Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000
The search for examples of proton radioactivity has resulted in the discovery of a large number of proton emitters in the region 50 < Z < 84 [1]. Many of these proton emitters and their daughters are also a-emitters, and in some cases the a-decay chain from the daughter terminates on a nuclide closer to stability whose mass excess is known. This opens up the possibility of using a-and proton-decay Q-values to determine the mass excesses of a large group of nuclei connected by particle decay. The Q-values are derived from the measured kinetic energies of the emitted protons or a-particles. Where the decay chains are not connected to nuclei with known mass excesses, proton separation energies can be measured in some cases and derived in others. For the a-decay of the parent nucleus (Z, A) to the daughter (Z - 2, A - 4), the energy and momentum relations used to convert between Q-value, mass (M) and mass excess (ME) are: M(4He)E", (1) M(Z - 2, A - 4)Erecoil, (2) Q", E", + Erecoi\, ME(Z, A) Q", + ME(Z - 2, A - 4) + ME(4He). (3) In practice, one uses M(4He) ~ 4 and M(Z - 2, A - 4) (A - 4), so that Equation (3) becomes ME(Z, A) = E", (_A_) + ME(Z - 2, A - 4) + ME(4He). (4) A -4 Similarly, for protons, we have ME(Z, A) = Ep(_A_) +ME(Z - 1, A-I) +ME(lH).
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Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000
The search for examples of proton radioactivity has resulted in the discovery of a large number of proton emitters in the region 50 < Z < 84 [1]. Many of these proton emitters and their daughters are also a-emitters, and in some cases the a-decay chain from the daughter terminates on a nuclide closer to stability whose mass excess is known. This opens up the possibility of using a-and proton-decay Q-values to determine the mass excesses of a large group of nuclei connected by particle decay. The Q-values are derived from the measured kinetic energies of the emitted protons or a-particles. Where the decay chains are not connected to nuclei with known mass excesses, proton separation energies can be measured in some cases and derived in others. For the a-decay of the parent nucleus (Z, A) to the daughter (Z - 2, A - 4), the energy and momentum relations used to convert between Q-value, mass (M) and mass excess (ME) are: M(4He)E", (1) M(Z - 2, A - 4)Erecoil, (2) Q", E", + Erecoi\, ME(Z, A) Q", + ME(Z - 2, A - 4) + ME(4He). (3) In practice, one uses M(4He) ~ 4 and M(Z - 2, A - 4) (A - 4), so that Equation (3) becomes ME(Z, A) = E", (_A_) + ME(Z - 2, A - 4) + ME(4He). (4) A -4 Similarly, for protons, we have ME(Z, A) = Ep(_A_) +ME(Z - 1, A-I) +ME(lH).
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Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000

Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000

Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000

Atomic Physics at Accelerators: Mass Spectrometry: Proceedings of the APAC 2000, held in Cargèse, France, 19-23 September 2000

Overview

The search for examples of proton radioactivity has resulted in the discovery of a large number of proton emitters in the region 50 < Z < 84 [1]. Many of these proton emitters and their daughters are also a-emitters, and in some cases the a-decay chain from the daughter terminates on a nuclide closer to stability whose mass excess is known. This opens up the possibility of using a-and proton-decay Q-values to determine the mass excesses of a large group of nuclei connected by particle decay. The Q-values are derived from the measured kinetic energies of the emitted protons or a-particles. Where the decay chains are not connected to nuclei with known mass excesses, proton separation energies can be measured in some cases and derived in others. For the a-decay of the parent nucleus (Z, A) to the daughter (Z - 2, A - 4), the energy and momentum relations used to convert between Q-value, mass (M) and mass excess (ME) are: M(4He)E", (1) M(Z - 2, A - 4)Erecoil, (2) Q", E", + Erecoi\, ME(Z, A) Q", + ME(Z - 2, A - 4) + ME(4He). (3) In practice, one uses M(4He) ~ 4 and M(Z - 2, A - 4) (A - 4), so that Equation (3) becomes ME(Z, A) = E", (_A_) + ME(Z - 2, A - 4) + ME(4He). (4) A -4 Similarly, for protons, we have ME(Z, A) = Ep(_A_) +ME(Z - 1, A-I) +ME(lH).

Product Details

ISBN-13: 9781402000140
Publisher: Springer Netherlands
Publication date: 11/30/2001
Edition description: Reprinted from HYPERFINE INTERACTIONS, 132:1-4, 2001
Pages: 556
Product dimensions: 6.10(w) x 9.25(h) x 0.05(d)

Table of Contents

Foreword - organizing APAC2000; D. Lunney. Tutorial on Aspects of Atomic Masses (in honor of the 78th birthday of Aaldert Wapstra). The evaluation of atomic masses; G. Audi. Experimental overview of mass measurements; A. Lépine-Szily. The quest for a microscopic nuclear mass formula; J.M. Pearson. Effects of QED and beyond from the atomic binding energy; G. Soff, et al. Nuclear masses and the r- and p-processes of nucleosynthesis; S. Goriely. Standard-model tests with superallowed beta decay: an important application of very precise mass measurements; J.C. Hardy, I.S. Towner. Memories of mass determinations; A.H. Wapstra. Mass Measurements and Nuclear Structure. Masses and proton separation energies obtained from Qalpha and Qrho measurements; C.N. Davids, et al. Anomalies in the alphadecay energies and half lives of neutron-deficient Po isotopes; M. Huyse, et al. Shape coexistence and the N=28 shell closure far from stability; F. Sarazin, et al. Decay experiments on N ' Z nuclei: the role of masses Q values and separation energies; E. Roeckl. Mass Measurements for Metrology. Ultra-precise mass measurements using the UW-PTMS; R.S. Van Dyck Jr., et al. Precise measurements on the masses of Cs, Rb and Na: a new route to the fine structure constant; S. Rainville, et al. Prompt (n.gamma) mass measurements for the AVOGADRO project; A. Paul, et al. Precision measurement of the charged pion mass by high resolution x-ray spectroscopy; G.L. Borchert, et al. A possible new value for the electron mass from g-factor measurements on hydrogen-like ions; G. Werth, et al. On-Line IonTrap Mass Measurement Programs. ISOLTRAP mass measurements – an overview; G. Bollen. The Canadian Penning Trap spectrometer at Argonne; G. Savard, et al. New massmeasurements using highly charged ions at SMILETRAP; T. Fritioff, et al. On-Line Mass Programs. The SPEG mass measurement program at GANIL; H. Savajols. Mass measurements at the Wright nuclear structure laboratory; D.S. Brenner. Mass measurements in nuclear reactions; Y.E. Penionzhkevich. On-Line Mass Programs Using Circulating Ions. Mass measurements at GANIL using the CSS2 and CIME cyclotrons; M. Chartier, et al. Schottky Mass Measurements of cooled exotic nuclei; Yu.A. Litvinov, et al. Isochronous mass measurements of hot exotic nuclei; M. Hausmann, et al. Recent results on Ne and Mg from the MISTRAL mass program at ISOLDE; D. Lunney, et al. Recent Mass Measurements for Nuclea Physics. Towards shorter-lived nuclides in ISOLTRAP mass measurements; F. Herfurth, et al. Mass Measurement of Exotic Nuclei Around N = Z = 40 With CSS2; A.-S. Lalleman, et al. Determination of Atomic Masses and Nuclear Binding Energies via Neutron Induced Reactions; C. Wagemans, et al. Mass Measurements of 114-124,130Xe With the Isoltrap Penning Trap Spectrometer; J. Dilling, et al. Accurate mass determination of neutron-deficient nuclides close to Z=82 with ISOLTRAP; S. Schwarz, et al. Atomic Theory. QED effects in heavy few-electron ions; V.M. Shabaev, et al. Relativistic calculations for trapped ions; P. Indelicato, et al. Parity nonconserving radiative corrections in the highly-charged ions; I. Bednyakov, et al. Vacuum polarization scr
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