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Related Concept Videos

Nuclear Transmutation03:20

Nuclear Transmutation

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Nuclear transmutation is the conversion of one nuclide into another. It can occur by the radioactive decay of a nucleus, or the reaction of a nucleus with another particle. The first manmade nucleus was produced in Ernest Rutherford’s laboratory in 1919 by a transmutation reaction, the bombardment of one type of nuclei with other nuclei or with neutrons. Rutherford bombarded nitrogen-14 atoms with high-speed α particles from a natural radioactive isotope of radium and observed...
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Radioactivity is a spontaneous disintegration of an unstable nuclide and is a random process, as all the nuclei in the sample do not decay simultaneously. The number of disintegrations per unit time is called the activity (A), which is directly proportional to the number of nuclei in the sample. The decay constant (λ) is an average probability of decay per nucleus in unit time.
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Related Experiment Video

Updated: Jun 4, 2025

Preparing an Isotopically Pure 229Th Ion Beam for Studies of 229mTh
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Preparing an Isotopically Pure 229Th Ion Beam for Studies of 229mTh

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229ThF4 thin films for solid-state nuclear clocks.

Chuankun Zhang1, Lars von der Wense1,2, Jack F Doyle1

  • 1JILA, NIST and University of Colorado, Department of Physics, University of Colorado, Boulder, CO, USA.

Nature
|December 18, 2024
PubMed
Summary
This summary is machine-generated.

Researchers developed a new method for creating Thorium-229 (²²⁹Th) thin films for nuclear clocks. This scalable approach uses microgram quantities of ²²⁹Th, reducing radioactivity and enabling field-deployable solid-state nuclear clocks.

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Area of Science:

  • Nuclear Physics
  • Quantum Optics
  • Materials Science

Background:

  • The Thorium-229 (²²⁹Th) nuclear isomeric transition is a promising candidate for next-generation nuclear clocks.
  • Current methods using ²²⁹Th-doped crystals face challenges due to material scarcity, radioactivity, and complex handling.
  • Advances in ²²⁹Th spectroscopy necessitate scalable and robust target materials for various applications.

Purpose of the Study:

  • To develop a scalable and efficient method for preparing ²²⁹Th spectroscopy targets.
  • To demonstrate the feasibility of using ²²⁹ThF₄ thin films for nuclear clock applications.
  • To reduce the amount of radioactive material required for ²²⁹Th-based technologies.

Main Methods:

  • Thin films of Thorium-229 tetrafluoride (²²⁹ThF₄) were grown using physical vapour deposition.
  • Laser excitation was performed on the ²²⁹Th nuclear transition within the ²²⁹ThF₄ thin films.
  • The radioactivity of the ²²⁹ThF₄ thin films was compared to traditional ²²⁹Th-doped crystals.

Main Results:

  • Successfully demonstrated laser excitation of the ²²⁹Th nuclear transition in ²²⁹ThF₄ thin films.
  • The thin film approach requires only micrograms of ²²⁹Th material, significantly less than previous methods.
  • ²²⁹ThF₄ thin films are compatible with photonic platforms and nanofabrication, enabling integrated devices.
  • Radioactivity levels are up to three orders of magnitude lower than in typical ²²⁹Th-doped crystals.
  • High nuclear emitter density in ²²⁹ThF₄ opens possibilities for quantum optics studies.

Conclusions:

  • Physical vapour deposition of ²²⁹ThF₄ thin films offers a scalable solution for ²²⁹Th spectroscopy targets.
  • This method paves the way for integrated, field-deployable solid-state nuclear clocks with reduced radioactivity.
  • The developed thin films hold potential for advancing nuclear clock technology and quantum optics research.