7 research outputs found

    Dissociative electron attachment to molecular chlorine

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    We report the study of dissociative electron attachment to molecular chlorine in the energy range of 1 to 20 eV using velocity slice imaging technique. Based on the angular distributions at various electron energies, we identify the partial waves involved in the resonance formation that lead to DEA

    Dissociative electron attachment dynamics of ozone using velocity slice imaging

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    We report the study of dissociative electron attachment to ozone (O3) in the energy range of 1 to 10 eV using velocity slice imaging technique. Based on the momentum images that we obtained for O- and O2 - channels at various electron energies we unravel the molecular dynamics leading to DEA

    Dissociative electron attachment to chlorine dioxide probed by velocity slice imaging

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    We report the study of dissociative electron attachment (DEA) to chlorine dioxide (OClO) in the energy range of 1 to 10 eV using velocity slice imaging technique. DEA to OClO shows Cl-, O-, O2 -, and OCl- as fragment channels at various electron energies. Based on the momentum images of these ions we unravel the molecular dynamics leading to DEA

    Probing the resonant states of Cl2 using velocity slice imaging

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    The negative ion resonances in molecular chlorine are probed using velocity slice imaging of the Cl- fragment produced in dissociative electron attachment (DEA). The capability of the velocity slice imaging to cover the entire 360° allows us to obtain clear evidence for the presence of the 2∑u+resonance in the 2.5 eV DEA peak along with the presence of The resonance is expected to be the contributor only to the 0 eV DEA peak. Its presence in the 2.5 eV DEA peak calls for a relook at the theoretical calculations which have not identified any resonance in the 2.5 eV peak. We also identify the presence of the and resonances in the 5.6 eV peak. The momentum images indicate no signature of a resonant contribution in the dipolar dissociation region up to 80 eV
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