In the realm of time measurement, scientists have long relied on atomic clocks that utilize the oscillations of electrons within atoms, providing an accurate representation of the second, the foundational unit of time. However, a paradigm shift is underway as researchers explore nuclear clocks, which promise even greater precision by leveraging the behavior of atomic nuclei.

Traditional atomic clocks, while groundbreaking, have limitations when it comes to accuracy. These limitations arise mainly from environmental factors and the inherent properties of electrons. Nuclear clocks, in contrast, take advantage of the stable properties of atomic nuclei, especially the transitions that occur within them. One particularly promising candidate in this uncharted territory is the 229Th isotope. Characterized by a long half-life of 103 seconds and a relatively low excitation energy, this isomer becomes a prime focus for technological advancement.

The potential of 229Th lies in its capability to be excited by vacuum ultraviolet (VUV) lasers, which allows researchers to utilize its unique properties in various applications. With nuclear clocks, we open the doors to not only enhanced timekeeping but could also pave the way towards advancements in fields such as fundamental physics and compact measurement devices.

To tap into the benefits of the 229Th isomer, Assistant Professor Takahiro Hiraki and his team from Okayama University embarked on an ambitious project. In their groundbreaking study published in *Nature Communications* on July 16, 2024, they demonstrated innovative techniques to handle the 229Th isomeric states effectively. By synthesizing VUV-transparent CaF2 crystals doped with 229Th, they created an experimental setup that could assess the states of the isomeric nuclear population and observe its radiative decay.

Hiraki articulated the aim of their research, stating the necessity of controlling both excitation and de-excitation processes of the nucleus for the development of a solid-state nuclear clock. Their method approached excitation through the manipulation of the nuclear state using X-rays, showcasing the versatility of their technique and ensuring an unprecedented level of control over the isomeric state.

The team’s exploration into radiative decay revealed crucial insights. By applying resonant X-ray beams to excite the 229Th nuclei from their ground state to the isomer state, they were able to document the decay process back to the ground state, resulting in a VUV photon emission. This finding was monumental, shedding light on the rapid decay rates influenced by X-ray exposure. Notably, they identified “X-ray quenching,” a phenomenon enabling the on-demand depopulation of the isomer state.

Such developments unveil new possibilities for advancing nuclear clock precision, indicating a step forward in achieving more compact yet highly efficient metrology devices, like portable gravity sensors and enhanced GPS systems. The researchers’ control over these quantum states could revolutionize timekeeping technology, potentially leading to highly precise navigation systems and improved scientific measurements.

The implications of this research stretch beyond mere accuracy in timekeeping; successful development of a nuclear clock utilizing 229Th could enable scientists to evaluate fundamental constants of nature. Assistant Professor Hiraki voiced the aspirations of their work, indicating that nuclear clocks may one day allow researchers to test whether constants believed to be universal actually change over time.

This revelation could confront long-standing assumptions that physical constants are immutable, potentially influencing other scientific disciplines from cosmology to quantum mechanics. As we peel back layers of understanding about time and its measurement, the pursuit of such advanced technologies presents profound questions that challenge our understanding of the universe.

As researchers like Hiraki lead the charge into the next frontier of timekeeping with nuclear clocks, the blend of atomic physics and time measurement may redefine how we perceive temporal phenomena. The journey from traditional atomic clocks to the intricate dynamics of nuclear timekeeping not only refines our grasp of time but also opens avenues for groundbreaking discoveries in the fundamental laws that govern our universe.

Physics

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