An efficient method for producing <sup>9</sup>Be<sup>+</sup> ions using a 2 + 1 resonance-enhanced multiphoton ionization process

Li, Min; Zhang, Yong; Zhang, Qian-Yu; Bai, Wen-Li; He, Sheng-Guo; Peng, Wencui; Tong, Xin

doi:10.1088/1361-6455/ac4c8f

Cited by 5 publications

(5 citation statements)

References 47 publications

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“…The distance from the calcium target to the entrance end cap is 55 mm. A diodepumped pulsed laser at wavelength 1064 nm, with the energy of ∼110 µJ/pulse and 8 ns duration, has a Gaussian spatial profile and is focused to a 1/e 2 diameter of 80 (10) µm on a calcium target. The ablation laser energy is monitored by an energy meter (Coherent, FieldMaxII) and the laser is operated at a stable condition but with a large energy of about 20 mJ.…”

Section: Methodsmentioning

confidence: 99%

Section: Ion Loading With Multiple-pulse Laser Ablationmentioning

confidence: 99%

“…When the pulse energy of the ablation laser is below 70 (10) µJ, no ion is loaded into the ion trap due to the low fluence of the ablation laser. The ablation threshold for successfully loading ions is then obtained to be 1.4(3) J cm −2 with the ablation laser spot size of 80 (10) µm, which is consistent with the ablation threshold of metal targets [49]. At the low energy range of 70 and 90 µJ of the ablation laser, the numbers of Ca + ions loaded and accumulated in the ion trap increase with almost equal quantities for each ablation laser pulse.…”

Section: Ion Loading With Multiple-pulse Laser Ablationmentioning

confidence: 99%

“…A conventional method for loading ions into an ion trap consists of the production and ionization of atoms. A neutral flux of atoms is commonly produced from a resistively heated oven, and atoms are ionized in the trap via electron impact [7,8] or photoionization [9,10]. The heated oven is typically operated for tens of seconds and at temperatures over several hundred Kelvin, resulting in a significant heating background and limited application in a cryogenic environment.…”

Section: Introductionmentioning

confidence: 99%

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Dynamic laser ablation loading of a linear Paul trap

Li,

Hua

et al. 2024

J. Phys. D: Appl. Phys.

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We present a detailed method for accumulating Ca+ ions controllably in a linear Paul trap. The ions are generated by pulsed laser ablation and dynamically loaded into the ion trap by switching the trapping potential on and off. The loaded ions are precooled by buffer gas and then laser-cooled to form Coulomb crystals for verifying quantity. The number of ions is controlled by manipulating the trapping potential of the ion trap, partial pressure of buffer gas and turn-on time of the entrance end cap voltage. With single-pulse laser ablation, the number of trapped ions ranges from tens to ten thousand. The kinetic energy of loaded ions can be selected via the optimal turn-on time of the entrance end cap. Using multiple-pulse laser ablation, the number is further increased and reaches about 4×10^4. The dynamic loading method has wide application for accumulating low-yielding ions via laser ablation in the ion trap.

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Section: Methodsmentioning

confidence: 99%

Section: Ion Loading With Multiple-pulse Laser Ablationmentioning

confidence: 99%

Section: Ion Loading With Multiple-pulse Laser Ablationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dynamic laser ablation loading of a linear Paul trap

Li,

Hua

et al. 2024

J. Phys. D: Appl. Phys.

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“…[21] The 9 Be + ions are then loaded into the ion trap by photoionizing the atomic Be beam produced by a Be oven. [22] The trapped 9 Be + ions are sympathetically cooled by the ultracold 40 Ca + ions to form a 9 Be + -40 Ca + bicomponent CC. The 9 Be + ions appear as a dark core in the center area of the bi-component CC if the 313 nm laser is not introduced or at large detuning from the 9 Be + resonance.…”

Section: Methodsmentioning

confidence: 99%

Investigation of spatial structure and sympathetic cooling in the ⁹Be⁺–⁴⁰Ca⁺ bi-component Coulomb crystals

Zhang

et al. 2023

Chinese Phys. B

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We study the spatial structure and sympathetic cooling of the bi-component Coulomb crystal (CC) which consists of approximate 450 9Be+ ions and 450 40Ca+ ions with a mass ratio of 0.225 in a segmented linear ion trap. By two-dimensional imaging of the bi-component CC, the 9Be+ ions are found to be surrounded by the 40Ca+ ions in the radial direction with a separation ratio of ~2.0, and the axial length of the 9Be+ ions occupied area is much larger than that of the 40Ca+ ions occupied area. Combined with the previous experimental results, the structure of the 9Be+-40Ca+ CC shows the larger the difference in the mass-charge ratio, the larger the separation between the two species. The comparison of the fluorescence spectra of the 9Be+ ions in the bi-component CC and the pure CC indicates that the 9Be+ ions can be sympathetically cooled and stably localized by the laser-cooled 40Ca+ ions during the recording of the fluorescence spectrum.

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Scheme for the excitation of thorium-229 nuclei based on electronic bridge excitation

Li²,

Wang³

et al. 2023

NUCL SCI TECH

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Thorium-229 possesses the lowest first nuclear excited state, with an energy of approximately 8 eV. The extremely narrow linewidth of the first nuclear excited state, with an uncertainty of 53 THz, prevents direct laser excitation and realization of the nuclear clock. We present a proposal using the Coulomb crystal of a linear chain formed by $$^{229}$$ 229 Th$$^{3+}$$ 3 + ions, where the nuclei of $$^{229}$$ 229 Th$$^{3+}$$ 3 + ions in the ion trap are excited by the electronic bridge (EB) process. The 7$$P_{1/2}$$ P 1 / 2 state of the thorium-229 nuclear ground state is chosen for EB excitation. Using the two-level optical Bloch equation under experimental conditions, we calculate that 2 out of 36 prepared thorium ions in the Coulomb crystal can be excited to the first nuclear excited state, and it takes approximately 2 h to scan over an uncertainty of 0.22 eV. Taking advantage of the transition enhancement of EB and the long stability of the Coulomb crystal, the energy uncertainty of the first excited state can be limited to the order of 1 GHz.

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An efficient method for producing ⁹Be⁺ ions using a 2 + 1 resonance-enhanced multiphoton ionization process

Cited by 5 publications

References 47 publications

Dynamic laser ablation loading of a linear Paul trap

Dynamic laser ablation loading of a linear Paul trap

Investigation of spatial structure and sympathetic cooling in the ⁹Be⁺–⁴⁰Ca⁺ bi-component Coulomb crystals

Scheme for the excitation of thorium-229 nuclei based on electronic bridge excitation

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An efficient method for producing 9Be+ ions using a 2 + 1 resonance-enhanced multiphoton ionization process

Cited by 5 publications

References 47 publications

Dynamic laser ablation loading of a linear Paul trap

Dynamic laser ablation loading of a linear Paul trap

Investigation of spatial structure and sympathetic cooling in the 9Be+–40Ca+ bi-component Coulomb crystals

Scheme for the excitation of thorium-229 nuclei based on electronic bridge excitation

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Product

Resources

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An efficient method for producing ⁹Be⁺ ions using a 2 + 1 resonance-enhanced multiphoton ionization process

Investigation of spatial structure and sympathetic cooling in the ⁹Be⁺–⁴⁰Ca⁺ bi-component Coulomb crystals