Researchers have successfully detected the excitation of Thorium-229 nuclei in a solid clock using a laser-based method.
The experiment involved using Thorium dioxide and counting electrons emitted during the decay of excited nuclei.
A clear resonance was detected at 2,020,407.5 GHz, consistent with previous studies on Thorium-229.
The inferred internal conversion lifetime of 12.3 seconds suggests the clock would only be off by one second every 15.8 billion years.
Detailed Insights:
The core principle involves using the nucleus of Thorium-229 as a timekeeping mechanism, which is less sensitive to external disturbances compared to atomic clocks.
The process relies on exciting Thorium-229 nuclei with vacuum-ultraviolet (VUV) laser pulses and detecting the electrons emitted during internal conversion.
Researchers suppressed ordinary photoelectrons using timed electric fields to isolate and count the delayed electrons associated with nuclear decay.
This advancement allows for the development of stable, high-precision nuclear clocks and sensors capable of probing the nuclear environment of different materials.
The design facilitates substantial miniaturization, as the nuclear clock can be monitored by measuring the current of emitted electrons.
Scientific/Technical Concepts Involved:
Thorium-229: An isotope of thorium with a unique nuclear excited state suitable for nuclear clocks.
Internal Conversion: A decay process where a nucleus transfers energy to an electron instead of emitting a photon.
Vacuum-Ultraviolet (VUV): A region of the electromagnetic spectrum with wavelengths shorter than ultraviolet light, used to excite thorium nuclei.