Cryogenic linear Paul trap for cold highly charged ion experiments

Schwarz, Maria A.; Versolato, Oscar; Windberger, Alexander; Brunner, F.; Ballance, Tim; Eberle, S.; Ullrich, J.; Schmidt, Piet O.; Hansen, Anders Kragh; Gingell, Alexander D.; Drewsen, Michael; López‐Urrutia, J. R. Crespo

doi:10.1063/1.4742770

Cited by 67 publications

(61 citation statements)

References 65 publications

(63 reference statements)

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“…Spectroscopy of the fluorescent light emitted by the electron-impact excited ions can yield sub-ppm accuracy for the absolute determination of transition wavelengths [4,5]. After such preliminary work we propose to exploit this system for a competitive search for ATV by performing laser spectroscopy of laser-cooled Ir 17+ trapped in a cryogenic Paul trap that was newly constructed for the purpose of trapping HCIs [24]. Quantum logical readout will be applied for ultimate sensitivity [6].…”

Section: Introductionmentioning

confidence: 99%

Cold highly charged ions in a cryogenic Paul trap

et al. 2013

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Narrow optical transitions in highly charged ions (HCIs) are of particular interest for metrology and fundamental physics, exploiting the high sensitivity of HCIs to new physics. The highest sensitivity for a changing fine structure constant ever predicted for a stable atomic system is found in Ir17 + . However, laser spectroscopy of HCIs is hindered by the large (∼ 106 K) temperatures at which they are produced and trapped. An unprecedented improvement in such laser spectroscopy can be obtained when HCIs are cooled down to the mK range in a linear Paul trap. We have developed a cryogenic linear Paul trap in which HCIs will be sympathetically cooled by 9Be + ions. Optimized optical access for laser light is provided while maintaining excellent UHV conditions. The Paul trap will be connected to an electron beam ion trap (EBIT) which is able to produce a wide range of HCIs. This EBIT will also provide the first experimental input needed for the determination of the transition energies in Ir17 + , enabling further laser-spectroscopic investigations of this promising HC

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Section: Introductionmentioning

confidence: 99%

Cold highly charged ions in a cryogenic Paul trap

et al. 2013

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“…For several types of ion-trap experiments, even small amounts of micromotion can have significant harmful effects: it can lead to large systematic Doppler shifts in ion-based atomic clocks [44,45], and it can substantially reduce the fidelities of quantum gates during a quantum computation (in the absence of advanced micromotion-correcting protocols) [46,47]. Nevertheless, many successful experiments do not depend sensitively on micromotion amplitude [48][49][50][51][52], and ion Coulomb crystals of up to 10 5 − 10 6 particles have been confined in rf Paul traps [53,54]. This section will demonstrate that for carefully chosen parameters (such as those introduced above), micromotion effects on 2D quantum simulation experiments are both predictable and small.…”

Section: Effects Of Micromotionmentioning

confidence: 99%

Two-dimensional ion crystals in radio-frequency traps for quantum simulation

Richerme

2016

Phys. Rev. A

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The computational difficulty of solving fully quantum many-body spin problems is a significant obstacle to understanding the behavior of strongly correlated quantum matter. Experimental iontrap quantum simulation is a promising approach for studying these lattice spin models, but has so far been limited to one-dimensional systems. This work argues that such quantum simulation techniques are extendable to a 2D ion crystal confined in a radiofrequency (rf) trap. Using appropriately chosen parameters, driven ion motion due to the rf fields can be made small and will not limit the types of quantum spin models that can be experimentally encoded. The rf-driven motion is calculated to modestly reduce the stability region of a 2D crystal and must be considered when designing the 2D trap. The system will be scalable to 100+ quantum particles, far beyond the realm of classical intractability, while maintaining the traditional ion-trap strengths of individual-ion control, long quantum coherence times, and site-resolved projective spin measurements.

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“…These steps enable follow-up laser spectroscopic studies suitable for optical clock applications. For this purpose, we have recently commissioned an experiment in which HCIs were extracted from an EBIT into a novel cryogenic Paul trap [13] where they were sympathetically laser cooled into Coulomb crystals at temperatures of few mK [46], thus preparing HCIs for quantum-logic readout schemes similar to that of Ref. [16].…”

Section: Prl 114 150801 (2015) P H Y S I C a L R E V I E W L E T T Ementioning

confidence: 99%

“…In most of the proposed HCIs with atomic number Z ¼ 55-98 and in charge states from 7 to 35, the complex electronic structures are experimentally unknown, and accurate calculations are extremely difficult. In view of novel techniques for sympathetically cooling HCIs in Paul traps [13][14][15] aiming at quantum logic spectroscopy on highly forbidden transitions [16], such data are urgently required.Observations from quasar absorption spectra have suggested a spatial variation of the value of the fine-structure constant α over cosmological dimensions [17], characterized by a dipolar distribution with a value of 10 −6 GLyr −1 . Laboratory experiments [18][19][20][21] have not yet reached the accuracy needed to test this dipolar pattern, which translates to a temporal variation of 10 −19 yr −1 [22] due to the motion of the Earth.…”

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Identification of the Predicted5s−4fLevel Crossing Optical Lines with Applications to Metrology and Searches for the Variation of Fundamental Constants

et al. 2015

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We measure optical spectra of Nd-like W, Re, Os, Ir, and Pt ions of particular interest for studies of a possibly varying fine-structure constant. Exploiting characteristic energy scalings we identify the strongest lines, confirm the predicted 5s-4f level crossing, and benchmark advanced calculations. We infer two possible values for optical M2=E3 and E1 transitions in Ir 17þ that have the highest predicted sensitivity to a variation of the fine-structure constant among stable atomic systems. Furthermore, we determine the energies of proposed frequency standards in Hf 12þ and W 14þ . DOI: 10.1103/PhysRevLett.114.150801 PACS numbers: 06.20.Jr, 31.15.am, 31.15.bw, 32.30.Jc Highly charged ions (HCIs) are currently in the focus of theoretical studies analyzing their applications to frequency metrology and tests of a variation of the fine-structure constant α [1][2][3][4][5][6][7][8][9][10][11][12]. In most of the proposed HCIs with atomic number Z ¼ 55-98 and in charge states from 7 to 35, the complex electronic structures are experimentally unknown, and accurate calculations are extremely difficult. In view of novel techniques for sympathetically cooling HCIs in Paul traps [13][14][15] aiming at quantum logic spectroscopy on highly forbidden transitions [16], such data are urgently required.Observations from quasar absorption spectra have suggested a spatial variation of the value of the fine-structure constant α over cosmological dimensions [17], characterized by a dipolar distribution with a value of 10 −6 GLyr −1 . Laboratory experiments [18][19][20][21] have not yet reached the accuracy needed to test this dipolar pattern, which translates to a temporal variation of 10 −19 yr −1 [22] due to the motion of the Earth. Future optical clocks based on HCIs [3] could improve such tests. Interconfiguration transitions in HCIs have a high sensitivity to a variation of α due to large relativistic contributions to their binding energies. Advantageously, they have a strongly suppressed sensitivity to external perturbations [12]. However, interconfiguration transitions quickly shift from the optical laser range into the extreme ultraviolet or x-ray region with increasing charge state [23]. Nonetheless, at level crossings with two or more nearly degenerate electronic configurations, forbidden, and thus narrow, optical transitions with an enhanced sensitivity [1,2] arise. In particular, the Nd-like system Ir 17þ offers narrow lines between three electronic configurations 4f 14 , 4f 13 5s 1 , and 4f 12 5s 2 with the highest ever predicted sensitivity in a stable atomic system [2]. However, calculations for this system are exceptionally difficult, and the predicted energies for intraconfiguration M1 transitions ideally suited for clock applications [6] can exhibit errors on the 10% level, as can be seen below. For interconfiguration transitions, uncertainties at the eV level are expected. Thus, optical line identification becomes extremely difficult.In this Letter, we demonstrate a method to reliably identify transitions in...

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Cryogenic linear Paul trap for cold highly charged ion experiments

Cited by 67 publications

References 65 publications

Cold highly charged ions in a cryogenic Paul trap

Cold highly charged ions in a cryogenic Paul trap

Two-dimensional ion crystals in radio-frequency traps for quantum simulation

Identification of the Predicted5s−4fLevel Crossing Optical Lines with Applications to Metrology and Searches for the Variation of Fundamental Constants

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