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Chronological [ 1990-2016 ] - PDF
[ Coauthors / colleagues - 2016 ]
Please note that this is a private web site NOT located at NDSU.
Names highlighted in blue are undergraduate coauthors.
Publications on Metal Oxides:
MgO
112 | Carbon Dioxide Adsorption on MgO(001) - CO2 Kinetics and Dynamics, |
CuO cluster
105 | Adsorption dynamics of CO on silica supported CuOx clusters – |
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102 | Utilizing electron beam lithography for studying methanol synthesis model systems – the case of Cu, CuOx, and Au nano clusters, Preprints of Symposia – American Chemical Society, Division of Fuel Chemistry, 57 (2012) 712 by J. Shan, A. Chakradhar, M. Komarneni, E. Kadossov, J. Schmidt, U. Burghaus, D. Rosenmann, L.E. Ocola, S. Dhuey, S. Cabrini |
ZnO
58 | Adsorption of iso-butane on ZnO(0001)-Zn, Surface Science,600 (2006) 4855-4859, by J. Wang, B. Hokkanen, and U.Burghaus. |
51 | Adsorption dynamics of CO2 on copper precovered ZnO(0001)-Zn: a molecular beam scattering and thermal desorption spectroscopy study, Journal of Chemical Physics 123 (2005) 204710, J. Wang, S. Funk, U. Burghaus. |
50 | Adsorption of CO on the copper precovered ZnO(0001) surface: a molecular beam scattering study, Journal of Chemical Physics 123 (2005) 184716, J. Wang, U. Burghaus. |
49 | Indications for Metal Support Interactions: The case of CO2 Adsorption on Cu/ZnO(0001), Catalysis Letters 103 (2005) 219 J. Wang, S. Funk, and U. Burghaus. |
48 | Particle Size Effects in The Adsorption Dynamics of CO: The Structure-Activity Relationship in The Case of Cu/Zn-ZnO, Chemical Physics Letters 410 (2005) 131-135, J. Wang, E. Johnson, and U. Burghaus. |
47 | Adsorption of CO2 on Pristine Zn-ZnO(0001) and Defected Zn-ZnO(0001): A Thermal Desorption Spectroscopy Study, Surface Science 577 (2005) 158-166, by J. Wang, B. Hokkanen, U. Burghaus. |
46 | Structure-Activity Relationship : The Case of CO2 Adsorption on H/Zn-ZnO(0001), Chemical Physics Letters 403 (2005) 42-46, by J. Wang, U. Burghaus. |
45 | Adsorption Dynamics of CO2 on Zn-ZnO: a Molecular Beam Study, Journal of Chemical Physics 122 (2005) 044705-11, by J. Wang, U. Burghaus. |
42 | The interaction of water withtheoxygen-terminated, polar surface of ZnO, Journal of Physical Chemistry B 107 (2003) 14350-14356, by M. Kunat, St. Gil Girol, U. Burghaus, Ch. Wöll. |
41 | Adsorption of hydrogen on the polar O-ZnO surface: a molecular beam study, PCCP - Phys. Chem. Chem. Phys. 5 (2003) 4962-4967 by M. Kunat, U. Burghaus, Ch. Wöll. |
30 | Monte Carlo Simulation of the adsorbate assisted adsorption in the case of CO/ZnO, Surface Review and Letters 8 (2001) 353-360, by U. Burghaus. |
28 | Interaction of hydrogen with metal oxides: The case of the polar ZnO(0001)-surface, Surface Science. 486 (2001) L502-506 by Th. Becker, St. Hövel, M. Kunat, Ch. Boas, U. Burghaus, and Ch. Wöll. |
40 | Adsorption of CO on rutile (1x1)-TiO2(110): amolecular beamstudy, Surface Science 544 (2003) 170-182, by M. Kunat, U. Burghaus. |
38 | Coadsorption of hydrogen and CO on Zn-ZnO: a molecular beam study, Journal of Vacuum Science and Technology A21 (2003) 1322-1325, M. Kunat, U. Burghaus*. |
36 | Stabilization of polar ZnO-surfaces: Validating microscopic models by using CO as a probe molecule, Physical Review Letters 90(2003) 106102--106102-4, by V. Staemmler, K. Fink, B. Meyer, D. Marx, M. Kunat, S.Gil Girol, U. Burghaus, Ch. Wöll. |
33 | Stability of polar surfaces of ZnO: a reinvestigation by He atom scattering, Rapid Communication PhysicalReview B66 (2002) 081402--081402-3, by M. Kunat, St. Gil-Girol, Th. Becker, U. Burghaus, Ch. Wöll. |
24 | Adsorption dynamics of CO on the polar surfaces of ZnO, Journal of Chemical Physics 113 (2000) 6334-6342, by Th. Becker, M. Kunat, Ch. Boas, U. Burghaus*, and Ch. Wöll. |
22 | Adsorption probability of CO on ZnO a molecular beam study. Journal of Vacuum Science and Technology A 18(4)(2000) 1089-1092, by Th. Becker, Ch. Boas, U. Burghaus*, Ch. Wöll. |
18 | Adsorption probability of CO on a metal-oxide:The case of oxygen-terminated ZnO and the influence of defects, Physical Review B61 (2000) 4538-4541, by Th. Becker, Ch. Boas, U. Burghaus*, Ch. Wöll. |
CaO
100 | Adsorption and dissociation kinetics of alkanes on CaO(100), Surface Science 605 (2011) 1534-1540, by A.Chakradhar, Y. Liu, J. Schmidt, E. Kadossov, and U. Burghaus |
86 | Interaction of combustion gases with a CaO(100) surface: adsorption kinetics and dynamics, ACS proceedings division of fuel chemistry, Salt Lake City, Am. Chem. Soc., Div. Fuel Chem. 54 (2009) 268, by E. Kadossov, M.R. Hoffmann, U. Burghaus |
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78 | Unexpected bond activation of small organic molecules on a metal oxide - butane/CaO(100), by E. Kadossov, U. Burghaus Chemical Communications (2008) 4073-4075 |
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76 | Adsorption kinetics and dynamics of CO, NO, and CO2 on reduced CaO(001), Journal of Physical Chemistry C, 112 (2008) 7390-7400 by E. Kadossov, U. Burghaus |
FeOx
81 | Adsorption kinetics and dynamics of CO and CO 2 on FeOx nanoclusters: DFT and molecular beam scattering, ACS proceedings division of fuel chemistry, ISSN 1521-4648 53 (2008) 855-856, by E. Kadossov, U. Burghaus, M.R. Hoffmann |
74 | Adsorption dynamics and kinetics of CO2 on Fe/FeOx nanoclusters supported on HOPG, Surface and Interface Analysis 40(2008) 893-898, by E. Kadossov, U. Burghaus |
73 | Molecular beam scattering of CO on iron oxide clusters supported on graphite (HOPG) Surface Science 602 (2008) 811-818, by E. Kadossov, J. Goering, U. Burghaus |
TiO2
71 | Reactivity screening of anatase TiO2 nanotube arrays and antase thin films: a surface chemistry point of view, by S. Funk, B. Hokkanen, T. Nurkic, J. Goering, E. Kadossov, U. Burghaus (NDSU) A. Ghicov, P. Schmuki (Nuernberg-Erlangen University) Z.Q. Yu, S. Thevuthasan, L.V. Saraf (PNNL) In "Nanoparticles: Synthesis, Stabilization,Passivation and Functionalization", Eds., R. Nagarajan and T. A. Hatton, ACS Symposium Series 996, American Chemical Society, Washington DC., Chapter 11 ISBN 978-0-8412-6969-9 |
69 | Adsorption kinetics of alkanes on TiO2 nanotubes array - structure-activity relationship, Surface Science 601 (2007) 4620-4628, by B. Hokkanen, S. Funk, U. Burghaus (NDSU), A. Ghicov, P. Schmuki (Nuernberg-Erlangen University) |
67 | CO oxidation on anatase TiO2 nanotubes array and the effect of defects, Catalysis Letters 118 (2007) 118-122 by S. Funk and U. Burghaus |
65 | Adsorption of iso-/n-butane on an anatase thin film: a molecular beam scattering and TDS study, Catalysis letters 116 (2007) 9-14, J. Goering, E. Kadossov, U. Burghaus (NDSU) Z.Q. Yu, S. Thevuthasan, L.V. Saraf (PNNL) |
63 | Unexpected adsorption of oxygen on TiO2 nanotube arrays - influence of crystal structure, Nano Letters 7 (2007) 1091-1094 by S. Funk, B. Hokkanen, U. Burghaus (NDSU) A. Ghicov, P. Schmuki (Erlangen-Nuernberg University) |
59 | Adsorption of CO2 on oxidized, defected, hydrogen, and oxygen covered rutile (1x1)-TiO2 (110), PCCP - Physical Chemistry Chemical Physics, 8 (2006) 4805-4813, by S. Funk, U. Burghaus |
57 | Effect of oxygen vacancy sites on CO2 adsorption dynamics: the case of rutile (1x1)-TiO2(110), Chemical Physics Letters 422 (2006) 461-465, by S. Funk, B. Hokkanen, E. Johnson , and U.Burghaus |
43 | The adsorption of hydrogen on the rutile TiO2(110) surface, Phys. Chem. Chem. Phys., 6 (2004) 4203-4207, by M. Kunat, U. Burghaus, and Ch. Wöll. |
Cr2O3
62 | CO2 adsorption on Cr(110) and Cr2O3(0001)/Cr(110), Applied Surface Science 253 (2007) 7108-7114, by S. Funk, T. Nurkic, B. Hokkanen, U. Burghaus |