C
Christopher Gorse
Researcher at Leeds Beckett University
Publications - 121
Citations - 1969
Christopher Gorse is an academic researcher from Leeds Beckett University. The author has contributed to research in topics: Excited state & Boltzmann equation. The author has an hindex of 22, co-authored 119 publications receiving 1768 citations. Previous affiliations of Christopher Gorse include University of New South Wales & University of Exeter.
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Open problems in the physics of volume H/sup -//D/sup -/ sources
TL;DR: In this paper, old and new problems in the physics of magnetic multipole sources for the production of negative H/sup −D/sup -/ ions are presented and discussed.
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Informal interaction in construction progress meetings
Christopher Gorse,Stephen Emmitt +1 more
TL;DR: In this article, the authors used the Bales Interaction Process Analysis (IPA) method to collect data on group interaction and found that socio-emotional interaction is used to express feelings in relation to tasks and serves as the flux that creates and sustains the group's social framework.
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Electron energy distribution functions and second kind collisions
Mario Capitelli,Gianpiero Colonna,O. De Pascale,Christopher Gorse,Khaled Hassouni,Savino Longo +5 more
TL;DR: In this article, the role of second-kind collisions (skc) in affecting the electron energy distribution function (eedf) is discussed in the light of old and new results.
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Plasma kinetics in molecular plasmas and modeling of reentry plasmas
Mario Capitelli,Roberto Celiberto,Gianpiero Colonna,G. D'Ammando,O. De Pascale,Paola Diomede,Fabrizio Esposito,Christopher Gorse,Annarita Laricchiuta,Savino Longo,Lucia Daniela Pietanza,Francesco Taccogna +11 more
TL;DR: In this article, the dependence of elementary process probability on both the vibrational and rotational energy content of the H2 molecule is analyzed for the channels governing the microscopic collisional dynamics in non-equilibrium plasmas, i.e., electron-impact induced resonant processes, vibrational deactivation and dissociation in atom-diatom collisions and atomic recombination at the surface.