Periodic Reporting for period 2 - ThoriumNuclearClock (Thorium nuclear clocks for fundamental tests of physics)
Berichtszeitraum: 2021-08-01 bis 2023-01-31
Time is one of the most basic physical units and probably the one we all have most experience within daily life. The most precise way of measuring time is by using so-called atomic clocks, which make use of extremely well determined quantum levels in the electron shell of atoms or ions to stabilize the “ticking”. These precision clocks have tremendous technological relevance; they constitute the backbone of our satellite-based navigation systems as well as our synchronized digital data traffic.
The Thorium nuclear clock project aims to implement a new type of clock – a nuclear clock. In contrast to electron shell levels used in atomic clocks, it uses quantum states within the atomic nucleus of Thorium-229 as a “ticking” reference. As the nucleus is a thousand times smaller than the electron shell, it reacts much less to perturbations caused by external fields or forces, so the nuclear clock is expected to be dramatically more robust than the current atomic clocks. Furthermore, the nuclear clock transition frequency is determined strongly by all fundamental forces acting inside the nucleus and hence can be used to probe these. A temporal or spatial variation of these forces could be a signature of the existence of dark matter, probably the universe’s greatest standing mystery.
Within the ERC synergy project, we will construct three complementary types of Thorium nuclear clocks and compare them amongst each other (and with conventional atomic clocks) to search for variations in the fundamental forces of nature.
The Thorium nuclear clock project aims to implement a new type of clock – a nuclear clock. In contrast to electron shell levels used in atomic clocks, it uses quantum states within the atomic nucleus of Thorium-229 as a “ticking” reference. As the nucleus is a thousand times smaller than the electron shell, it reacts much less to perturbations caused by external fields or forces, so the nuclear clock is expected to be dramatically more robust than the current atomic clocks. Furthermore, the nuclear clock transition frequency is determined strongly by all fundamental forces acting inside the nucleus and hence can be used to probe these. A temporal or spatial variation of these forces could be a signature of the existence of dark matter, probably the universe’s greatest standing mystery.
Within the ERC synergy project, we will construct three complementary types of Thorium nuclear clocks and compare them amongst each other (and with conventional atomic clocks) to search for variations in the fundamental forces of nature.
The first reporting period (M20) corresponds roughly to the 1st project phase (first 2 years). The main aim of this phase is a coarse determination of the isomer energy to within < 1 nm precision. This will be the starting point for phase two, which will see the development of dedicated laser systems for high precision spectroscopy and direct optical excitation of the isomer.
Phase 1 is almost complete. The synergy team has produced and published the most precise isomer energy measurements so far, partially in collaborative work.
Two complementary experiments have yielded compatible (within error bars) results.
A third experiment performed be the team of Piet van Duppen of KU Leuven at CERN with the participation of Synergy partners TU-Wien and LMU-Munich has observed the direct radiative decay of the isomer and performed VUV spectroscopy in this signal.
When this result has been published, the first phase can be considered as terminated successfully.
The two former results have been published in Nature and created significant media attention; we expect a similar or even greater impact from the third result.
Phase 1 is almost complete. The synergy team has produced and published the most precise isomer energy measurements so far, partially in collaborative work.
Two complementary experiments have yielded compatible (within error bars) results.
A third experiment performed be the team of Piet van Duppen of KU Leuven at CERN with the participation of Synergy partners TU-Wien and LMU-Munich has observed the direct radiative decay of the isomer and performed VUV spectroscopy in this signal.
When this result has been published, the first phase can be considered as terminated successfully.
The two former results have been published in Nature and created significant media attention; we expect a similar or even greater impact from the third result.