dissociative electron attachment
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2022 ◽  
Vol 76 (1) ◽  
Author(s):  
Fabian Schmidt ◽  
Martin Philipp Mues ◽  
Jan Hendrik Bredehöft ◽  
Petra Swiderek

Author(s):  
Nail L. Asfandiarov ◽  
Mars Muftakhov ◽  
Stanislav Anatolievich Pshenichnyuk ◽  
Rustam G. Rakhmeev ◽  
Aleksey Safronov ◽  
...  

2021 ◽  
Vol 75 (12) ◽  
Author(s):  
Fabian Schmidt ◽  
Martin Philipp Mues ◽  
Jan Hendrik Bredehöft ◽  
Petra Swiderek

Abstract Chemical reactions in mixed molecular ices as relevant in the context of astrochemistry can be initiated by electron-molecule interactions. Dissociative electron attachment (DEA) as initiating step is identified from the enhancement of product yields upon irradiation at particular electron energies. Herein, we show that DEA to CO leads to the formation of HCN in mixed CO/$$\hbox {NH}_{{3}}$$ NH 3 ice at electron energies around 11 eV and 16 eV. We propose that this reaction proceeds via insertion of the neutral C fragment into a N–H bond. In the case of CO/$$\hbox {H}_{{2}}$$ H 2 O and CO/$$\hbox {CH}_{{3}}$$ CH 3 OH ices, a resonant enhancement of the yields of HCOOH and $$\hbox {CH}_{{3}}$$ CH 3 OCHO, respectively, is observed around 10 eV. In both ices, both molecular constituents exhibit DEA processes in this energy range so that the energy-dependent product yield alone does not uniquely identify the relevant DEA channel. However, we demonstrate by comparing with earlier results on mixed ices where CO is replaced by $$\hbox {C}_{{2}}\hbox {H}_{{4}}$$ C 2 H 4 that DEA to CO is again responsible for the enhanced product formation. In this case, $$\hbox {O}^{\cdot -}$$ O · - activates $$\hbox {H}_{{2}}$$ H 2 O or $$\hbox {CH}_{{3}}$$ CH 3 OH which leads to the formation of larger products. We thus show that DEA to CO plays an important role in electron-induced syntheses in molecular ices. Graphical abstract


Atoms ◽  
2021 ◽  
Vol 9 (4) ◽  
pp. 77
Author(s):  
Sylwia Ptasinska

Ionizing radiation releases a flood of low-energy electrons that often causes the fragmentation of the molecular species it encounters. Special attention has been paid to the electrons’ contribution to DNA damage via the dissociative electron attachment (DEA) process. Although numerous research groups worldwide have probed these processes in the past, and many significant achievements have been made, some technical challenges have hindered researchers from obtaining a complete picture of DEA. Therefore, this research perspective calls urgently for the implementation of advanced techniques to identify non-charged radicals that form from such a decomposition of gas-phase molecules. Having well-described DEA products offers a promise to benefit society by straddling the boundary between physics, chemistry, and biology, and it brings the tools of atomic and molecular physics to bear on relevant issues of radiation research and medicine.


Author(s):  
A. Mauracher ◽  
H. Schöbel ◽  
S. Haughey ◽  
S.E. Huber ◽  
T.A. Field

2021 ◽  
Author(s):  
Stanislav A. Pshenichnyuk ◽  
Nail' L. Asfandiarov ◽  
Alexander S. Vorob'ev ◽  
Štefan Matejčík

Author(s):  
Stanislav A. Pshenichnyuk ◽  
Nail' L. Asfandiarov ◽  
Alexander S. Vorob'ev ◽  
Štefan Matejčík

2021 ◽  
Vol 22 (14) ◽  
pp. 7676
Author(s):  
Janina Kopyra ◽  
Paulina Wierzbicka ◽  
Adrian Tulwin ◽  
Guillaume Thiam ◽  
Ilko Bald ◽  
...  

In this contribution the dissociative electron attachment to metabolites found in aerobic organisms, namely oxaloacetic and citric acids, was studied both experimentally by means of a crossed-beam setup and theoretically through density functional theory calculations. Prominent negative ion resonances from both compounds are observed peaking below 0.5 eV resulting in intense formation of fragment anions associated with a decomposition of the carboxyl groups. In addition, resonances at higher energies (3–9 eV) are observed exclusively from the decomposition of the oxaloacetic acid. These fragments are generated with considerably smaller intensities. The striking findings of our calculations indicate the different mechanism by which the near 0 eV electron is trapped by the precursor molecule to form the transitory negative ion prior to dissociation. For the oxaloacetic acid, the transitory anion arises from the capture of the electron directly into some valence states, while, for the citric acid, dipole- or multipole-bound states mediate the transition into the valence states. What is also of high importance is that both compounds while undergoing DEA reactions generate highly reactive neutral species that can lead to severe cell damage in a biological environment.


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