eccentric (the gravity centers of the P and N can not be superposed), which accompanied with lower binding energy per nucleon (EB/A). 5) For odd Z ring, odd number of extra N may reduce the eccentricity, leading to higher EB/A, while for even Z rings, odd number of extra N arouses eccentricity, leading to lower EB/A. This situation is demonstrated in unexceptional zigzag EB/A variation of all the isotopes of any reported element, where in odd Z elements, vertex at odd A; while in even Z elements, vertex at even A. 6) For large Z elements, which is based on a large ring, more extra N are necessary to fill the larger void space of the ring even though it is folding. This is another function of extra N, The N/P ratio of the stable zone increases with higher Z, the maximum N/P ratio should be 1.5 (every two ring Pâ??s hold one extra N). Arguably, some heavy stable nuclides, such as 208Pb, may be eventually found to be unstable with extra long life time. The stablity island with both large magic number seems to be impossible because it needs very high N/P ratio to fill the very large void space.
Xiaodong Li has completed his PhD from Université de Montréal (1993), MS from Nankai University (1981), BS from Tianjin University (1977). He is a Professor in NUDT reseaching and teaching in the fields of polymer chemistry, material chemistry and physics, crystal and structure chemistry and physics.
Astrophysics & Aerospace Technology received 114 citations as per Google Scholar report