The AME 2020 atomic mass evaluation (II). Tables, graphs and references
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Meng Wang1,2, , W.J. Huang1,3,4,5, , Kondev F.G.6, , Audi G.5, , S. Naimi7, , 1.Institute of Modern Physics, Chinese Academy of Sciences, Lanzhou 730000, China 2.University of Chinese Academy of Sciences, Beijing 100084, China 3.Advanced Energy Science and Technology Guangdong Laboratory, Huizhou 516003, China 4.Max-Planck-Institut für Kernphysik, Saupfercheckweg 1, 69117 Heidelberg, Germany 5.Université Paris-Saclay, CNRS/IN2P3, IJCLab, 91405 Orsay, France 6.Physics Division, Argonne National Laboratory, Lemont, IL 60439, USA 7.RIKEN Nishina Center, Wako, Saitama 351-0198, Japan Received Date:2021-01-19 Available Online:2021-03-15 Abstract:This is the second part of the new evaluation of atomic masses, AME2020. Using least-squares adjustments to all evaluated and accepted experimental data, described in Part I, we derived tables with numerical values and graphs which supersede those given in AME2016. The first table presents the recommended atomic mass values and their uncertainties. It is followed by a table of the influences of data on primary nuclides, a table of various reaction and decay energies, and finally, a series of graphs of separation and decay energies. The last section of this paper provides all input data references that were used in the AME2020 and the NUBASE2020 evaluations.
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2.Atomic mass tableTable I presents the atomic masses expressed as mass excess in keV, together with the binding energy per nucleon, the beta-decay energy and the total atomic mass in the unified atomic mass unit, similar to those published in the earlier AME editions [3-9]. Traditionally, the masses of nuclides are measured for electrically neutral atoms or single-charged ions. At present, the highest precision masses are measured using Penning traps for a single-charged ion. This is the main reason why atomic masses, rather than nuclear masses, are presented in the Ame. In general, the nuclear masses $ M_N $ can be calculated from the atomic ones $ M_A $ as:
where $ B_{e} $(Z) is the electron binding energy. The ionization energy is generally (much) smaller than the uncertainty of the mass and, for a small number of very precise mass measurements, corrections for the first- and second-ionization potentials can be applied without much loss of accuracy. The same is true for the electron mass, $ m_e $; see Table A in Part I [1]. Nowadays, several mass measurements are conducted with fully or almost fully ionized atoms. In such cases, a correction must be made for the total binding energy of all the removed electrons $ B_e(Z) $. Unfortunately, the precision of the calculated $ B_e (Z) $ values is not well established, since this quantity (approximately 760 keV for $ _{92}{\rm{U}} $) cannot be easily measured. However, we can state with a high confidence that the precision for $ _{92} {\rm{U}}$ is better compared to that for the best known masses of the uranium isotopes, which is about 1.1 keV. An approximate formula for $ B_{e} $ can be found in the review of Lunney, Pearson and Thibault [10]:
The atomic masses are given in mass units and the derived quantities in energy units. For the atomic mass unit we use the “unified atomic mass unit”, symbol “u”, defined as 1/12 of the atomic mass of one $ ^{12} {\rm{C}}$ atom in its electronic and nuclear ground states and in its rest coordinate system. The energy values are expressed as electron-volt, using the international volt V (see discussion in Part I, Section 2). Due to the dramatic increase in the mass accuracy for some light nuclides, the printing format of the mass table is not adequate for the most precisely known masses, which require additional digits. Table A gives mass excess and atomic mass values for 16 nuclides, whose masses are known with the highest precision, with an uncertainty below 1 eV.
4.Nuclear reaction and decay energiesThe linear combinations involving neighboring nuclides with small differences in atomic number and mass number, and particles such as n, p, d, t, $ ^3 {\rm{He}}$ and $ \alpha $, are important for studies of the trends in the nuclear energy surface and for Q-values of frequently used reactions and decays. In Table III, values for 12 such combinations and their uncertainties are presented. With the help of the instructions given in the explanation of Table III, values for 28 additional reactions and their uncertainties can be derived. The derived values will be correct, but in a few cases (when reactions involving light nuclei measured with very high precision) the uncertainties will be slightly larger than those obtained when correlations are taken into account. In cases where any combination of the most precise mass values are involved, the uncertainties can be obtained with the help of the correlation coefficients given in Table B, where the variances and covariances for the most precisely known light nuclei are listed. As an example, if one considers the mass difference between $ ^3 {\rm{H}}$ and $ ^3 {\rm{He}}$, it can be easily obtained from the values listed in Table A. However, the corresponding uncertainty cannot be simply determined from the square root of the quadratic sum of the individual uncertainties, which would be:
$ \sqrt{0.081^2+0.060^2} = 0.10\; {\rm{nu}}. $
(3)
Since there is a strong correlation between these two nuclides, the uncertainty of the mass difference should be calculated using the correlation information provided in Table B. Thus, its uncertainty can be obtained from the square root of the sum of the variances minus twice the covariance:
As a result, the final uncertainty is smaller when the correlations are taken into account. For all other cases, the correlation coefficients are made available at the AMDC websites [11].