Nuclear clock
A nuclear clock is a highly precise timekeeping device that utilizes the frequency of transitions between energy levels within an atom's nucleus, rather than the electron shells used in atomic clocks, to achieve stability potentially exceeding current standards by orders of magnitude.[1] Unlike atomic clocks, which operate at microwave frequencies around 10 gigahertz, nuclear clocks leverage gamma-ray or low-energy nuclear excitations, such as those in thorium-229, to produce oscillations with narrower linewidths and reduced sensitivity to external electromagnetic perturbations.[2] This nuclear approach exploits the strong nuclear force binding protons and neutrons, enabling measurements that could redefine the second in the International System of Units (SI) and probe variations in fundamental constants.[3] The concept of nuclear clocks emerged in the early 2000s as an extension of atomic timekeeping technology, first proposed in 2003 by researchers Ekkehard Peik and Christian Tamm, who suggested using low-energy nuclear transitions for frequency standards far superior to electronic ones.[4] Early interest stemmed from the 1976 conjecture of an isomeric state in thorium-229 (²²⁹Th), an excited nuclear level at approximately 8 electron volts—uniquely low for nuclear excitations, making it accessible via ultraviolet lasers rather than high-energy gamma rays required for most nuclei.[4] Direct observation of this ²²⁹Th isomer proved challenging, with the first unambiguous identification occurring in 2016 through detection of internal-conversion electrons, paving the way for experimental pursuits at facilities like CERN's ISOLDE and JILA.[4] Significant progress accelerated in the late 2010s and early 2020s, with refined measurements of the ²²⁹Th transition energy narrowing from 0.1 eV uncertainty in 2019 to 0.01 eV by 2022, enabling laser excitation demonstrations in trapped ions and solid-state crystals.[4] Challenges included achieving long-lived excited states for narrow spectral lines and bridging the precision gap from electron-volt to hertz scales, but approaches like ion trapping reached relative accuracies of about 10⁻¹⁹.[4] In September 2024, an international team at JILA, including researchers from NIST, achieved a breakthrough by demonstrating the world's first operational nuclear clock prototype using ²²⁹Th nuclei embedded in calcium fluoride crystals, linking its transition frequency directly to a strontium atomic clock with 12-digit precision—one million times better than previous nuclear measurements.[1] This experiment, published in Nature, observed the nuclear excitation via ultraviolet laser pulses and revealed unprecedented details about the nucleus's octupole-deformed shape, confirming its suitability for timekeeping.[1] Nuclear clocks promise transformative applications beyond timekeeping, including centimeter-level enhancements to GPS and deep-space navigation, as well as stringent tests of fundamental physics by comparing nuclear and atomic frequencies to detect drifts in constants like the fine-structure constant or search for dark matter influences.[3] With projected stabilities reaching 10⁻²⁰ or better—surpassing atomic clocks' 10⁻¹⁸—these devices could lose just one second over billions of years, opening new windows into quantum gravity and unseen particles.[2]Background
Nuclear isomers
Nuclear isomers are metastable excited states of atomic nuclei, where one or more protons or neutrons occupy higher-energy quantum levels within the nucleus, leading to delayed decay compared to typical nuclear excited states.[5] These states exhibit half-lives spanning from nanoseconds to years, with the longer-lived ones classified as metastable due to hindered transitions caused by factors such as high angular momentum differences or forbidden multipolarities.[5] In contrast to electronic transitions in atomic shells, which operate at energy scales of a few electron volts (eV), nuclear isomers involve excitation energies typically ranging from tens of keV to several MeV, reflecting the stronger binding forces within the nucleus.[6] This disparity arises from the vastly different interaction strengths: electromagnetic forces dominate atomic electrons, while the strong nuclear force governs nucleon arrangements.[6] Prominent examples of nuclear isomers include technetium-99m, with a 6-hour half-life and applications in medical imaging, and tantalum-180m, which has a half-life exceeding 10^{15} years and occurs naturally in trace amounts.[5] Low-energy isomers, particularly those below 10 keV, are rare but noteworthy for their potential accessibility to laser excitation; thorium-229 serves as a prime example in this category. These isomers form through nuclear reactions, such as neutron capture, charged-particle bombardment, or astrophysical processes like the slow neutron capture in stars.[5] Decay occurs mainly via electromagnetic transitions, including gamma-ray emission or internal conversion where the energy is transferred to an atomic electron, though low-lying isomers may enable direct optical or near-optical excitation without such processes.[5] A key advantage of nuclear isomers lies in their relative insensitivity to external perturbations, as the nucleons are shielded by the surrounding electron cloud, minimizing shifts from electric, magnetic fields, or chemical environments compared to atomic transitions.[7] This property positions them as candidates for enhanced precision in timekeeping applications.[7]Comparison to atomic clocks
Atomic clocks operate by measuring the frequency of hyperfine transitions in the ground state or optical transitions in the electron shells of atoms, such as cesium-133 for microwave standards or ytterbium and strontium for optical lattice clocks, achieving fractional frequency uncertainties around 10^{-19} as of 2025.[8] These clocks rely on the larger atomic scale (on the order of angstroms), making their electron transitions susceptible to perturbations from external electric and magnetic fields, temperature variations, and relativistic effects like time dilation in moving frames.[1] In contrast, nuclear clocks utilize transitions within the atomic nucleus, which operates on a femtometer scale—about 10,000 times smaller than the atomic electron cloud—leading to inherently lower sensitivity to these environmental and relativistic perturbations due to the shielding by surrounding electrons and the compact nuclear structure.[9] The leading candidate for such a clock is the low-energy isomer transition in thorium-229.[1] This nuclear insensitivity, combined with higher transition frequencies in the ultraviolet range, enables projected fractional uncertainties of 10^{-19} or better, potentially matching or exceeding current atomic standards.[10][9] Beyond precision, nuclear clocks offer advantages in size and portability; implementations in ion traps or solid-state crystals could yield compact devices robust against vibrations and field fluctuations, facilitating applications in navigation, telecommunications, and fundamental physics tests where atomic clocks require extensive stabilization.[2]| Parameter | Atomic Clocks | Nuclear Clocks (Projected) |
|---|---|---|
| Transition Scale | Electron shells (~0.1 nm) | Nucleus (~1 fm) |
| Sensitivity to Fields | High (e.g., blackbody radiation shift ~10^{-17}) | Low (shielded, ~10^{-19} or better) |
| Current Stability | ~10^{-19} (e.g., optical lattice, as of 2025) | Goal: 10^{-19} (e.g., Th-229 transition) |
| Transition Energy | Optical: ~1-3 eV | UV: ~8 eV (Th-229) |
Operating principles
Thorium-229 transition
The thorium-229 nucleus hosts a low-lying isomeric state, denoted ^{229m}Th, which lies approximately 8.3 eV above the ground state and represents the lowest known excitation energy among all nuclear isomers. This unique property arises from the nuclear structure of ^{229}Th, where the isomer corresponds to a first excited state with spin and parity 3/2^+ , contrasting the ground state's 5/2^+ .[11] The transition between the isomeric and ground states is of mixed magnetic dipole (M1) and electric quadrupole (E2) character, rendering it partially forbidden and resulting in a relatively long radiative half-life of about 1740(50) seconds in vacuum conditions.[12] This corresponds to an ultraviolet wavelength of approximately 150 nm. The energy of this transition has been refined over decades through indirect methods before achieving direct measurement. Initially conjectured in 1976 with an upper limit below 100 eV, subsequent gamma spectroscopy and internal conversion studies in the 1990s to 2000s yielded estimates ranging from 3.5 eV to 7.8 eV. More precise indirect values emerged around 8.28(17) eV in 2016 via internal conversion electron spectroscopy, culminating in the first direct laser excitation in 2024, which confirmed the energy as 8.355(18) eV using thorium-doped crystals. The transition frequency \nu is given by \nu = E / h, where E is the excitation energy and h is Planck's constant. Substituting E \approx 8.355 eV yields \nu \approx 2.0 \times 10^{15} Hz, establishing a sharp optical-frequency reference. In nuclear clock designs, this frequency governs the coherent Rabi oscillations between the ground and isomeric states, providing an insensitive reference for ultraprecise timekeeping.Excitation and readout methods
The excitation of the nuclear isomer in thorium-229 for clock operation relies on direct laser pumping, where a vacuum-ultraviolet (VUV) laser at approximately 148–160 nm resonantly populates the 229mTh state from the nuclear ground state. This process exploits the low excitation energy of about 8.3 eV, enabling optical access to the isomer, though the transition's forbidden nature (primarily M1 with E2 admixture) results in a weak interaction strength.[13][14][15] Following excitation, the dominant decay channel is internal conversion (IC), in which the nuclear excitation energy is transferred non-radiatively to an atomic electron, ejecting it as a conversion or Auger electron with kinetic energy roughly equal to the isomer energy minus the electron binding energy. The IC coefficient for neutral 229Th is extremely high, on the order of 10^8–10^9, suppressing the radiative decay probability to less than 10^{-8} and yielding a short isomer lifetime of microseconds in neutral atoms.[15] In highly charged ions (e.g., Th^{3+}), IC is suppressed due to increased binding energies, allowing a longer radiative lifetime of seconds to hours, which is advantageous for clock interrogation; for example, the radiative lifetime of the ^{229m}Th^{3+} isomer has been measured as approximately 1400 seconds (2024).[14][16] Readout techniques primarily leverage the IC process for high sensitivity. Upon decay, the emitted electron causes ionization, producing a detectable charge-state change or electron signal, often captured using microchannel plates (MCPs) or spectrometers after ion neutralization to trigger IC. An alternative, though less efficient, method involves detecting VUV fluorescence from the rare radiative decay, using parabolic mirrors and photomultiplier tubes with collection efficiencies around 0.3%. The overall process proceeds as follows: a narrow-linewidth VUV laser pulse excites the nucleus, prompting IC-mediated electron emission that generates an ion or fluorescence signal for state readout.[17][14][18] Key challenges include the low efficiency of direct excitation, stemming from the transition's small oscillator strength (f ≈ 10^{-6}–10^{-7}) and resulting in absorption probabilities per pulse often below 1% without resonant enhancement. Additionally, achieving the required laser linewidth (sub-kHz to match the nuclear coherence time) demands advanced VUV sources, such as frequency combs generated via high-harmonic generation, to avoid off-resonant losses.[15]Implementations
Ion-trap nuclear clocks
Ion-trap nuclear clocks are designed around single ^{229}Th^{3+} ions confined in radiofrequency Paul traps or Penning traps, which provide electrostatic isolation to minimize interactions with external fields and surfaces. This setup leverages the high charge state of Th^{3+} to suppress internal conversion in the electronic ground state, allowing the nuclear isomer to decay primarily via radiative processes while enabling precise control over the ion's quantum state. The choice of Th^{3+} ensures closed electronic transitions for efficient laser cooling and state manipulation using auxiliary visible or near-infrared wavelengths. Operation involves preparing the ion in a specific hyperfine state of the nuclear ground level, followed by interrogation with a vacuum-ultraviolet laser tuned to the low-energy nuclear transition at approximately 8.36 eV (corresponding to a frequency of about 2.01 PHz). Excitation populates the nuclear isomeric state ^{229m}Th, and the clock readout employs a double-resonance technique: fluorescence from an atomic transition is monitored to distinguish nuclear states, with the nuclear spin serving as a "memory" qubit insensitive to electronic perturbations. Internal conversion, if occurring, ejects an electron to produce Th^{4+}, which is detected via time-of-flight mass spectrometry using a microchannel plate detector after releasing the ion from the trap; however, for non-destructive clock operation, quantum logic spectroscopy with co-trapped ions can resolve the nuclear state without charge change. The advantages of this approach include exceptional spectral purity from single-ion isolation, enabling interrogation times limited only by the nuclear lifetime (projected at 10^3 to 10^4 seconds), and the potential for quantum entanglement with sympathetic cooling ions like ^{88}Sr^{+} for enhanced stability. Unlike atomic clocks, the nuclear transition exhibits greatly reduced sensitivity to electric fields (Stark shifts below 10^{-20} fractional frequency) and blackbody radiation, while allowing full quantum control for error mitigation. Key experiments include the 2012 proposal by Campbell et al. at NIST, which outlined the single-ion architecture and projected metrology performance. In 2023, researchers at the Weizmann Institute of Science quantified trap-induced AC Zeeman shifts, confirming they remain below 10^{-18} at typical trap frequencies.[19] A major milestone came in 2024 from the University of Tokyo and RIKEN, who trapped ^{229}Th^{3+} and ^{229m}Th^{3+} ions from ^{233}U decay, performed laser spectroscopy to resolve hyperfine structure, and measured the isolated isomer half-life at 1,400^{+600}_{-300} seconds—validating the system's suitability for clock operation.[20] JILA and NIST have contributed through development of VUV frequency combs via four-wave mixing, achieving linewidths under 1 kHz for future direct excitation in traps. Performance metrics project a short-term frequency stability of 10^{-15} τ^{-1/2} (where τ is averaging time in seconds), scaling to 10^{-19} fractional inaccuracy after accounting for systematic effects like second-order Doppler shifts (<5 \times 10^{-20}) and electric quadrupole interactions. Electric field shifts are dominated by residual motional effects but can be nulled using stretched hyperfine states, with overall uncertainty estimates at 10^{-19} for a realized device.Solid-state nuclear clocks
Solid-state nuclear clocks leverage ensembles of thorium-229 (²²⁹Th) nuclei embedded in crystalline hosts to enable scalable and compact timekeeping beyond the limitations of single-ion systems. In this approach, ²²⁹Th ions, typically in the Th⁴⁺ charge state, are doped or implanted into wide-bandgap crystals such as calcium fluoride (CaF₂), which are transparent to vacuum ultraviolet (VUV) light. These ensembles can contain up to 10¹⁴ nuclei per crystal, allowing collective interrogation for enhanced signal strength. Unlike ion-trap methods that isolate individual ions for high-fidelity control, solid-state designs prioritize ensemble averaging to improve overall clock performance through statistical robustness.[21][1] Operation involves direct laser excitation of the low-energy nuclear isomer transition at approximately 8.36 eV using broadband VUV sources, such as frequency combs generated via harmonic upconversion of infrared lasers in enhancement cavities. The excitation promotes the nucleus from its ground state to the metastable isomer (²²⁹mTh), which decays via internal conversion or radiative emission. Readout is achieved through detection of scintillation photons from crystal fluorescence or ejected conversion electrons from the lattice, often performed at cryogenic temperatures around 77 K to minimize thermal noise. This ensemble-based readout contrasts with single-ion fluorescence by providing higher photon or electron counts for better signal-to-noise ratios.[21][1][22] The primary advantages of solid-state nuclear clocks stem from their ability to interrogate vast numbers of nuclei simultaneously, yielding fractional instabilities as low as 1.8 × 10⁻¹⁹ over integration times of 10⁴ seconds in theoretical models. This ensemble scaling facilitates miniaturization into chip-scale devices without vacuum chambers or ion traps, potentially reducing costs and enabling portable applications in precision metrology. Additionally, the nuclear transition's insensitivity to external electromagnetic fields offers stability superior to atomic clocks in perturbed environments.[21][1] Key experiments include the development of a solid-state prototype by an international team including researchers from TU Wien and JILA/NIST, using ²²⁹Th-doped CaF₂ crystals to demonstrate the world's first operational nuclear clock in 2024. The team achieved direct laser excitation of the isomer and measured the nuclear transition frequency, enabling a direct comparison to the ⁸⁷Sr optical lattice clock and establishing a frequency ratio with fractional uncertainty of 4.8 × 10⁻¹⁵. This milestone, reported in Nature, marked the first realization of a functional nuclear frequency standard using solid-state media.[1] In 2025, the technology was further applied to measure the sensitivity of the nuclear transition to the fine-structure constant with K = 5900(2300), demonstrating its utility for fundamental physics tests.[10] Despite these advances, challenges persist, including line broadening due to lattice interactions such as magnetic dipole couplings and electric field gradients, which can limit linewidths to around 150 Hz and introduce global frequency shifts up to 1 GHz. Temperature variations exacerbate these effects, with the clock transition shifting by approximately 0.4 kHz/K in CaF₂ hosts, necessitating stabilization to 5 µK for 10⁻¹⁸ precision. Furthermore, inhomogeneous broadening from non-uniform doping sites requires site-selective implantation techniques to ensure consistent nuclear environments across the ensemble.[21][22]Technical challenges
Transition frequency requirements
The transition frequency of the nuclear clock, particularly for the thorium-229 isomer, must be determined with exceptional precision to enable the high stability required for advanced timekeeping. To achieve a fractional frequency stability of $10^{-18}, the absolute frequency \nu \approx 2 \times 10^{15} Hz must be known to within less than 1 Hz, as the relative uncertainty in frequency knowledge directly limits the clock's systematic accuracy.[23] Calibration of this frequency relies on direct comparison to established atomic clocks, such as the ^{87}Sr optical clock, using vacuum-ultraviolet frequency combs to bridge the nuclear transition to traceable electronic references and ensure absolute metrology.[1] Surpassing the performance of state-of-the-art optical lattice clocks, which operate at relative uncertainties around $10^{-18}, demands even tighter constraints on the nuclear transition. Specifically, the relative uncertainty must satisfy \frac{\delta \nu}{\nu} < 10^{-19} to provide a meaningful improvement in precision, allowing nuclear clocks to probe subtle variations in fundamental constants.[1] Factors influencing the accuracy of this frequency include isotope shifts arising from differences in nuclear radii across thorium isotopes, which alter the transition energy through volume-dependent effects, and hyperfine structure in the nuclear levels due to interactions with the atomic electron cloud.[24] Recent progress has significantly narrowed the measurement uncertainty. In 2024, researchers at NIST and JILA used VUV frequency comb spectroscopy in a solid-state thorium-doped calcium fluoride crystal to measure the ^{229m}Th transition frequency at 2,020,407,384,335 ± 2 kHz relative to the ^{87}Sr clock, achieving a relative uncertainty of $10^{-12} and reducing prior indirect estimates by orders of magnitude through direct excitation and readout.[1] This represents a factor-of-10 improvement over earlier direct attempts limited by broader linewidths and less stable references, though further refinements are needed to approach the sub-Hz regime.[1]Sensitivity and stability issues
Nuclear clocks based on the thorium-229 isomer exhibit minimal sensitivity to electric fields due to the small nuclear charge radius, which results in shifts several orders of magnitude smaller than those in atomic clocks.[25] However, residual sensitivities arise from electronic correlations in the surrounding atomic shell, which can induce second-order effects on the nuclear transition frequency.[26] The transition is inherently insensitive to magnetic fields, as the nuclear states involved have similar magnetic moments, suppressing Zeeman shifts compared to electronic transitions.[27] Key factors affecting long-term stability include the laser linewidth required for excitation, which must be narrower than 1 MHz to resolve the transition without broadening the linewidth beyond the natural limit. Blackbody radiation shifts are significantly suppressed in highly charged ions like Th^{4+}, where the closed-shell electronic structure minimizes dynamic Stark effects from thermal photons, reducing the shift to levels below 10^{-19} fractional frequency.[27] Relativistic effects, such as time dilation from ion motion, also contribute but can be controlled through trapping configurations. To mitigate these issues, cryogenic operation at temperatures below 4 K is employed to minimize thermal sensitivities and blackbody shifts, while active field compensation techniques, including dynamic decoupling, counteract residual electric and magnetic perturbations. Active stabilization of the laser source and trap environment further enhances coherence times, enabling interrogation periods necessary for high stability. A 2025 measurement in solid-state ^{229}Th revealed a temperature sensitivity of 0.4 kHz/K for key transitions, requiring crystal temperature stability of 5 μK to achieve 10^{-18} fractional frequency precision.[28] Performance targets for nuclear clocks include an Allen deviation σ_y(τ) below 10^{-18} at averaging times of 1 second, with potential scaling to 10^{-19} through multi-ion ensembles or solid-state implementations. Unlike neutral atomic clocks, nuclear transitions in thorium-229 are less susceptible to collision-induced frequency shifts, allowing operation in dense ensembles without significant perturbations.[21]Historical development
Discovery of the 229Th isomer
The existence of a low-lying isomeric state in the nucleus of thorium-229 (^{229m}Th) was first proposed in 1976 through gamma-ray spectroscopy of the alpha decay of uranium-233 (^{233}U). Researchers L. A. Kroger and C. W. Reich, affiliated with Los Alamos National Laboratory, analyzed the gamma-ray spectrum and identified an unexplained low-energy transition, inferring an isomeric state with an excitation energy below 100 eV, based on the experimental resolution of approximately 450 eV.[29] This marked the initial hint of a nuclear transition accessible in the ultraviolet or vacuum ultraviolet range, distinct from typical nuclear excitations in the keV to MeV regime. Nuclear isomers, being long-lived excited nuclear states, are common in heavy nuclei, but the proposed energy for ^{229m}Th was uniquely low, suggesting potential for direct optical probing. Early confirmations in the 1980s and 1990s relied on indirect methods, primarily high-resolution gamma spectroscopy of higher-lying states in ^{229}Th to infer the isomer energy via energy differences. In 1990, C. W. Reich and R. G. Helmer from the Idaho National Engineering Laboratory refined the estimate to -1 ± 4 eV by measuring gamma-ray transitions from 29 keV to 320 keV and extrapolating the ground-state doublet separation.[30] Further refinement came in 1994 from the same group, using similar gamma spectroscopy techniques to narrow the energy to 3.5 ± 1.0 eV, establishing a benchmark value that persisted for years. These measurements, involving groups at national laboratories including precursors to modern efforts at Lawrence Livermore National Laboratory (LLNL), confirmed the anomalously low energy but remained indirect, as no distinct emission line from the isomer itself was resolved. Significant challenges hampered progress, including the low production rate of the isomer ^{229m}Th, populated via approximately 0.2% branching ratio in ^{233}U alpha decay, yielding only trace amounts for spectroscopy. Attempts at internal conversion electron detection in the 1990s, probing the dominant decay mode of the isomer, failed to isolate the signal due to background noise and insufficient isomer population. Direct observation of the isomer's decay—via internal conversion electrons—remained elusive until 2016. The Physikalisch-Technische Bundesanstalt (PTB) in Germany and LLNL contributed to early theoretical and experimental frameworks, with initial energy estimates around 7.8 eV emerging from later refinements building on these foundations. This discovery underscored the potential for a nuclear transition bridging atomic and nuclear physics scales.Key experimental milestones
In the 2000s, experimental efforts refined the energy of the 229mTh isomer through indirect methods, including the detection of internal conversion electrons following alpha decay of 233U, yielding an improved estimate of approximately 7.8 ± 0.5 eV. This value, determined by Beck et al. in 2007, narrowed the uncertainty from earlier gamma-spectroscopy measurements and confirmed the isomer's accessibility to vacuum ultraviolet (VUV) light, paving the way for laser-based studies.[31] A major breakthrough occurred in 2016 with the first direct detection of the 229mTh isomer. Researchers at Ludwig Maximilian University of Munich produced a beam of 229Th ions enriched in the isomeric state via alpha recoil from 233U decay and observed its signature through internal conversion electron emission, providing confirmation of the isomer's existence.[32] In 2017, the same group measured the half-life of ~7 μs for Th^{3+} ions.[33] The half-life for neutral atoms was later measured as ~20 μs in 2020. This experiment laid the groundwork for resonant excitation attempts by enabling precise identification of the isomeric decay channel. During the 2020s, multiple laser excitation efforts advanced toward nuclear clock realization. In 2023, a collaboration at TU Wien observed the radiative decay of laser-populated 229mTh in thorium-doped crystals, marking the first direct evidence of VUV emission from the isomer and constraining its energy to 8.338 ± 0.024 eV.[34] In 2024, direct resonant laser excitation of the 229mTh isomer was achieved independently by two groups, enabling the first frequency measurements for a nuclear clock prototype. At TU Wien, researchers used a tabletop VUV laser to excite thorium-doped CaF2 crystals, observing nuclear fluorescence and determining the transition energy as 8.35574 ± 0.00002(stat) ± 0.00010(sys) eV.[35] Concurrently, the NIST/JILA team reported excitation in the same host material, measuring the nuclear transition frequency and its ratio to an optical atomic clock standard with a relative uncertainty of 3 × 10^{-15}, demonstrating stability competitive with state-of-the-art atomic clocks.[1] These results established the feasibility of nuclear clock operation by linking the isomer transition to traceable frequency references. In 2025, further advancements included precise measurement of the 229mTh transition's sensitivity to the fine-structure constant, enhancing prospects for dark matter detection and fundamental physics tests.[10]| Year | Key Group/Institution | Achievement |
|---|---|---|
| 2007 | Lawrence Livermore National Laboratory | Improved isomer energy estimate to ~7.8 eV via internal conversion electron spectroscopy. |
| 2016 | LMU Munich | First direct detection of 229mTh via internal conversion in ion beam. |
| 2017 | LMU Munich | Half-life measurement of ~7 μs for Th^{3+} ions. |
| 2023 | TU Wien/University of Vienna | Observation of radiative decay from laser-populated isomer, energy 8.338 ± 0.024 eV. |
| 2024 | TU Wien | Direct laser excitation in CaF2, precise energy measurement 8.35574 eV. |
| 2024 | NIST/JILA | Resonant excitation and frequency ratio to atomic clock, uncertainty 3 × 10^{-15}. |
| 2025 | Various (e.g., international collaborations) | Measurement of fine-structure constant sensitivity for fundamental physics applications. |