Ultraslow radiative cooling of Cn− (<i>n</i> = 3–5)

Bull, James N.; Scholz, Michael S.; Carrascosa, Eduardo; Kristiansson, M. K.; Eklund, Gustav; Najeeb, P. K.; Ruette, N. de; Zettergren, Henning; Schmidt, H. T.; Cederquist, H.; Stockett, Mark H.

doi:10.1063/1.5114678

Cited by 16 publications

(41 citation statements)

References 56 publications

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“…The action spectrum of C − 7 is attributed predominantly to direct photodetachment, and shows a clear Wigner-type threshold behavior above the adiabatic detachment energy [51], similar to the results of Bull et al for C − n (n = 3−5) [28]. However, unlike in the study of Bull et al [28], no significant time-dependent contribution due to depletion of hot-bands was observed for C − 7 (see Fig. 2 and compare with Fig.…”

Section: Action Spectroscopysupporting

confidence: 87%

“…less than a second) with time constant τ 1 ≈ 0.5 s. It is likely that this increase in the photo-action signal is due to recovery of the ground and low-lying vibrational states of the anion, which in turn increases the probability for resonant excitation. A similar effect was previously characterised for C − 5 [28]. The decay in photoaction signal at longer times (τ 2 > 100 s) in Figure 5 is probably associated with the ion beam storage lifetime (≈300 s for C − 11 ), but may have some contribution from further cooling of photo-activated ions that have insufficient vibrational energy to produce neutrals.…”

Section: Action Spectroscopysupporting

confidence: 80%

“…The nascent ions were accelerated to 10 keV (8 keV for C − 7 action spectroscopy measurements), selected according to their mass-to-charge ratio using a bending magnet, and injected into the storage ring [30]. Transport from the source to the ring takes ≈80−100 µs and the 1/e beam storage lifetimes are typically >100 s, limited by loss of ions through collisions with background gas of ∼10 4 H 2 molecules per cm 3 [28,31]. The ions initially stored in the ring have a broad distribution of internal excitations, similar to thermal distributions with temperatures exceeding 1000 K [26].…”

Section: Methodsmentioning

confidence: 99%

“…Infrared radiative cooling was modelled using a SHC model [28]. Briefly, the model utilizes the vibrational density of states ρ computed with the Beyer-Swinehart algorithm and scaled harmonic vibrational mode frequencies ν s calculated at the ωB97X-D//aug-cc-pVTZ level of Density Functional Theory (DFT) in Gaussian 16 [36][37][38].…”

Section: Modelingmentioning

confidence: 99%

“…In a recent study we developed a strategy for probing ultraslow radiative cooling of carbon cluster anions, C − n (n = 3−5) [28]. The strategy involves construction of twodimensional (i.e.…”

Section: Introductionmentioning

confidence: 99%

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Radiative cooling of carbon cluster anions C2n+1− (n = 3–5)

et al. 2020

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Radiative cooling of carbon cluster anions C2n+1− (n = 3–5) is investigated using the cryogenic electrostatic ion storage ring DESIREE. Two different strategies are applied to infer infrared emission on slow (milliseconds to seconds) and ultraslow (seconds to minutes) timescales. Initial cooling of the ions over the millisecond timescale is probed indirectly by monitoring the decay in the yield of spontaneous neutralization by thermionic emission. The observed cooling rates are consistent with a statistical model of thermionic electron emission in competition with infrared photon emission due to vibrational de-excitation. Slower cooling over the seconds to minutes timescale associated with infrared emission from low-frequency vibrational modes is probed using time-dependent action spectroscopy. For C9− and C11−, cooling is evidenced by the time-evolution of the yield of photo-induced neutralization following resonant excitation of electronic transitions near the detachment threshold. The cross-section for resonant photo-excitation is at least two orders of magnitude greater than for direct photodetachment. In contrast, C7− lacks electronic transitions near the detachment threshold. Graphical abstract

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Section: Action Spectroscopysupporting

confidence: 87%

Section: Action Spectroscopysupporting

confidence: 80%

Section: Methodsmentioning

confidence: 99%

Section: Modelingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Radiative cooling of carbon cluster anions C2n+1− (n = 3–5)

et al. 2020

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Thermionic Emission of Negative Ions of Molecules and Small Clusters as a Probe of Low-Energy Attachment

Concina

Bordas

2022

J. Phys. Chem. A

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We have been studying the thermionic emission of negatively charged molecules and small clusters for more than a decade. The kinetic energy released distribution (KERD) of mass-selected negative ions has been measured with a velocity map imaging spectrometer. A comparison of the experimental KERD to detailed balance models provided information on the reverse process, namely, the electron attachment to the parent. The electron attachment to neutral systems (reverse process of the electron emission from anions) is usually described in a simplified way as a single electron capture in the framework of the classical Langevin model. Our measurements show that this approach is insufficient and that, in addition to the capture step, an intramolecular vibrational redistribution (IVR) step should be included. As far as multiply charged anions are concerned, the electron attachment to anions (reverse process of the electron emission from dianions) is strongly affected by the repulsive Coulomb barrier (RCB). Previous studies assumed a pure over-the-barrier process, which is in disagreement with our study. Indeed, electron emission is measured below the RCB, revealing significant thermal tunneling. In the present review, we summarize these works on singly and doubly charged anions in an attempt to present a unified view of the involved processes. It is worth noting that the detailed measurements of KERDs in the very low kinetic energy region (typically around 0.1 eV) have been made possible thanks to electron imaging methods, without which all of this work could never have been done, with time-resolution capabilities allowing the disentangling of direct and delayed electron emission.

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Cascade Infrared Thermal Photon Emission

et al. 2023

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The later stages of cooling of molecules and clusters in the interstellar medium are dominated by emission of vibrational infrared radiation. With the development of cryogenic storage it has become possible to experimentally study these processes. Recent storage ring results demonstrate that intramolecular vibrational redistribution takes place within the cooling process, and an harmonic cascade model has been used to interpret the data. Here we analyze this model and show that the energy distributions and the photon emission rates develop into near-universal functions that can be characterized with only a few parameters, irrespective of the precise vibrational spectra and oscillator strengths of the systems. We show that the photon emission rate and emitted power vary linearly with total excitation energy with a small offset. The time developments of ensemble internal energy distributions are calculated with respect to their first two moments. The excitation energy decreases exponentially with a rate constant which is the average of all k 1→0 Einstein coefficients, and the time development of the variance is also calculated.

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Ultraslow radiative cooling of Cn− (n = 3–5)

Cited by 16 publications

References 56 publications

Radiative cooling of carbon cluster anions C2n+1− (n = 3–5)

Radiative cooling of carbon cluster anions C2n+1− (n = 3–5)

Thermionic Emission of Negative Ions of Molecules and Small Clusters as a Probe of Low-Energy Attachment

Cascade Infrared Thermal Photon Emission

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