Probing QED and fundamental constants through laser spectroscopy of vibrational transitions in HD+

Biesheuvel, J.; Karr, Jean‐Philippe; Hilico, Laurent; Eikema, K.S.E.; Ubachs, Wim; Koelemeij, J.C.J.

doi:10.1038/ncomms10385

Cited by 148 publications

(148 citation statements)

References 31 publications

(68 reference statements)

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“…level, and a test of molecular QED at the level of 2.7 × 10 −4 , which are the most stringent tests performed so far. Second, it allows us to put new bounds on the existence of hypothetical fifth forces, and put new limits on the compactification radius of higher dimensions, as described in detail in [3,4,12]. Third, the result presented here can be used to obtain a new value the proton-to-electron mass ratio with a precision of 2.9 p.p.b.…”

Section: Conclusion Implications and Outlookmentioning

confidence: 87%

“…Note that the specified error (within parentheses) does not include the uncertainty of the fundamental constants used. By far the largest contribution is due to the 4.1 × 10 −10 uncertainty of the 2010 Committee on Data for Science and Technology (CODATA) value of μ [16], which translates to a relative frequency uncertainty of 1.5 × 10 −10 (and an absolute frequency uncertainty of 59 kHz) [12].…”

Section: Calculation Of Ro-vibrational Frequency Transitions In Hd +mentioning

confidence: 99%

“…Third, the result presented here can be used to obtain a new value the proton-to-electron mass ratio with a precision of 2.9 p.p.b. [12], for the first time from molecular spectroscopy as proposed already four decades ago [5].…”

Section: Conclusion Implications and Outlookmentioning

confidence: 99%

“…In this article, we present the result of a high-precision frequency measurement of the ro-vibrational transition (v, L):(0, 2)→ (8,3) in the HD + molecule and compare it with state-of-the-art molecular theory to find excellent agreement. From this comparison, we subsequently derive new constraints on the size of effects due to possible new physics (in the form of hypothetical fifth forces or compactified higher dimensions [3,4,12]) in HD + , and we determine a value of μ for the first time from a molecular system [12].…”

Section: Introductionmentioning

confidence: 99%

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High-precision spectroscopy of the HD+ molecule at the 1-p.p.b. level

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Section: Conclusion Implications and Outlookmentioning

confidence: 87%

Section: Calculation Of Ro-vibrational Frequency Transitions In Hd +mentioning

confidence: 99%

Section: Conclusion Implications and Outlookmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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High-precision spectroscopy of the HD+ molecule at the 1-p.p.b. level

et al. 2016

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High-accuracy deep-UV Ramsey-comb spectroscopy in krypton

Galtier¹,

Altmann²,

Dreissen³

et al. 2016

Appl. Phys. B

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and bound-state QED tests based on precision spectroscopy in atoms, molecules and highly charged ions (see, e.g., [5][6][7][8][9][10]). Moreover, in the pursuit of testing QED ever better, substantial efforts have been made to extract fundamental quantities such as the Rydberg constant R ∞ and the proton charge radius. Both can be obtained from spectroscopy of atomic hydrogen, assuming that QED is sufficiently precise. However, when the CREMA collaboration determined the proton charge radius from spectroscopy in muonic hydrogen (consisting of a proton and a muon), it leads to a considerable (7σ) mismatch with the value extracted from normal (electronic) hydrogen [11][12][13]. This mismatch, known as the proton radius puzzle, remains to be explained and requires more spectroscopic measurements, e.g., in systems other than (muonic) hydrogen. Recent results on muonic deuterium [14] reveal that also the deuteron radius is significantly smaller (7.5 σ) than the radius based on normal deuterium spectroscopy.Interesting candidates for precision spectroscopy to solve this puzzle need to be sufficiently simple for precise theoretical treatment. One example is molecular hydrogen, made possible by recent improvements in theory [15]. Another is He + [16], which can be compared to muonic-He + spectroscopy [13]. The experimental challenge is the short wavelengths required for excitation, which ranges from the deep UV (≈ 200 nm) for H 2 to extreme ultraviolet (XUV, < 60 nm) for He + .Such short wavelengths are typically obtained by frequency upconversion of near-infrared lasers in nonlinear crystals or noble gases. One can use a frequency-comb (FC) laser as the fundamental laser and take advantage of its excellent spectral resolution and pulse peak power, to perform direct frequency-comb spectroscopy (DFCS) [17][18][19]. To achieve sufficient upconversion to the UV or XUV range, several approaches have been investigated. AbstractIn this paper, we present a detailed account of the first precision Ramsey-comb spectroscopy in the deep UV. We excite krypton in an atomic beam using pairs of frequency-comb laser pulses that have been amplified to the millijoule level and upconverted through frequency doubling in BBO crystals. The resulting phase-coherent deep-UV pulses at 212.55 nm are used in the Ramseycomb method to excite the two-photon 4p 6 → 4p 5 5p[1/2] 0 transition. For the 84 Kr isotope, we find a transition frequency of 2829833101679(103) kHz. The fractional accuracy of 3.7 × 10 −11 is 34 times better than previous measurements, and also the isotope shifts are measured with improved accuracy. This demonstration shows the potential of Ramsey-comb excitation for precision spectroscopy at short wavelengths.

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Molecular‐Ion Quantum Technologies

Sinhal

Willitsch

2023

Photonic Quantum Technologies

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Quantum-logic techniques for state preparation, manipulation and non-destructive interrogation are increasingly being adopted for experiments on single molecular ions confined in traps. The ability to control molecular ions on the quantum level via a co-trapped atomic ion offers intriguing possibilities for new experiments in the realms of precision spectroscopy, quantum information processing, cold chemistry and quantum technologies with molecules. The present article gives an overview of the basic experimental methods, recent developments and prospects in this field.

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Probing QED and fundamental constants through laser spectroscopy of vibrational transitions in HD+

Cited by 148 publications

References 31 publications

High-precision spectroscopy of the HD+ molecule at the 1-p.p.b. level

High-precision spectroscopy of the HD+ molecule at the 1-p.p.b. level

High-accuracy deep-UV Ramsey-comb spectroscopy in krypton

Molecular‐Ion Quantum Technologies

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