个人简介
Education
Postdoctoral Fellow 2007-2008 - Cornell University, US
Doktor-Ingenieur (with distinction) Mechanical Engineering, 2005 - Fridericiana University of Karlsruhe (now Karlsruhe Institute of Technology (KIT), Germany
Diplom-Ingenieur (with distinction) Chemical Engineering, 2001 - Dresden University of Technology, Germany
Diplom-Ingenieur (FH) Mechanical Engineering, 1996 - Aachen University of Applied Science, Germany
Professional Positions
Associate Professor, 2016-current - Department of Chemical Engineering and Department of Mechanical & Materials Engineering, Queen's University, Canada
Assistant Professor, 2011-2016 - Department of Mechanical & Materials Engineering, Queen's University, Canada
Assistant Professor, 2010-2016 - Department of Chemical Engineering, Queen's University, Canada
Associate Director, 2012-2015 - Queen's-RMC Fuel Cell Research Centre, Canada
Senior Research Engineer, 2008-2010 - Forschungszentrum Karlsruhe GmbH, Germany
Visiting Fellow Chemical Engineering, 2007-2008 - Cornell University, US
Senior Research Engineer, 2005-2007 - Forschungszentrum Karlsruhe GmbH, Germany
Research Engineer, 2002-2005 - Forschungszentrum Karlsruhe GmbH, Germany
Lab Engineer, 1997-2002 - FHTG Mannheim, Germany
Inspection Engineer, 1996-1997 - Hoevelmann & Bidinger Aachen, Germany
Areas of Expertise
Dominik Barz has academic and professional experience in areas encompassing both Mechanical and Chemical Engineering subjects. He worked as a laboratory engineer in a Mercedes Benz endowed fuel cells lab for five years and gained much experience in Electrochemical Engineering. Thereafter, his interests have been focused on the development of Lab-on-a-Chip Technologies including research on Microfluidics, Transport Mechanisms, and Surface & Interface Phenomena. The research consists, on one hand, of mathematical modeling and numerical simulations. On the other hand, his research always includes experiments to verify the theoretical models and assumptions that have been developed.
研究领域
Current Research Interests
Microfluidics & Transport Phenomena
Electrokinetic Phenomena
Interface Science
Electrochemical Engineering
近期论文
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J21 H. Falahati, E. Kim and D.P.J. Barz*: “Fabrication and Characterization of Thin-Film Nickel Hydroxide Electrodes for Micro-Power Applications” ACS Appl. Mater.Interfaces 7 (2015), p. 12797–12808, IF5(2014):6.8 free preprints with ACS ID
J20 R. Saini, M. Kenny, and D.P.J. Barz*: “Electroosmotic flow through packed beds of granular materials”, Microfluid. Nanofluid., 19 (2015), p. 693-708, IF5(2014):2.8
J19. H. Bockelmann and D.P.J. Barz*: “Optimised active flow control for micromixers and other fluid applications: Sensitivity- vs. adjoint-based strategies”, Comput Fluids, 106 (2015), p.93-107; IF:1.89
J18 R. Saini, A. Garg, and D.P.J. Barz* “Streaming potential revisited: The influence of convection on the surface conductivity”, Langmuir 30 (2014), p. 10950–10961. IF: 4.4
J17 H. Falahati, L. Wong, A. Garg, L. Davarpanah and D.P.J. Barz*: Investigation on the zeta potential of PMMA in contact with electrolytes of various conditions“, Electrophoresis 35 (2014), p. 870–882, IF: 3.3
J16 D.P.J. Barz* and P.H. Steen: “Dynamics of the electro-osmotically toggled droplet switch“, Phys. Fluids, 25 (2013), pp. 97104, IF: 1.99
J15 H. Falahati and D.P.J. Barz*: “Evaluation of hydrogen sorption models for AB5-type metal alloys by employing a gravimetric technique“, Int. J. Hydrogen Energy, 38 (2013), p. 8838-8851; IF: 4.4 Featured as Key Scientific Article in Renewable Energy Global Innovations, ISSN 2291-2460, http://reginnovations.org/, 08/03/2014
J14 H. Bockelmann, V. Heuveline and D.P.J. Barz*: “Optimization of an electrokinetic mixer for microfluidic applications”, Biomicrofluidics, 6 (2012) pp. 024123; IF: 3.4 Featured in Virtual Journal of Nanoscale Science & Technology, Vol. 25, Issue 23 (2012)
J13 D.P.J. Barz*, H.F. Zadeh, and P. Ehrhard: “Measurement and the simulation of time-dependent flow fields within an electrokinetic micromixer“, J. Fluid Mech., 676 (2011), p. 265-293; IF: 2.8
J12 D.P.J. Barz*, M.J. Vogel, and P.H. Steen: “Determination of the zeta potential of porous substrates by droplet deflection: II. Generation of electrokinetic flow in nonpolar liquids“, Langmuir, 26 (2010), p. 3126–3133; IF: 4.6
J11 D.P.J. Barz*: “Comprehensive model of electrokinetic flow and migration in microchannels with conductivity gradients“, Microfluid. Nanofluid., 7 (2009), p. 249-265; IF: 3.7
J10 D.P.J. Barz*, M.J. Vogel, and P.H. Steen: ”Determination of the zeta potential of porous substrates by droplet deflection: I. The influence of ionic strength and pH value of an aqueous electrolyte in contact with a borosilicate surface”, Langmuir, 25 (2009), p.1842-1850; IF: 4.4
J9 D.P.J. Barz*, H.F. Zadeh, and P. Ehrhard: ”Laminar flow and mass transport in a twice-folded microchannel“, AIChE J., 54 (2008), p. 381-393; IF: 2.3
J8 D.P.J. Barz*, H.F. Zadeh, and P. Ehrhard: ”3D simulation and experiment of flow in a folded microchannel“, PAMM, 6 (2006), p. 559-560;
J7 D.P.J. Barz, P. Ehrhard*: ”Model and validation of electrokinetic flow and transport in a micro electrophoresis device“, Lab Chip, 5 (2005), p. 949-958; IF: 5.3
J6 D.P.J. Barz*, P. Ehrhard: ”Fully-coupled model for electrokinetic flow and transport in microchannels“, PAMM, 5 (2005); p. 535-536.
J5 D.P.J. Barz*, P. Ehrhard: “Simulation of flow and mass transport in a meander microchannel subject to electroosmotic pumping”, Microscale Thermophysical Engineering, 9 (2005), p. 305-316;
J4 D.P.J. Barz*, P. Ehrhard: ”Simulation of flow and electrokinetic transport in a micro-analysis-system“, PAMM, 4 (2004), p. 472-473;
J3 D.P.J. Barz, U.K. Trägner, V.M. Schmidt*, and M. Koschowitz: “Thermodynamics of hydrogen generation from methane for domestic Polymer Electrolyte Fuel Cell Systems”, Fuel Cells, 3 (2003), p. 199-207;
J2 D.P.J. Barz*, P. Ehrhard: “Simulation of flow and mass transport in a meander micro-channel subject to electroosmotic driving“, PAMM, 3 (2003), p. 348-349;
J1 D.P.J. Barz, V.M. Schmidt*: “Addition of dilute H2O2 solutions to H2-CO fuel gases and their influence on performance of a Polymer Electrolyte Fuel Cell”, Phys. Chem. Chem. Phys., 3 (2001), p. 330-336; IF: 2.1