Observation of the competitive double-gamma nuclear decay

The exotic double-gamma nuclear decay has been observed in cases where the usual single-gamma decay is forbidden, but now a double-gamma decay of excited 137 Ba is reported that is in competition with a single-gamma decay. Competitive double-gamma decay Most decays of quantum states involve the emis...

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Veröffentlicht in:	Nature (London) 2015-10, Vol.526 (7573), p.406-409
Hauptverfasser:	Walz, C., Scheit, H., Pietralla, N., Aumann, T., Lefol, R., Ponomarev, V. Yu
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Schlagworte:	639/766/387/1126 639/766/387/1129 Atoms & subatomic particles Decay Gamma rays Humanities and Social Sciences letter multidisciplinary Nuclear physics Properties Quantum electrodynamics Science
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description	The exotic double-gamma nuclear decay has been observed in cases where the usual single-gamma decay is forbidden, but now a double-gamma decay of excited 137 Ba is reported that is in competition with a single-gamma decay. Competitive double-gamma decay Most decays of quantum states involve the emission of one photon, but in processes first predicted by Nobel laureate Maria Goeppert-Mayer more than 75 years ago, exotic decays emitting two photons can occur. An analogous exotic decay process in atomic nuclei is the double-gamma decay, which has been observed in cases where the usual single-gamma decay is forbidden. In an experimental tour de force, Heiko Scheit and colleagues observe a double-gamma decay which is in competition with a single-gamma decay. Through decay of caesium-137, the first excited state of barium-137 is populated. Monitoring the emissions for more than 50 days and carefully excluding alternative explanations for their data, the authors are able to unambiguously measure the competitive double-gamma decay. Precise measurements of the double-gamma decay rate promise to give access to nuclear structure information that is elusive by other methods. The double-gamma ( γγ )-decay of a quantum system in an excited state is a fundamental second-order process of quantum electrodynamics. In contrast to the well-known single-gamma ( γ )-decay, the γγ -decay is characterized by the simultaneous emission of two γ quanta, each with a continuous energy spectrum. In nuclear physics, this exotic decay mode has only been observed for transitions between states with spin-parity quantum numbers J π = 0 + (refs 1 , 2 , 3 ). Single-gamma decays—the main experimental obstacle to observing the γγ -decay—are strictly forbidden for these 0 + → 0 + transitions. Here we report the observation of the γγ -decay of an excited nuclear state ( J π = 11/2 − ) that is directly competing with an allowed γ -decay (to ground state J π = 3/2 + ). The branching ratio of the competitive γγ -decay of the 11/2 − isomer of 137 Ba to the ground state relative to its single γ -decay was determined to be (2.05 ± 0.37) × 10 −6 . From the measured angular correlation and the shape of the energy spectra of the individual γ-rays, the contributing combinations of multipolarities of the γ radiation were determined. Transition matrix elements calculated using the quasiparticle–phonon model reproduce our measurements well. The γγ -decay rate gives access to so far unexplored important nuclea
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Yu</creator><creatorcontrib>Walz, C. ; Scheit, H. ; Pietralla, N. ; Aumann, T. ; Lefol, R. ; Ponomarev, V. Yu</creatorcontrib><description>The exotic double-gamma nuclear decay has been observed in cases where the usual single-gamma decay is forbidden, but now a double-gamma decay of excited 137 Ba is reported that is in competition with a single-gamma decay. Competitive double-gamma decay Most decays of quantum states involve the emission of one photon, but in processes first predicted by Nobel laureate Maria Goeppert-Mayer more than 75 years ago, exotic decays emitting two photons can occur. An analogous exotic decay process in atomic nuclei is the double-gamma decay, which has been observed in cases where the usual single-gamma decay is forbidden. In an experimental tour de force, Heiko Scheit and colleagues observe a double-gamma decay which is in competition with a single-gamma decay. Through decay of caesium-137, the first excited state of barium-137 is populated. Monitoring the emissions for more than 50 days and carefully excluding alternative explanations for their data, the authors are able to unambiguously measure the competitive double-gamma decay. Precise measurements of the double-gamma decay rate promise to give access to nuclear structure information that is elusive by other methods. The double-gamma ( γγ )-decay of a quantum system in an excited state is a fundamental second-order process of quantum electrodynamics. In contrast to the well-known single-gamma ( γ )-decay, the γγ -decay is characterized by the simultaneous emission of two γ quanta, each with a continuous energy spectrum. In nuclear physics, this exotic decay mode has only been observed for transitions between states with spin-parity quantum numbers J π = 0 + (refs 1 , 2 , 3 ). Single-gamma decays—the main experimental obstacle to observing the γγ -decay—are strictly forbidden for these 0 + → 0 + transitions. Here we report the observation of the γγ -decay of an excited nuclear state ( J π = 11/2 − ) that is directly competing with an allowed γ -decay (to ground state J π = 3/2 + ). The branching ratio of the competitive γγ -decay of the 11/2 − isomer of 137 Ba to the ground state relative to its single γ -decay was determined to be (2.05 ± 0.37) × 10 −6 . From the measured angular correlation and the shape of the energy spectra of the individual γ-rays, the contributing combinations of multipolarities of the γ radiation were determined. Transition matrix elements calculated using the quasiparticle–phonon model reproduce our measurements well. 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Yu</creatorcontrib><title>Observation of the competitive double-gamma nuclear decay</title><title>Nature (London)</title><addtitle>Nature</addtitle><addtitle>Nature</addtitle><description>The exotic double-gamma nuclear decay has been observed in cases where the usual single-gamma decay is forbidden, but now a double-gamma decay of excited 137 Ba is reported that is in competition with a single-gamma decay. Competitive double-gamma decay Most decays of quantum states involve the emission of one photon, but in processes first predicted by Nobel laureate Maria Goeppert-Mayer more than 75 years ago, exotic decays emitting two photons can occur. An analogous exotic decay process in atomic nuclei is the double-gamma decay, which has been observed in cases where the usual single-gamma decay is forbidden. In an experimental tour de force, Heiko Scheit and colleagues observe a double-gamma decay which is in competition with a single-gamma decay. Through decay of caesium-137, the first excited state of barium-137 is populated. Monitoring the emissions for more than 50 days and carefully excluding alternative explanations for their data, the authors are able to unambiguously measure the competitive double-gamma decay. Precise measurements of the double-gamma decay rate promise to give access to nuclear structure information that is elusive by other methods. The double-gamma ( γγ )-decay of a quantum system in an excited state is a fundamental second-order process of quantum electrodynamics. In contrast to the well-known single-gamma ( γ )-decay, the γγ -decay is characterized by the simultaneous emission of two γ quanta, each with a continuous energy spectrum. In nuclear physics, this exotic decay mode has only been observed for transitions between states with spin-parity quantum numbers J π = 0 + (refs 1 , 2 , 3 ). Single-gamma decays—the main experimental obstacle to observing the γγ -decay—are strictly forbidden for these 0 + → 0 + transitions. Here we report the observation of the γγ -decay of an excited nuclear state ( J π = 11/2 − ) that is directly competing with an allowed γ -decay (to ground state J π = 3/2 + ). The branching ratio of the competitive γγ -decay of the 11/2 − isomer of 137 Ba to the ground state relative to its single γ -decay was determined to be (2.05 ± 0.37) × 10 −6 . From the measured angular correlation and the shape of the energy spectra of the individual γ-rays, the contributing combinations of multipolarities of the γ radiation were determined. Transition matrix elements calculated using the quasiparticle–phonon model reproduce our measurements well. 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Yu</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Observation of the competitive double-gamma nuclear decay</atitle><jtitle>Nature (London)</jtitle><stitle>Nature</stitle><addtitle>Nature</addtitle><date>2015-10-15</date><risdate>2015</risdate><volume>526</volume><issue>7573</issue><spage>406</spage><epage>409</epage><pages>406-409</pages><issn>0028-0836</issn><eissn>1476-4687</eissn><coden>NATUAS</coden><abstract>The exotic double-gamma nuclear decay has been observed in cases where the usual single-gamma decay is forbidden, but now a double-gamma decay of excited 137 Ba is reported that is in competition with a single-gamma decay. Competitive double-gamma decay Most decays of quantum states involve the emission of one photon, but in processes first predicted by Nobel laureate Maria Goeppert-Mayer more than 75 years ago, exotic decays emitting two photons can occur. An analogous exotic decay process in atomic nuclei is the double-gamma decay, which has been observed in cases where the usual single-gamma decay is forbidden. In an experimental tour de force, Heiko Scheit and colleagues observe a double-gamma decay which is in competition with a single-gamma decay. Through decay of caesium-137, the first excited state of barium-137 is populated. Monitoring the emissions for more than 50 days and carefully excluding alternative explanations for their data, the authors are able to unambiguously measure the competitive double-gamma decay. Precise measurements of the double-gamma decay rate promise to give access to nuclear structure information that is elusive by other methods. The double-gamma ( γγ )-decay of a quantum system in an excited state is a fundamental second-order process of quantum electrodynamics. In contrast to the well-known single-gamma ( γ )-decay, the γγ -decay is characterized by the simultaneous emission of two γ quanta, each with a continuous energy spectrum. In nuclear physics, this exotic decay mode has only been observed for transitions between states with spin-parity quantum numbers J π = 0 + (refs 1 , 2 , 3 ). Single-gamma decays—the main experimental obstacle to observing the γγ -decay—are strictly forbidden for these 0 + → 0 + transitions. Here we report the observation of the γγ -decay of an excited nuclear state ( J π = 11/2 − ) that is directly competing with an allowed γ -decay (to ground state J π = 3/2 + ). The branching ratio of the competitive γγ -decay of the 11/2 − isomer of 137 Ba to the ground state relative to its single γ -decay was determined to be (2.05 ± 0.37) × 10 −6 . From the measured angular correlation and the shape of the energy spectra of the individual γ-rays, the contributing combinations of multipolarities of the γ radiation were determined. Transition matrix elements calculated using the quasiparticle–phonon model reproduce our measurements well. The γγ -decay rate gives access to so far unexplored important nuclear structure information, such as the generalized (off-diagonal) nuclear electric polarizabilities and magnetic susceptibilities 3 .</abstract><cop>London</cop><pub>Nature Publishing Group UK</pub><pmid>26469051</pmid><doi>10.1038/nature15543</doi><tpages>4</tpages></addata></record>
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title	Observation of the competitive double-gamma nuclear decay
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