Kai Sundmacher
Kai Sundmacher
Professor of Process Systems Engineering, Max Planck Institute for Dynamics of Complex Technical
Verified email at - Homepage
Cited by
Cited by
Reactive distillation: status and future directions
K Sundmacher, A Kienle
John Wiley & Sons, 2006
The impact of mass transport and methanol crossover on the direct methanol fuel cell
K Scott, WM Taama, P Argyropoulos, K Sundmacher
Journal of Power Sources 83 (1-2), 204-216, 1999
Sequential bottom-up assembly of mechanically stabilized synthetic cells by microfluidics
M Weiss, JP Frohnmayer, LT Benk, B Haller, JW Janiesch, T Heitkamp, ...
Nature materials 17 (1), 89-96, 2018
The use of CO stripping for in situ fuel cell catalyst characterization
T Vidaković, M Christov, K Sundmacher
Electrochimica Acta 52 (18), 5606-5613, 2007
Dynamics of the direct methanol fuel cell (DMFC): experiments and model-based analysis
K Sundmacher, T Schultz, S Zhou, K Scott, M Ginkel, ED Gilles
Chemical Engineering Science 56 (2), 333-341, 2001
MaxSynBio: avenues towards creating cells from the bottom up
P Schwille, J Spatz, K Landfester, E Bodenschatz, S Herminghaus, ...
Angewandte Chemie International Edition 57 (41), 13382-13392, 2018
Current status of and recent developments in the direct methanol fuel cell
T Schultz, S Zhou, K Sundmacher
Chemical Engineering & Technology 24 (12), 1223-1233, 2001
Big data creates new opportunities for materials research: a review on methods and applications of machine learning for materials design
T Zhou, Z Song, K Sundmacher
Engineering 5 (6), 1017-1026, 2019
Recent advances in enzymatic fuel cells: experiments and modeling
I Ivanov, T Vidaković-Koch, K Sundmacher
Energies 3 (4), 803-846, 2010
Overview of surrogate modeling in chemical process engineering
K McBride, K Sundmacher
Chemie Ingenieur Technik 91 (3), 228-239, 2019
Towards a methodology for the systematic analysis and design of efficient chemical processes: Part 1. From unit operations to elementary process functions
H Freund, K Sundmacher
Chemical Engineering and Processing: Process Intensification 47 (12), 2051-2060, 2008
A model for the liquid feed direct methanol fuel cell
K Scott, P Argyropoulos, K Sundmacher
Journal of Electroanalytical Chemistry 477 (2), 97-110, 1999
An overview of mutual solubility of ionic liquids and water predicted by COSMO-RS
T Zhou, L Chen, Y Ye, L Chen, Z Qi, H Freund, K Sundmacher
Industrial & engineering chemistry research 51 (17), 6256-6264, 2012
Computer‐aided design of ionic liquids as solvents for extractive desulfurization
Z Song, C Zhang, Z Qi, T Zhou, K Sundmacher
AIChE Journal 64 (3), 1013-1025, 2018
Assessment of Methanol Synthesis Utilizing Exhaust CO2 for Chemical Storage of Electrical Energy
LK Rihko-Struckmann, A Peschel, R Hanke-Rauschenbach, ...
Industrial & Engineering Chemistry Research 49 (21), 11073-11078, 2010
Steady-state multiplicities in reactive distillation columns for the production of fuel ethers MTBE and TAME: theoretical analysis and experimental verification
KD Mohl, A Kienle, ED Gilles, P Rapmund, K Sundmacher, U Hoffmann
Chemical Engineering Science 54 (8), 1029-1043, 1999
Sustainability of green solvents–review and perspective
V Hessel, NN Tran, MR Asrami, QD Tran, NVD Long, M Escribā-Gelonch, ...
Green Chemistry 24 (2), 410-437, 2022
Limiting current behaviour of the direct methanol fuel cell
K Scott, WM Taama, S Kramer, P Argyropoulos, K Sundmacher
Electrochimica Acta 45 (6), 945-957, 1999
Steam reforming of glycerol: The experimental activity of La1− xCexNiO3 catalyst in comparison to the thermodynamic reaction equilibrium
Y Cui, V Galvita, L Rihko-Struckmann, H Lorenz, K Sundmacher
Applied Catalysis B: Environmental 90 (1-2), 29-37, 2009
Direct methanol polymer electrolyte fuel cell: analysis of charge and mass transfer in the vapour–liquid–solid system
K Sundmacher, K Scott
Chemical Engineering Science 54 (13-14), 2927-2936, 1999
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