Publications

- Franz Xaver Bronold -

[63]
M. Pamperin, F.X. Bronold, and H. Fehske, submitted (2017), arXiv:1704.00942
Electron emission by auto-detachment in collisions of He+ ions with metal surfaces
[62]
F.X. Bronold and H. Fehske, J. Phys. D: Appl. Phys. 50, 294003 (2017)
Kinetic modeling of the electronic response of a dielectric plasma-facing solid
[61]
F.X. Bronold and H. Fehske, Plasma Phys. Contol. Fusion 59, 014011 (2017)
Microscopic theory of electron absorption by plasma-facing surfaces
[60]
E. Thiessen, R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. A 93, 033827 (2016)
Surface mode hybridization in the optical response of core-shell particles
[59]
F.X. Bronold and H. Fehske, Phys. Rev. Lett. 115, 225001 (2015)
Absorption of an electron by a dielectric wall
[58]
E. Thiessen, F.X. Bronold, R.L. Heinisch, and H. Fehske, Phys. Rev. A 91, 043837 (2015)
Scattering of infrared light by dielectric core-shell particles
[57]
M. Pamperin, F.X. Bronold, and H. Fehske, Phys. Rev. B 91, 035440 (2015)
Many-body theory of the neutralization of strontium ions on gold surfaces
[56]
M. Pamperin, F.X. Bronold, and H. Fehske, Phys. Scr. T165, 014008 (2015)
Mixed-valence correlations in charge-transferring atom-surface collisions
[55]
B. Zenker, D. Ihle, F. X. Bronold, and H. Fehske, Journal of Physics: Conf. Series 529, 012030 (2014)
Exciton formation in strongly correlated electron-hole systems near the semimetal-semiconductor transition
[54]
R. L. Heinisch, F.X. Bronold, and H. Fehske in Complex Plasmas: Scientific Challenges and Technological Opportunities
Editors: M. Bonitz, K. Becker, J. Lopez and H. Thomsen
Springer Series on Atomic, Optical, and Plasma Physics 82, 267-298, Springer-Verlag Berlin Heidelberg (2014)
Surface electrons at plasma walls
[53]
E. Thiessen, R.L. Heinisch, F.X. Bronold, and H. Fehske, Eur. Phys. J. D 68, 98 (2014)
Infrared light extinction by charged dielectric core-coat particles
[52]
H. Deutsch, F.X. Bronold, and H. Becker, Int. J. Mass Spectrometry 365, 128 (2014)
Calculation of electron-impact ionization cross sections: Bottum-up inductive vs. top-down deductive approaches
[51]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. E 88, 023109 (2013)
Optical signatures of the charge of a dielectric particle in a plasma
[50]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. B 87, 155409 (2013)
Mie scattering analog in graphene: lensing, particle confinement, and depletion of Klein tunneling
[49]
F.X. Bronold and H. Fehske in Non-thermal plasma chemistry and physics
Taylor and Francis Group, Boca Raton (2013), Sect. 9.2
Editors: M. Schmidt, J. Meichsner, R. Schneider, and H.-E. Wagner
Elementary processes in gas discharges
[48]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. Lett. 109, 243903 (2012)
Mie scattering by a charged dielectric particle
[47]
J. Marbach, F.X. Bronold, and H. Fehske, Phys. Rev. B 86, 115417 (2012)
Pseudo-particle approach for charge-transferring molecule-surface collisions
[46]
F.X. Bronold, H. Fehske, R.L. Heinisch, J. Marbach, Contrib. Plasma Phys. 52, 856 (2012)
Wall charge and potential from a microscopic point of view
[45]
J. Marbach, F.X. Bronold, and H. Fehske, Eur. Phys. J. D 66, 106 (2012)
Resonant charge transfer at dielectric surfaces
[44]
B. Zenker, D. Ihle, F.X. Bronold, and H. Fehske, Phys. Rev. B 85, 121102R (2012)
Electron-hole pair condensation at the semimetal-semiconductor transition: A BCS-BEC crossover scenario
[43]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. B 85 075323 (2012)
Electron surface layer at the interface of a plasma and a dielectric wall
[42]
J. Marbach, F.X. Bronold, and H. Fehske, Phys. Rev. B 84, 085443 (2011)
Auger de-excitation of metastable molecules at metallic surfaces
[41]
J. Marbach, F.X. Bronold, and H. Fehske, accepted contribution to the ICPIC 2011; arXiv:1109.0845
Secondary electron emission due to Auger de-excitation of metastable nitrogen molecules at metallic surfaces
[40]
R.L. Heinisch, F.X. Bronold, and H. Fehske, accepted contribution to the ICPIC 2011
Electronic physisorption at plasma walls
[39]
B. Zenker, D. Ihle, F.X. Bronold, and H. Fehske, Phys. Rev. B 83, 235123 (2011)
Slave-field fluctuation approach to the extended Falicov-Kimball model: charge, orbital, and excitonic susceptibilities
[38]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. B 83, 195407 (2011); arXiv:1102.0632
Physisorption of an electron in deep surface potentials off a dielectric surface
[37]
F.X. Bronold, R.L. Heinisch, J. Marbach, and H. Fehske, IEEE Trans. Plasma Science 39, 644 (2011); arXiv:1009.2897
Plasma walls beyond the perfect absorber approximation for electrons
[36]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. B 82, 125408 (2010); arXiv:1006.1758
Phonon-mediated sticking of electrons at dielectric surfaces
[35]
R.L. Heinisch, F.X. Bronold, and H. Fehske, Phys. Rev. B 81, 155420 (2010); arXiv:1001.4956
Phonon-mediated desorption of image-bound electrons from dielectric surfaces
[34]
B. Zenker, D. Ihle, F.X. Bronold, and H. Fehske, Phys. Rev. B 81, 115122 (2010); arXiv:0912.2854
On the existence of the excitonic insulator phase in the extended Falicov-Kimball model: an SO(2)-invariant slave-boson approach
[33]
F.X. Bronold, H. Deutsch, and H. Fehske, Eur. Phys. J. D 54, 519 (2009); arXiv:0901.4915
Physisorption kinetics of electrons at plasma boundaries
[32]
F.X. Bronold, H. Fehske, and H. Deutsch, accepted contribution to the 19th International Symposium on Plasma Chemistry (ISPC19), Bochum, Germany, July 2009
Microphysics of electrons at plasma boundaries
[31]
F.X. Bronold, H. Fehske, H. Kersten, and H. Deutsch, Contrib. Plasma Phys. 49, 303 (2009); arXiv:0904.3187
Towards a Microscopic Theory of Particle Charging
[30]
D. Ihle, M. Pfafferott, E. Burovski, F.X. Bronold, and H. Fehske, Phys. Rev. B 78, 193103 (2008)
Bound state formation and nature of the excitonic insulator phase in the extended Falicov-Kimball model
[29]
F.X. Bronold, H. Fehske, H. Kersten, and H. Deutsch, Phys. Rev. Lett. 101, 175002 (2008)
Surface states and the charge of a dust particle in a plasma
[28]
F.X. Bronold and H. Fehske, Superlattices and Microstructures 43, 512 (2008)
On the possibility of excitonic phases at the semiconductor-semimetal transition
[27]
F.X. Bronold, in Computational Many-Particle Physics, Lecture Notes in Physics 739, pp. 223-254, Springer Berlin Heidelberg 2008
Boltzmann transport in condensed matter
[26]
K. Matyash, R. Schneider, F. Taccogna, A. Hatayama, S. Longo, M. Capitelli, D. Tskhakaya, and F.X. Bronold, Contr. Plasma Physics 47, 595 (2007)
Particle-in-cell simulation of low-temperature plasmas
[25]
K. Matyash, R. Schneider, K. Dittmann, J. Meichsner, F.X. Bronold, and D. Tskhakaya, J. Phys. D: Applied Physics 40, 6601 (2007)
Radio-frequency discharges in oxygen. III: Comparison of simulation and experiment
[24]
F.X. Bronold, K. Matyash, D. Tskhakaya, R. Schneider, and H. Fehske, J. Phys. D: Applied Physics 40, 6583 (2007)
Radio-frequency discharges in oxygen. I: Particle-based Modeling
[23]
F.X. Bronold, K. Matyash, D. Tskhakaya, R. Schneider, and H. Fehske, Proceedings of the ICPIC 2007
Particle-based modeling of oxygen discharges
[22]
K. Dittmann, K. Matyash, F.X. Bronold, R. Schneider, H. Fehske, und J. Meichsner, Proceedings of the ICPIC 2007
Heavy particle impact excitation of atomic oxygen in front of the powered electrode of oxygen rf plasmas -- Experiment and PIC-simulation
[21]
F.X. Bronold, H. Fehske, and G. Röpke, J. Phys. Soc. Jpn. 76 Suppl. A, 27-30 (2007)
Electron-hole liquid versus excitonic phases in TmSeTe
[20]
F.X. Bronold and H. Fehske , Phys. Rev. B 74, 165107 (2006)
Possibility of an excitonic insulator at the semiconductor-semimetal transition
[19]
B. Hülsen, F.X. Bronold, H. Fehske, and Y. Yonemitsu, Physica B 378-380, 267 (2006)
Phase diagram of the excitonic insulator
[18]
H. Fehske, F.X. Bronold, and A. Alvermann, Proc. Int. School of Physics ``Enrico Fermi'', Course CLXI, Polarons in Bulk Materials and Systems with Reduced Dimensionality, Eds. G. Iadonisi, J. Ranninger, G. de Filippis, IOS Press, Amsterdam, Oxford, Tokio, Washington DC (2006), pp 313-325
Localisation versus self-trapping: Polaron formation in the Anderson-Holstein model.
[17]
A. Alvermann, G. Schubert, A. Weiße, F.X. Bronold, and H. Fehske, Physica B 359-361, 789 (2005).
Characterisation of Anderson localisation using distributions
[16]
F.X. Bronold, A. Saxena, and D.L. Smith , Phys. Rev. B 70, 245210 (2004)
Semiclassical kinetic theory of electron spin relaxation in semiconductors
[15]
F.X. Bronold, A. Saxena, and D.L. Smith, in Solid State Physics 58, eds., H. Ehrenreich and F. Spaepen, Academic Press, San Diego, pp.73-166 (2004)
Electron spin dynamics in semiconductors
[14]
F.X. Bronold, A. Alvermann, and H. Fehske, Phil. Mag. B 84, 673-704 (2004)
Anderson localization in strongly coupled disordered electron-phonon systems
[13]
A. Alvermann, F.X. Bronold, and H. Fehske, Phys. Status Solidi (c) 1, 63-66 (2004)
Electron transport in the Anderson model
[12]
F.X. Bronold, Proceedings of NATO Advanced Research Workshop on "Optical Properties of 2D systems with interacting electrons", edited by W. J. Ossau and R. Suris, NATO Science Series 119, Kluwer Academic Publishers (2003), pp. 169; cond-mat/0209042
Cluster meanfield approximation for the optical response of weakly doped semiconductor quantum wells
[11]
F.X. Bronold and H. Fehske, Acta Physica Polonica 34, 851 (2003); cond-mat/0206019
Statistical dynamical mean-field description of strongly correlated disordered electron-phonon systems
[10]
F.X. Bronold, I. Martin, A. Saxena, and D.L. Smith, Phys. Rev. B 66, 233206 (2002), cond-mat/0208139.
Magnetic-Field Dependence of Electron Spin Relaxation in n-type Semiconductors
[9]
F.X. Bronold and H. Fehske, Phys. Rev. B 66, 073102 (2002).
Anderson localization of polaron states
[8]
F.X. Bronold, A. Saxena, and A.R. Bishop, Phys. Rev. B 63, 235109 (2001).
Dynamics of a single electron in the disordered Holstein model
[7]
F.X. Bronold, Phys. Rev. B 61, 12620 (2000).
Absorption spectrum of a weakly n-doped quantum well
[6]
F.X. Bronold, Journal of Luminescence 87-89, 198 (2000).
Charged excitons in weakly doped semiconductors
[5]
F.X. Bronold and A.R. Bishop, Phys. Rev. B 53, 13456 (1996).
Nonlinear optics of conjugated polymers: A coupled exciton-phonon gas approach
[4]
F.X. Bronold, A. Saxena, and A.R. Bishop, Journal of Luminescence 60, 849 (1994).
Radiative processes in poly(phenylene vinylene)
[3]
F.X. Bronold, A. Saxena, and A.R. Bishop, Phys. Rev. B 48, (RC)13162 (1993).
Radiative decay of polaron-excitons in poly(phenylene vinylene)
[2]
F.X. Bronold, A. Saxena, and A.R. Bishop, Physica D 66, 14 (1993).
Interchain coupling and 3D modeling of trans-polyacetylene
[1]
F.X. Bronold and K. Fesser, Nonlinear Coherent Structures in Physics and Biology, M. Remoissenet and M. Peyrard, Eds., Lecture Notes in Physics 393, Springer Verlag 1991, 118.
Kinks in disordered conjugated polymers