Proton emission

In this article, we will explore Proton emission in depth, analyzing its impact in different contexts and its relevance in today's society. From its origin to its evolution over time, Proton emission has played a fundamental role in various aspects of our daily lives. Through research and analysis, we will examine the various facets of Proton emission and how it has influenced and impacted the way we relate, work, and live. Additionally, we will examine the future implications of Proton emission and how it continues to shape our ever-changing world. This article provides an in-depth understanding of Proton emission and its importance in contemporary society.
"Proton radioactivity" redirects here. For hypothetical decay of protons into subatomic particles, see Proton decay.
The decay of a proton rich nucleus A populates excited states of a daughter nucleus B by β+ emission or electron capture (EC). Those excited states that lie below the separation energy for protons (Sp) decay by γ emission towards the ground state of daughter B. For the higher excited states a competitive decay channel of proton emission to the granddaughter C exists, called β-delayed proton emission.
Nuclear physics
Models of the nucleus
Nuclides' classification
Nuclear stability
Radioactive decay
Nuclear fission
Capturing processes
High-energy processes
Nucleosynthesis and
nuclear astrophysics
High-energy nuclear physics
Scientists

Proton emission (also known as proton radioactivity) is a rare type of radioactive decay in which a proton is ejected from a nucleus. Proton emission can occur from high-lying excited states in a nucleus following a beta decay, in which case the process is known as beta-delayed proton emission, or can occur from the ground state (or a low-lying isomer) of very proton-rich nuclei, in which case the process is very similar to alpha decay.[citation needed] For a proton to escape a nucleus, the proton separation energy must be negative (Sp < 0)—the proton is therefore unbound, and tunnels out of the nucleus in a finite time. The rate of proton emission is governed by the nuclear, Coulomb, and centrifugal potentials of the nucleus, where centrifugal potential affects a large part of the rate of proton emission. The half-life of a nucleus with respect to proton emission is affected by the proton energy and its orbital angular momentum.[1] Proton emission is not seen in naturally occurring isotopes; proton emitters can be produced via nuclear reactions, usually using linear particle accelerators.

Although prompt (i.e. not beta-delayed) proton emission was observed from an isomer in cobalt-53 as early as 1969, no other proton-emitting states were found until 1981, when the proton radioactive ground states of lutetium-151 and thulium-147 were observed at experiments at the GSI in West Germany.[2] Research in the field flourished after this breakthrough, and to date more than 25 isotopes have been found to exhibit proton emission. The study of proton emission has aided the understanding of nuclear deformation, masses, and structure, and it is a pure example of quantum tunneling.

In 2002, the simultaneous emission of two protons was observed from the nucleus iron-45 in experiments at GSI and GANIL (Grand Accélérateur National d'Ions Lourds at Caen).[3] In 2005 it was experimentally determined (at the same facility) that zinc-54 can also undergo double proton decay.[4]

See also

References

  1. ^ Poenaru, Dorin N.; Rebel, Heinigerd; Wentz, Jürgen, eds. (2001). Nuclei Far from Stability and Astrophysics. Dordrecht: Springer Netherlands. pp. 79–81. doi:10.1007/978-94-010-0708-5. ISBN 978-0-7923-6937-0.
  2. ^ S. Hofmann (1996). "Chapter 3: Proton radioactivity". In Dorin N. Poseru (ed.). Nuclear Decay Modes. Bristol: Institute of Physics Publishing. pp. 143–203. ISBN 0-7503-0338-7.
  3. ^ Armand, Dominique (June 6, 2002). "A new mode of radioactive decay". CNRS. Archived from the original on 4 February 2005. Retrieved 2022-01-07.
  4. ^ Blank, Bertram; Ploszajczak, Marek (December 17, 2013). "Two-proton radioactivity". Reports on Progress in Physics. 71 (4): 046301. arXiv:0709.3797. doi:10.1088/0034-4885/71/4/046301. S2CID 119276805.
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