Laser Spectroscopy of Pionic Helium Atoms

Overview

Journal Nature

Specialty Science

Date 2020 May 8

PMID 32376962

Citations 5

Authors

Masaki Hori

Hossein Aghai-Khozani

Anna Soter

Andreas Dax

Daniel Barna

Affiliations

Soon will be listed here.

Abstract

Charged pions are the lightest and longest-lived mesons. Mesonic atoms are formed when an orbital electron in an atom is replaced by a negatively charged meson. Laser spectroscopy of these atoms should permit the mass and other properties of the meson to be determined with high precision and could place upper limits on exotic forces involving mesons (as has been done in other experiments on antiprotons). Determining the mass of the π meson in particular could help to place direct experimental constraints on the mass of the muon antineutrino. However, laser excitations of mesonic atoms have not been previously achieved because of the small number of atoms that can be synthesized and their typically short (less than one picosecond) lifetimes against absorption of the mesons into the nuclei. Metastable pionic helium (πHe) is a hypothetical three-body atom composed of a helium-4 nucleus, an electron and a π occupying a Rydberg state of large principal (n ≈ 16) and orbital angular momentum (l ≈ n - 1) quantum numbers. The πHe atom is predicted to have an anomalously long nanosecond-scale lifetime, which could allow laser spectroscopy to be carried out. Its atomic structure is unique owing to the absence of hyperfine interactions between the spin-0 π and the He nucleus. Here we synthesize πHe in a superfluid-helium target and excite the transition (n, l) = (17, 16) → (17, 15) of the π-occupied πHe orbital at a near-infrared resonance frequency of 183,760 gigahertz. The laser initiates electromagnetic cascade processes that end with the nucleus absorbing the π and undergoing fission. The detection of emerging neutron, proton and deuteron fragments signals the laser-induced resonance in the atom, thereby confirming the presence of πHe. This work enables the use of the experimental techniques of quantum optics to study a meson.

Citing Articles

High-resolution laser resonances of antiprotonic helium in superfluid He.

Soter A, Aghai-Khozani H, Barna D, Dax A, Venturelli L, Hori M Nature. 2022; 603(7901):411-415.

PMID: 35296843 PMC: 8930758. DOI: 10.1038/s41586-022-04440-7.

Superfluid confines exotic atoms without disrupting precision measurements.

Matsuo Y Nature. 2022; 603(7901):398-399.

PMID: 35296816 DOI: 10.1038/d41586-022-00688-1.

Laser Spectroscopy Measurements of Metastable Pionic Helium Atoms at Paul Scherrer Institute.

Hori M, Aghai-Khozani H, Soter A, Dax A, Barna D Few Body Syst. 2021; 62(3):63.

PMID: 34720287 PMC: 8550253. DOI: 10.1007/s00601-021-01630-3.

Cold and stable antimatter for fundamental physics.

Yamazaki Y Proc Jpn Acad Ser B Phys Biol Sci. 2021; 96(10):471-501.

PMID: 33390386 PMC: 7859084. DOI: 10.2183/pjab.96.034.

Tuning the quantumness of simple Bose systems: A universal phase diagram.

Kora Y, Boninsegni M, Son D, Zhang S Proc Natl Acad Sci U S A. 2020; 117(44):27231-27237.

PMID: 33087572 PMC: 7959564. DOI: 10.1073/pnas.2017646117.

References

Ahmadi M, Alves B, Baker C, Bertsche W, Butler E, Capra A . Observation of the 1S-2S transition in trapped antihydrogen. Nature. 2016; 541(7638):506-510. DOI: 10.1038/nature21040. View

DiSciacca J, Marshall M, Marable K, Gabrielse G, Ettenauer S, Tardiff E . One-particle measurement of the antiproton magnetic moment. Phys Rev Lett. 2013; 110(13):130801. DOI: 10.1103/PhysRevLett.110.130801. View

Ulmer S, Smorra C, Mooser A, Franke K, Nagahama H, Schneider G . High-precision comparison of the antiproton-to-proton charge-to-mass ratio. Nature. 2015; 524(7564):196-9. DOI: 10.1038/nature14861. View

Korobov V, Hilico L, Karr J . mα(7)-order corrections in the hydrogen molecular ions and antiprotonic helium. Phys Rev Lett. 2014; 112(10):103003. DOI: 10.1103/PhysRevLett.112.103003. View

Hori M, Aghai-Khozani H, Soter A, Barna D, Dax A, Hayano R . Buffer-gas cooling of antiprotonic helium to 1.5 to 1.7 K, and antiproton-to-electron mass ratio. Science. 2016; 354(6312):610-614. DOI: 10.1126/science.aaf6702. View

Hori M, Soter A, Barna D, Dax A, Hayano R, Friedreich S . Two-photon laser spectroscopy of antiprotonic helium and the antiproton-to-electron mass ratio. Nature. 2011; 475(7357):484-8. DOI: 10.1038/nature10260. View

Ficek F, Fadeev P, Flambaum V, Jackson Kimball D, Kozlov M, Stadnik Y . Constraints on Exotic Spin-Dependent Interactions Between Matter and Antimatter from Antiprotonic Helium Spectroscopy. Phys Rev Lett. 2018; 120(18):183002. DOI: 10.1103/PhysRevLett.120.183002. View

Nakamura , Iwasaki , Outa , Hayano , WATANABE , Nagae . Negative-pion trapping by a metastable state in liquid helium. Phys Rev A. 1992; 45(9):6202-6208. DOI: 10.1103/physreva.45.6202. View

Hori M, Eades J, Hayano R, Ishikawa T, Sakaguchi J, Widmann E . Sub-ppm laser spectroscopy of antiprotonic helium and a CPT-violation limit on the antiprotonic charge and mass. Phys Rev Lett. 2001; 87(9):093401. DOI: 10.1103/PhysRevLett.87.093401. View

10.

Biesheuvel J, Karr J, Hilico L, Eikema K, Ubachs W, Koelemeij J . Probing QED and fundamental constants through laser spectroscopy of vibrational transitions in HD(.). Nat Commun. 2016; 7:10385. PMC: 4737800. DOI: 10.1038/ncomms10385. View

11.

Soter A, Todoroki K, Kobayashi T, Barna D, Horvath D, Hori M . Segmented scintillation detectors with silicon photomultiplier readout for measuring antiproton annihilations. Rev Sci Instrum. 2014; 85(2):023302. DOI: 10.1063/1.4863648. View

12.

Martial I, Balembois F, Didierjean J, Georges P . Nd:YAG single-crystal fiber as high peak power amplifier of pulses below one nanosecond. Opt Express. 2011; 19(12):11667-79. DOI: 10.1364/OE.19.011667. View

13.

Hori M, Dax A . Chirp-corrected, nanosecond Ti:sapphire laser with 6 MHz linewidth for spectroscopy of antiprotonic helium. Opt Lett. 2009; 34(8):1273-5. DOI: 10.1364/ol.34.001273. View