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Carbon: Nitrogen: Oxygen: Fluorine: Neon: ... Samarium-149 is an ... Its neutron cross section is 41000 barns for thermal neutrons. [73] Because samarium-149 is not ...
The stable fission product 149 Sm is also a neutron poison. Samarium is theoretically the lightest element with even atomic number with no stable isotopes (all isotopes of it can theoretically go either alpha decay or beta decay or double beta decay), other such elements are those with atomic numbers > 66 (dysprosium, which is the heaviest ...
Carbon: Nitrogen: Oxygen: Fluorine: Neon: Sodium: Magnesium: ... 149 Sm 13.8% stable 150 ... ionization energy 3 comment = | number of ionization energies ...
149 Sm 13.8% stable 150 Sm 7.37% ... The number willbe rounded to 3 sigfig. ... Two neutrons ejected from nucleus simultaneously.
Examples include carbon-14, nitrogen-15, and oxygen-16 in the table above. Isobars are nuclides with the same number of nucleons (i.e. mass number) but different numbers of protons and neutrons. Isobars neighbor each other diagonally from lower-left to upper-right. Examples include carbon-14, nitrogen-14, and oxygen-14 in the table above.
There are 6 stable nuclides and one radioactive primordial nuclide with neutron number 82 (82 is the neutron number with the most stable nuclides, since it is a magic number): barium-138, lanthanum-139, cerium-140, praseodymium-141, neodymium-142, and samarium-144, as well as the radioactive primordial nuclide xenon-136, which decays by a very ...
Samarium-149 is the second most important neutron poison in nuclear reactor physics. Samarium-151, produced at lower yields, is the third most abundant medium-lived fission product but emits only weak beta radiation. Both have high neutron absorption cross sections, so that much of them produced in a reactor are later destroyed there by neutron ...
The number of protons (Z column) and number of neutrons (N column). energy column The column labeled "energy" denotes the energy equivalent of the mass of a neutron minus the mass per nucleon of this nuclide (so all nuclides get a positive value) in MeV, formally: m n − m nuclide / A, where A = Z + N is the mass number. Note that this means ...