Abstract
Low-energy electrons are the most abundant product of ionizing radiation in condensed matter. The origin of these electrons is most commonly understood to be secondary electrons1 ionized from core or valence levels by incident radiation and slowed by multiple inelastic scattering events. Here, we investigate the production of low-energy electrons in amorphous medium-sized water clusters, which simulate water molecules in an aqueous environment. We identify a hitherto unrecognized extra source of low-energy electrons produced by a non-local autoionization process called intermolecular coulombic decay2 (ICD). The unequivocal signature of this process is observed in coincidence measurements of low-energy electrons and photoelectrons generated from inner-valence states with vacuum-ultraviolet light. As ICD is expected to take place universally in weakly bound aggregates containing light atoms between carbon and neon in the periodic table2,3, these results could have implications for our understanding of ionization damage in living tissues.
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Main
Electronic vacancy states can be produced in matter by ionizing radiation, such as X-ray photons or fast charged particles. When a state with a high electronic excitation energy has been produced by impact of such particles, electron correlation can cause the ejection of electrons. Auger decay is the best known representative of this class of secondary processes that is more generally termed autoionization. In the case of Auger decay, a vacancy in an inner shell is filled by a transition involving electrons of lower binding energy at the same atom. For extended systems of weakly bound constituents, such as van-der-Waals or hydrogen-bonded clusters, Cederbaum et al. 2 have found that a different mechanism pertains. They predicted that in such systems electron correlation can effect an Auger-like autoionization transition in which valence electrons on neighbouring sites participate. In other words, the mechanism is a concerted transition in which a single hole in an inner shell is replaced by two vacancies in the outer valence shells of two adjacent molecules, and a free electron. This decay channel was termed intermolecular (interatomic, in the case of atomic clusters) coulombic decay and was subsequently observed in rare-gas clusters4,5,6,7. The process is shown schematically in Fig. 1. A resonant variant of ICD, which may take place after photoexcitation into an unoccupied orbital, has also been discussed7,8,9. Here, we consider ICD of inner-valence vacancy states, for which case the ejected electrons have a low kinetic energy.
On the basis of energetic considerations, ICD can take place whenever the binding energy of the ionized state lies above the double-ionization threshold of the corresponding cluster or liquid. This prerequisite for ICD is fulfilled in hydrogen-bonded systems2,10, but so far the process has not been seen. Calculations of the energy spectrum of electrons ejected by ICD of small water clusters give a hint as to why it has escaped observation: a broad, rather unstructured distribution of energies is expected, which peaks at 0 eV (ref. 10). If we consider an experiment with a conventional electron energy analyser on a bulk or liquid sample, an electron spectrum with this shape can hardly be distinguished from the ‘universal curve’1 for secondary electrons (Fig. 2). In this respect our work differs from earlier experiments, which were either restricted to dimers5,6,7, or dealt with simpler cases where an ICD feature appears from simple electron kinetic energy spectra4,8,9. Producing primary electrons of a well-defined energy by photoionization and detecting them in coincidence with the ICD electron has enabled us to overcome the aforementioned problem. Here, we demonstrate that ICD follows the photoionization of medium-sized water clusters and show that—above the corresponding photoionization threshold—ICD electrons make an important contribution to the low-kinetic-energy spectrum.
In our experiment, a jet of water clusters with a mean size 〈N〉 of 40 and 200 was used. Such clusters are believed to form amorphous structures, which resemble the hydrogen-bonded network of liquid water rather than that of crystalline ice11. Inner-valence vacancies were produced by photoionization using synchrotron radiation. The complete non-coincident photoelectron spectrum of water clusters, recorded in a separate experiment with a hemispherical electron energy analyser12, is shown in Fig. 2. It is similar to that of liquid water recorded previously13. At the excitation energy range covered in this work the ICD process can take place for the 2a1 inner-valence vacancy states, which are mainly derived from the O 2s orbitals.
As described above, it is necessary to record simultaneously both electrons involved to show that ICD actually occurs. For this coincidence experiment we have used a so-called magnetic bottle time-of-flight electron spectrometer, which is well suited for this purpose owing to its large acceptance angle and good transmission for electrons down to very low kinetic energies (see the Methods section). In the lower right panel of Fig. 3, we show the yield of electron pairs (e1,e2) recorded in a coincidence experiment at a photon energy of 45 eV. The kinetic energy of the higher-energy electron e1 increases along the vertical axis; that of the lower-energy electron e2 along the horizontal axis. Correlating the energies along the e1 axis with Fig. 2, we can see which parts of the spectrum are characterized by strong emission of very low-energy electrons. We observe in particular the feature between the two red lines in the figure: these pairs consist of an e1 electron with a kinetic energy corresponding to inner-valence photoionization and an e2 electron, with a very low kinetic energy. The energy spectrum of all e2 electrons detected in coincidence with an inner-valence electron e1, within the energy interval marked by the red bars in Fig. 3, is shown in the top panel. It consists of a convolution of the singly ionized states with binding energies in the range of 28–35 eV (ref. 10) with all available two-hole final states. The resulting intensity profile decreases from zero towards higher kinetic energy and has similarly been found in calculations10 for water clusters up to the tetramer. In analogy to earlier experiments on rare-gas clusters4,5,6,7, we identify this autoionization process with intermolecular coulombic decay. As expected, the respective feature is not observed for a beam consisting purely of water monomers (see Supplementary Fig. S1). We can further confirm the assignment by following the photon energy dependence: the e1 energy of the ICD feature should vary linearly with photon energy, whereas the e2 energy remains constant. Exactly this behaviour is observed in Fig. 4, which shows the results of coincidence experiments at photon energies of 45, 60 and 80 eV.
The doubly charged final states, which are populated by the ICD process, can be inferred from a plot of the electron coincidence intensities as a function of final two-hole-state energy (Fig. 3, green curve). This curve is obtained by integrating along lines of constant total energy, which are diagonals in the main panel parallel to the green line. This line itself marks the minimum final-state energy expected, namely 22.1 eV corresponding to twice the highest occupied molecular orbital ionization potential of a large water cluster12. As the final-state spectrum is composed of numerous combinations of outer-valence single vacancies10, and is further broadened by summation over different cluster geometries, a broadened double-ionization spectrum between 23 and 36 eV is observed. These final-state energies correspond to the production of two outer-valence vacancies, mostly as a result of ICD. The intensity of the electron coincidences (green curve) at higher binding energies is partly due to direct photo-double-ionization of uncondensed molecules in the jet, which can result in the creation of molecular dicationic states with up to 47 eV binding energy14. Intra cluster scattering processes also make a minor contribution to the electron-pair intensities in Figs 3 and 4. Further details in connection with these figures, such as subtraction of random coincidences, are discussed in the Methods section and Supplementary Information.
The above analysis was made under the assumption that no nuclear relaxation occurs during ICD. The timescale of this process has been investigated experimentally5,15 and by calculations3,16 for a number of systems, including water clusters10. Transition times in the femtosecond range have been found. This is even faster than the proton rearrangement associated with the ionization of water17. Autoionization through ICD therefore will dominate over alternative relaxation channels, such as fluorescence or nuclear rearrangement. For Ne clusters, 100% efficiency of ICD for the relaxation of 2s vacancies has been demonstrated18.
We will now briefly comment on the possible impact of these results. It is well known that even low doses of ionizing radiation can lead to cell damage in living matter, and that such events primarily are caused by double-strand breaks in the DNA involved19,20. The mechanisms that lead from absorption of the radiation energy to double-strand breaks are far from understood. One possible process is the chemical attack by OH radicals resulting from the radiolysis of water19,20. Recently the potential importance of low-kinetic-energy electrons has been recognized21,22, as it was found that they can efficiently induce DNA strand breaks by dissociative attachment23,24,25. These results have now been confirmed in humid air, thus resembling more closely conditions in the cell26. As electron attachment can be promoted by so-called shape resonances, there is practically no lower limit for the electron energy at which an interaction with DNA ceases to occur27,28. Intermolecular coulombic decay provides a production mechanism for low-kinetic-energy electrons not considered previously. For primary ionization with large impact energy, it differs from other mechanisms, such as multiple inelastic scattering of high-kinetic-energy photoelectrons, by the fact that the ICD electron is produced immediately at the site of ionization. Quantitatively, for vacuum-ultraviolet photon energies, an upper limit for the amount of slow electrons expected from ICD is given by the relative inner-valence photoionization cross-section, which is 18% for h ν=80 eV (ref. 13) and could be higher near threshold. For higher primary energies, ICD can also occur as part of a cascade process following normal Auger decay6. Although it is difficult to assess the number of resulting ICD electrons as a fraction of the ‘true’ secondaries (largely because of the problem of quantifying the latter), their contribution is clearly important.
Another aspect contributing to the relevance of ICD is the production of two positively charged ions in its final state. For our system, their nuclear Coulomb repulsion energy, calculated at the original water–water bond length10, is around 4.9 eV. This will lead to a Coulomb explosion in a small system, and to structural changes at the site of ICD in larger aggregates.
Finally, we see important perspectives in the study of ICD in inhomogeneous systems such as, for example, chemical systems; DNA itself might participate in such a process.
Note added in proof: The Coulomb explosion of water dimers after ICD has very recently been independently observed29.
Methods
Cluster production.
Clusters were produced by supersonic expansion of water vapour from a heated reservoir inside the vacuum chamber. Data specific to our instrument are: conical copper nozzle, diameter 80 μm, length 1.1 mm, half opening angle 15∘. The expansion chamber and main chamber are pumped by two 210 l s−1 and one 1,000 l s−1 turbopumps, respectively, and are separated by a conical skimmer of 1 mm diameter. Background pressure in the main chamber was kept below 10−5 mbar. The cluster size was estimated from the empirical formula given in ref. 30. Cluster formation was monitored by recording the highest occupied molecular orbital photoelectron peaks of water monomers and clusters at 14 eV photon energy12.
Electron detection.
The magnetic bottle spectrometer we have used features an adaptation of an earlier design31 to experiments with the bunch period of BESSY II, which is 800 ns. We have therefore shortened the drift tube to 60 cm. The guiding field is produced by a coil of Kapton-insulated cable wound around the drift tube inside the vacuum. The anisotropic field near the interaction region is produced by a permanent magnet, generating a magnetic field strength of approximately 0.4 T. Backscattering of electrons from the magnet surface is prevented by a mesh in front of the magnet to which a positive bias voltage was applied. Electrons with kinetic energies down to 100 meV were detected without loss of transmission, which was verified by recording He 1s photoelectron spectra with photon energies down to the ionization threshold. A small accelerating field (1.2 V) along the interaction region was used to achieve a time-of-flight of the slowest electrons below 800 ns.
The complete non-coincident valence photoelectron spectrum shown in Fig. 2 was recorded in a separate experiment, which is described elsewhere12. Briefly, a conventional hemispherical analyser was used to record photoelectrons emitted under the magic angle with respect to the polarization direction of the light, and in the plane perpendicular to its propagation direction. A pass energy of 20 eV was used. Although we have not quantified it, we expect that under these conditions the transmission function of the analyser leads to a decrease in the detection efficiency for electrons with kinetic energies below about 8 eV. A quantitative comparison of Fig. 2 to the low-kinetic-energy-electron spectra acquired with the magnetic bottle spectrometer is hampered by this problem.
Synchrotron radiation.
Experiments were carried out at the undulator beamline UE 112-low energy-PGMa at the synchrotron radiation source BESSY II (Berlin, Germany), operating in single-bunch mode. The light polarization was chosen as horizontally linear, that is, perpendicular to the cluster beam and within the plane spanned by the photon beam and the central axis of the magnetic bottle spectrometer.
Data acquisition and analysis.
Event-based data acquisition was carried out with a multi-hit capable time-to-digital converter of 60 ps bin width (GPTA). The electron flight times were transformed into kinetic energies according to calibration data obtained from He 1s photoelectron spectra. The amount of random coincidences was estimated from electron pairs produced by two different, subsequent synchrotron radiation pulses, and was subtracted. In Fig. 3, additionally a background of coincident electron pairs of apparative origin was subtracted. This background consists mainly of electron pairs with a total kinetic energy below 10 eV, and was estimated from a spectrum of gaseous He recorded at 44.7 eV, which was scaled with the ratio of outer-valence photoelectron intensities. No such subtraction has been carried out in Fig. 4 to highlight the fact that the background in this energy region is essentially constant in shape.
Typical acquisition times were 1,000 s per panel. In this period, for Fig. 3 about 11 million total events were registered, which could be condensed to 366,000 true coincidence events, after background subtraction. These figures are typical for the other spectra as well. The coincidence electron spectra in the three panels of Fig. 4 were normalized to equal maximum intensity.
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Acknowledgements
U.H. would like to acknowledge useful discussions with B. Winter. Financial support by the Deutsche Forschungsgemeinschaft, the Fonds der Chemischen Industrie and the Advanced Study Group of the Max-Planck-Society is gratefully acknowledged.
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U.H. conceived the experiment, S.B. and V.U. constructed the cluster source, M.B. and U.B. constructed the spectrometer, M.M., M.B., S.B., M.F., T.L. and U.H. carried out the experiment and M.M. and U.H. analysed the data; all authors discussed the results and contributed to writing of the manuscript.
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Mucke, M., Braune, M., Barth, S. et al. A hitherto unrecognized source of low-energy electrons in water. Nature Phys 6, 143–146 (2010). https://doi.org/10.1038/nphys1500
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DOI: https://doi.org/10.1038/nphys1500
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