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Observation of a shape resonance of the positronium negative ion

Nature Communications volume 7, Article number: 11060 (2016) | Download Citation

Abstract

When an electron binds to its anti-matter counterpart, the positron, it forms the exotic atom positronium (Ps). Ps can further bind to another electron to form the positronium negative ion, Ps (ee+e). Since its constituents are solely point-like particles with the same mass, this system provides an excellent testing ground for the three-body problem in quantum mechanics. While theoretical works on its energy level and dynamics have been performed extensively, experimental investigations of its characteristics have been hampered by the weak ion yield and short annihilation lifetime. Here we report on the laser spectroscopy study of Ps, using a source of efficiently produced ions, generated from the bombardment of slow positrons onto a Na-coated W surface. A strong shape resonance of 1Po symmetry has been observed near the Ps (n=2) formation threshold. The resonance energy and width measured are in good agreement with the result of three-body calculations.

Introduction

The three-body problem with a Coulomb interaction has been the focus of attention in fundamental physics for not only classical mechanics but also quantum mechanics, since the Schrödinger equation for a three-body system has not been solved analytically, despite the proposal of a variety of approximation approaches. The Ps ion1,2 can be regarded, from an atomic and molecular physics perspective, as an intermediate between the two extreme cases of H (atomic-like) and H2+ (molecular-like) because of its mass ratio3,4,5. Since the theoretical simplifications applied to atoms or molecules may often be inadequate, research on Ps structure and dynamics can provide a stringent testing ground for the quantum mechanical three-body problem.

Theoretical studies indicate that Ps has only a ground state (1Se) where the two electrons have opposite spins, and no particle-stable excited states6,7, unlike the H ion, which has a doubly excited 3Pe state. However, quasi-bound states (resonances) have been theoretically predicted in the vicinity of the formation thresholds of Ps (for principal quantum number n≥2) (ref. 8), offering the expectation that experiments will reveal rich structures around the energy levels of Ps. Although the resonance states spontaneously dissociate into Ps in the ground state or lower-lying excited state and electron in the continuum, interference between the direct detachment process and the detachment via the resonance state gives rise to characteristic structures on the cross sections near the resonance energy. The resonance of the 1Po symmetry, which is accessible by the single-photon absorption of Ps, has been theoretically investigated9,10,11,12,13. In the vicinity of the n=2 threshold, a strong shape resonance, in which the electron is temporarily trapped by a centrifugal barrier potential, is thought to lie above the level. Moreover, a series of Feshbach resonances, which originates from an attractive dipole potential formed by the 2S−2P degeneracy of Ps (n=2), is also expected to lie just below this threshold.

Historically, the existence of Ps was predicted by Wheeler1 in 1946 and was discovered in the laboratory, using the beam-foil method, by Mills2 in 1981. Since then numerous theoretical studies have been devoted to exploring the nature of this exotic ion14,15,16,17,18,19,20,21,22,23. However, because of the extremely weak ion yield and short annihilation lifetime (479 ps), experimental investigations on Ps have been limited to a few measurements of its annihilation rate (ref. 24 and references therein). Recently, an efficient formation method for this ion was found where, on impacting slow positron beams onto tungsten (W) surfaces coated with sub-monolayer alkali-metal atoms, the conversion efficiency increased by double digits due to the coating25,26,27. This discovery has opened up new experimental fields for Ps, such as its photodetachment28 and the consequent generation of an energy-tunable Ps beam29.

In this letter, we report on a study of its kind made on the laser spectroscopy of Ps ions, generated by this efficient production scheme. We report the observation of a strong shape resonance of 1Po near the Ps (n=2) formation threshold. The resonance energy and width measured are in good agreement with the result of three-body calculations.

Result

Experimental setup and procedure

A pulsed slow positron beam at the KEK-IMSS slow positron facility30 was used to synchronize the Ps beam and a pulsed ultraviolet laser beam of sufficient photon density for the photodetachment of the short-lived Ps ions. The positron beam, with a repetition of 50 Hz and pulse-width of 12 ns FWHM, was transported to the measurement chamber with a kinetic energy of 4.2 keV, passing through a plate with a 5 mm circular aperture. The beam intensity and the diameter were 4 × 103 e+ per pulse and 4 mm FWHM, respectively. As shown in Fig. 1a, it was deflected by an angle of 45° along a curved magnetic field (0.01 T), then passed through forward and back grids biased at the same voltage of 3,400 V and, finally, impacted onto a W target coated with a 0.3 monolayer of Na (Supplementary Note 1). In order to maintain Ps emission from the surface26 for the duration of the runs, the chamber was evacuated to a pressure of 1 × 10−8 Pa.

Figure 1: Schematic diagram of the experimental setup and the energy levels of Ps.
Figure 1

(a) A pulsed slow positron beam is guided along a magnetic field and impacted onto a Na-coated W target to generate Ps ions. The ions are accelerated by a static electric field between the target and a back grid, and are then irradiated by ultraviolet laser beam in the electric field-free region between the forward and back grids biased at the same voltage. The neutral Ps atoms formed by (resonant) photodetachment are detected by the MCP. (b) Optical transition from Ps (1Se) to Ps (n=1 or 2) +e continuum state via shape resonance (1Po) as indicated by Ps−*.

When positrons impinge onto a surface, they can lose their kinetic energies and thermalize in the bulk. Some diffuse back to the surface to form Ps ions, and these are emitted spontaneously with a low kinetic energy governed by the Ps affinity (−3 eV). The formation efficiency of Ps ions against the incident positron flux is reported to be about 2% (ref. 26). The Ps ions formed in this setup were accelerated by the potential difference, V, between the target and back grid. The potential of the target was varied to set the value of V. The ions intersected the laser beams from a tunable dye laser (see the ‘Methods’ section for details on the laser system) at right angle in the electric field-free region between the two grids. The effects of stray magnetic fields in the beam intersection region were considered: for a field of about 3 × 10−3 T with a Ps speed of 0.07c (V=3,400 V), where c is the speed of light, the effective electric field was estimated to be 6 × 102 V cm−1. Motional Stark-broadening and shift of resonance energies are small enough to be neglected at this field strength31,32.

Neutral Ps atoms formed both by the direct photodetachment process and via the resonances (Fig. 1b) were detected by a micro-channel plate (MCP), of effective diameter 42 mm, while charged particles were removed by the curved magnetic field. The residual background was due to stray light, reflected from the laser inlet and outlet fused-silica windows coated by broadband anti-reflection coatings and annihilation γ-rays from the target. In order to reduce the MCP signal due to the stray light, baffles and cylindrical tubes with 5 mm diameter apertures were placed between the target and each window.

Para-Ps (S=0) and ortho-Ps (S=1) are formed in the Ps photodetachment process. As for the S-states, para-Ps atoms decay with a lifetime of 125n3 ps into two γ-rays, while ortho-Ps atoms decay with a lifetime of 142n3 ns into three γ-rays. The 2P-states, which have longer lifetimes against annihilation (0.1–3 ms) (refs 33, 34), are de-excited to 1S-states with a lifetime of 3.2 ns and these then decay according to their own annihilation lifetimes. Owing to the short flight length (<20 mm) of para-Ps atoms, even in the n=2 state, due to self-annihilation, only ortho-Ps atoms were detected by the MCP which was placed at a distance, L, of 0.88 m from the target. Although the m=0 states of ortho-Ps atoms are perturbed and its lifetime becomes shorter by Zeeman mixing with para-Ps atoms in a magnetic field, this effect is negligibly small, even in the Ps (n=2) state at the present field strength35.

Observation

Figure 2 shows the 2D time-of-flight (TOF) spectra of the MCP signals at two different laser wavelengths for V=3,400 V, accumulated over 2 × 103 s. The prompt peaks seen at time t=0–10 ns are attributed mainly to the detection of stray light. Annihilation γ-rays of the positrons in the target and self-annihilation of para-Ps also contribute to these peaks. No significant signal is observed at the laser wavelength 229.7 nm, a delayed peak is seen at t=44 ns when the wavelength is tuned to 228.5 nm. The TOF is consistent with that of Ps atoms formed by photodetachment, given by , where e and me are the charge and the rest mass of the electron, respectively.

Figure 2: 2D time-of-flight spectra of the MCP signals.
Figure 2

The wavelengths of the laser beams were 228.5 nm (a) and 229.7 nm (b). The bottom sections are the vertical projections of the spectra with pulse height over 18 mV. When λ=228.5 nm, delayed signals from the detection of Ps atoms formed by photodetachment are observed at t=44 ns, while these signals are not observed for λ=229.7 nm.

The count rate of the Ps atoms, RPs, was determined using RPs=RPLRPRL, where RPL and RP are the signal rates with and without the laser irradiation, respectively, for the TOF windows of 40–50 ns (V=3,400 V) and 62–72 ns (V=1,500 V). RL is the background rate due to the laser irradiation. RPs was normalized to the average photon flux and the overlapping volume of the laser beam and the Ps beam estimated from each spatial and temporal profile to ensure proportionality to the photodetachment cross sections (Supplementary Figs 1 and 2, and Supplementary Note 2). Figure 3 shows RPs measured as a function of the wavelength from 225 nm (5.51 eV) to 231 nm (5.37 eV) for V=3,400 V and V=1,500 V. Asymmetric peaks with a tail to higher photon energies were clearly observed in both cases.

Figure 3: Resonance profiles of Ps ions in the vicinity of the n=2 threshold.
Figure 3

RPs plotted against photon energy for acceleration voltages of 3,400 V (a) and 1,500 V (b). The best fit results using a Fano profile convoluted with a Gaussian profile which represents the angular distribution of Ps are indicated by the solid lines, where the fitting parameters, except for the resonance energy, were constrained to be the same for both sets of data (χ2/v=0.66). Error bars show the standard deviation of the mean RPs values including the error of normalization factors.

Discussion

The photodetachment cross sections, σ(hv), near resonances with energy Er and width Γ are often described by the Fano line profile36,

where

Here, σa and σb are the cross sections of continuum states interacting with and without the resonance state, respectively, and q is the shape parameter. It has been reported that the Fano profile describes the shape resonances (1Po) of H and D (refs 37, 38), and was applied to molecular shape resonances39. The data obtained were fitted with this profile, as shown in Fig. 3a,b, where the fitting parameters, except for Er, were kept the same for both cases. σb was assumed to be constant. In the laboratory frame, because of the Ps motion perpendicular to the average Ps velocity vz, transverse Doppler-broadening takes place. Accordingly, a Gaussian profile with s.d.=1.3 × 10−3hv, obtained in a previous measurement40, has been convoluted to the fitting profile. The values of Er derived by the fitting were 5.4246(12) eV (V=3,400 V) and 5.4317(16) eV (V=1,500 V), where the errors represent the s.d. of the fitted values. It is clearly seen that each resonance position shifts with V, due to the longitudinal Doppler effect expressed as . The zero-velocity values of each Er extracted from this formula, 5.4367(12) eV (V=3,400 V) and 5.4370(16) eV (V=1,500 V), are consistent within the s.d. Therefore the resonance energy in the rest frame of the ions was deduced to be 5.437(1) eV from the weighted arithmetic mean of these values. Er and the other fitting parameters are listed in Table 1, along with theoretically derived values of the shape resonance by the adiabatic treatment9, the complex rotation method10 and the hyperspherical close-coupling method12. The obtained Er and Γ values are in good agreement with the theoretical predictions to within meV precision. The shape parameter q is also consistent with the theoretical value obtained by fitting the Fano profile to the photodetachment cross sections in the (ref. 12).

Table 1: Comparison of experimental and theoretical results for the 1Po shape resonance in the vicinity of the n=2 threshold.

In conclusion, we have developed an experimental system for Ps laser spectroscopy based on an efficient Ps source. We have observed the 1Po shape resonance in the photodetachment of Ps ions near the n=2 threshold. The present experimental resolution is constrained by the Doppler width of about 7 meV due to the Ps motion. With a combination of the present Ps production system and the two-photon absorption technique, in which the Ps ions are irradiated with two counter-propagating laser beams to cancel the Doppler shift, the observation of the narrower Feshbach resonances8,41,42 will be feasible. This precise spectroscopy will be the next challenge for future research.

Methods

Laser system

The light source was based on a nano-second dye laser (Sirah, Cobra-Stretch-D; dye solution: Coumarin 460) pumped by the third harmonic of a Q-switched Nd:YAG laser with a repetition of 10 Hz. In order to extend the dye lifetime, DABCO (1, 4-diazabicyclo [2.2.2] octane) was dissolved in the dye solution at 1 g l−1 (ref. 43), thereby, almost tripling the lifetime. The outputs were converted to the second harmonics by a type I BBO crystal, resulting in a wavelength range of 225–230 nm with a nominal linewidth of about 0.4 pm (9 μeV). The wavelength was measured using a wavelength metre (HighFinesse, WS-6). The average pulse-width of the output pulses was about 10 ns FWHM, and the average energy was measured to be several 10−4 J by an energy metre (Coherent, J-25MUV-193). The spatial and temporal profiles of the laser beam were continuously monitored by a beam profiler (Thorlabs, BC106-UV) and a photodiode (Thorlabs, DET10A/M), respectively. The polarization of the light was set to be parallel to the Ps velocity vector.

Data acquisition

The waveforms of the MCP signals were recorded by a digitizer with a 10-bit resolution (National instruments, PXIe-5162). The sampling rate and the band width were 1.25 GS s−1 and 1.5 GHz, respectively. The characteristic properties of the laser beam (wavelength, energy, spatial profile and temporal profile) were recorded in synchronization with the digitizer. Data, with and without laser, were recorded with the repetition ratio of positrons (50 Hz) and laser (10 Hz).

Effect of positronium atoms in n=2 excited states

For the measurement of the resonance profile, presented in Fig. 3a,b, above the n=2 threshold (5.428 eV), Ps in the n=2 state is formed in competition with the n=1 state. As for the 23P states, they are de-excited to the 13S state (Lyman-α transition) within a lifetime of 3.2 ns before reaching the MCP detector, while most of the Ps in the metastable 23S state can reach the detector without in-flight loss since the annihilation lifetime of this state is ten times longer than that of the 13S state and de-excitation is forbidden. The detection efficiencies of the 23S state are thus 1.3 times and 1.5 times higher than those of the other states for acceleration voltages of 3,400 and 1,500 V, respectively. To evaluate this contribution, we multiplied these ratios by 2S partial photodetachment cross sections calculated by the HSCC method12 and compared them with the total photodetachment cross sections with and without the multiplication. We found a shift of resonance energy of only 0.2 meV when it was taken into account, therefore this effect was disregarded.

Additional information

How to cite this article: Michishio, K. et al. Observation of a shape resonance of the positronium negative ion. Nat. Commun. 7:11060 doi: 10.1038/ncomms11060 (2016).

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Acknowledgements

We thank Akinori Igarashi for helpful discussion and providing calculated values. We also thank the staff of the Photon Factory and the Accelerator Laboratory of KEK for their support. This work was conducted under the approval of the Photon Factory Program Advisory Committee (Proposal No. 2013S2-005). It was supported by JSPS KAKENHI Grant Numbers 24221006 and 25887046. T.K. is financially supported by MATSUO FOUNDATION.

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Affiliations

  1. Department of Physics, Tokyo University of Science, 1-3 Kagurazaka, Shinjuku, Tokyo 162-8601, Japan

    • Koji Michishio
    •  & Yasuyuki Nagashima
  2. Atomic, Molecular and Optical Physics Laboratory, RIKEN, 2-1 Hirosawa, Wako, Saitama 351-0198, Japan

    • Tsuneto Kanai
    • , Susumu Kuma
    •  & Toshiyuki Azuma
  3. Institute of Materials Structure Science, High Energy Accelerator Research Organization (KEK), 1-1 Oho, Tsukuba, Ibaraki 305-0801, Japan

    • Ken Wada
    • , Izumi Mochizuki
    • , Toshio Hyodo
    •  & Akira Yagishita

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Contributions

K.M. designed the apparatus and carried out the measurements with S.K. and T.K. The laser system was developed by T.K. The data was analysed by K.M. and S.K. K.W., I.M., A.Y. and T.H. provided the support on the slow positron beam line. Y.N. and T.A. proposed and supervised the experiment. The manuscript was prepared by K.M., S.K., T.A. and Y.N. and then discussed with all authors.

Competing interests

The authors declare no competing financial interests.

Corresponding author

Correspondence to Koji Michishio.

Supplementary information

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    Supplementary

    Supplementary Figures 1-2, Supplementary Notes 1-2 and Supplementary References.

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