<p>The&#xa0;radioactivity&#xa0;of the&#xa0;α particle is among the most compelling evidence for the existence of cluster structures in atomic nuclei. During the decay process, a pre-existing α particle tunnels through the potential barrier formed by the residual nucleus<sup><CitationRef CitationID="CR1">1</CitationRef>,<CitationRef CitationID="CR2">2</CitationRef></sup>. The degree of preformation of the α particle, a strongly bound system of two protons and two neutrons, is extracted from the data by dividing the α-decay probability by the barrier penetrability for a given particle energy. The preformation probability changes rapidly near nuclear shell closures, which is direct evidence that clustering is connected to nuclear structure<sup><CitationRef CitationID="CR3">3</CitationRef></sup>. Enhanced preformation was observed in the lightest α-particle emitters, spherical tellurium and xenon isotopes decaying to magic isotopes of tin. Here we show the most extreme case of α-particle preformation from the measurement of the decay of tellurium-104 (<sup>104</sup>Te). With a half-life of <InlineEquation ID="IEq1"> <EquationSource Format="TEX">\(7.{2}_{-1.5}^{+2.3}\,{\rm{ns}}\)</EquationSource> <EquationSource Format="MATHML"><math> <mn>7.</mn> <msubsup> <mrow> <mn>2</mn> </mrow> <mrow> <mo>−</mo> <mn>1.5</mn> </mrow> <mrow> <mo>+</mo> <mn>2.3</mn> </mrow> </msubsup> <mspace width="0.25em" /> <mrow> <mrow> <mi mathvariant="normal">ns</mi> </mrow> </mrow> </math></EquationSource> </InlineEquation>, <sup>104</sup>Te is the fastest ground-state α-emitting nucleus known so far. The deduced preformation demonstrates that the enhancement is greater for <sup>104</sup>Te than for any other nucleus. One nuclear model that can explain our observation postulates that the α particle can exist only in the low-nuclear-matter-density regions on the surface of the nucleus. The uniquely high preformation for <sup>104</sup>Te is attributed to its relation to doubly magic tin-100 (<sup>100</sup>Sn), creating conditions conducive to form an α particle.</p>

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Direct observation of the superallowed α-decay of 104Te

  • Ian Cox,
  • Robert Grzywacz,
  • T. T. King,
  • K. P. Rykaczewski,
  • S. Nishimura,
  • R. Yokoyama,
  • N. Fukuda,
  • N. Kitamura,
  • S. Go,
  • C. Mazzocchi,
  • J. M. Allmond,
  • A. Augustyn,
  • N. Braukman,
  • P. Brionnet,
  • A. Esmaylzadeh,
  • J. Fischer,
  • G. Garcia de Lorenzo,
  • S. Hanai,
  • D. Hoskins,
  • N. Imai,
  • K. Kolos,
  • A. Korgul,
  • B. Kreider,
  • S. Michimasa,
  • K. Nishio,
  • V. Phong,
  • T. J. Ruland,
  • H. Sakurai,
  • Y. Shimizu,
  • A. Skruch,
  • H. Suzuki,
  • H. Takeda,
  • Y. Togano,
  • Z. Y. Xu,
  • M. Yoshimoto

摘要

The radioactivity of the α particle is among the most compelling evidence for the existence of cluster structures in atomic nuclei. During the decay process, a pre-existing α particle tunnels through the potential barrier formed by the residual nucleus1,2. The degree of preformation of the α particle, a strongly bound system of two protons and two neutrons, is extracted from the data by dividing the α-decay probability by the barrier penetrability for a given particle energy. The preformation probability changes rapidly near nuclear shell closures, which is direct evidence that clustering is connected to nuclear structure3. Enhanced preformation was observed in the lightest α-particle emitters, spherical tellurium and xenon isotopes decaying to magic isotopes of tin. Here we show the most extreme case of α-particle preformation from the measurement of the decay of tellurium-104 (104Te). With a half-life of \(7.{2}_{-1.5}^{+2.3}\,{\rm{ns}}\) 7. 2 1.5 + 2.3 ns , 104Te is the fastest ground-state α-emitting nucleus known so far. The deduced preformation demonstrates that the enhancement is greater for 104Te than for any other nucleus. One nuclear model that can explain our observation postulates that the α particle can exist only in the low-nuclear-matter-density regions on the surface of the nucleus. The uniquely high preformation for 104Te is attributed to its relation to doubly magic tin-100 (100Sn), creating conditions conducive to form an α particle.