| 1 - 1 |
Special issue: Microreaction technolgy
Renken A, Baselt JP, Matlosz M |
| 3 - 9 |
Micro-structured string-reactor for autothermal production of hydrogen
Horny C, Kiwi-Minsker L, Renken A |
| 11 - 16 |
Carbon-coated microstructured reactors for heterogeneously catalyzed gas phase reactions: influence of coating procedure on catalytic activity and selectivity
Schimpf S, Bron A, Claus P |
| 17 - 22 |
Microreaction engineering studies of the hydroxylation of benzene with nitrous oxide
Hiemer U, Klemm E, Scheffler F, Selvam I, Schwieger W, Emig G |
| 23 - 29 |
Novel microreactors for functional polymer beads
Nisisako T, Torii T, Higuchi T |
| 31 - 38 |
Development of a new micromixer based on split/recombination for mass production and its application to soap free emulsifier
Mae K, Maki T, Hasegawa I, Eto U, Mizutani Y, Honda N |
| 39 - 48 |
Microchannel devices for the coalescence of dispersed droplets produced for use in rapid extraction processes
Okubo Y, Toma M, Ueda H, Maki T, Mae K |
| 49 - 56 |
Analysis of a toluene stripping process: a comparison between a microfabricated stripping column and a conventional packed tower
Cypes SH, Engstrom JR |
| 57 - 63 |
New methods for increasing productivity by using microreactors of planar pumping and alternating pumping types
Okamoto H, Ushijima T, Kitoh O |
| 65 - 74 |
Static micromixers for modular chip reactor arrangements in two-step reactions an photochemical activated processes
Kirner T, Albert J, Gunther M, Mayer G, Reinhackel K, Kohler JM |
| 75 - 85 |
g/l-Dispersion in interdigital micromixers with different mixing chamber geometries
Lob P, Pennemann H, Hessel V |
| 87 - 92 |
Development of microchannel methanol steam reformer
Park GG, Seo DJ, Park SH, Yoon YG, Kim CS, Yoon WL |
| 93 - 99 |
Catalytic conversion of propane to hydrogen in microstructured reactors
Aartun I, Gjervan T, Venvik H, Gorke O, Pfeifer P, Fathi M, Holmen A, Schubert K |
| 101 - 106 |
CO selective oxidation in a microchannel reactor for PEM fuel cell
Chen GW, Yuan Q, Li HQ, Li SL |
| 107 - 111 |
A new proton-conducting porous silicon membrane for small fuel cells
Pichonat T, Gauthier-Manuel B, Hauden D |
| 113 - 121 |
Wall coating of a CuO/ZnO/AI(2)O(3) methanol steam reforming catalyst for micro-channel reformers
Bravo J, Karim A, Conant T, Lopez GP, Datye A |
| 123 - 131 |
Experiments and modelling of an integrated preferential oxidation-heat exchanger microdevice
Delsman ER, de Croon MHJM, Kramer GJ, Cobden PD, Hofmann C, Cominos V, Schouten JC |
| 133 - 141 |
Hydrogen production for fuel cell application in an autothermal micro-channel reactor
Reuse P, Renken A, Haas-Santo K, Gorke O, Schubert K |
| 143 - 149 |
MEMS-based components of a miniature fuel cell/fuel reformer system
Tanaka S, Chang KS, Min KB, Satoh D, Yoshida K, Esashi M |
| 151 - 156 |
Microfabricated flow-through device for DNA amplification - towards in situ gene analysis
Fukuba T, Yamamoto T, Naganuma T, Fujii T |
| 157 - 161 |
Microfluidic system for DNA sequence detection
Yamashita K, Yamaguchi Y, Miyazaki M, Nakamura H, Shimizu H, Maeda H |
| 163 - 169 |
Spatially resolved detection of miniaturized reaction-diffusion experiments in chip reactors for educational purposes
Kirner T, Jaschinsky P, Kohler JM |
| 171 - 178 |
Feasibility study on concentration of slurry and classification of contained particles by microchannel
Ookawara S, Higashi R, Street D, Ogawa K |
| 179 - 185 |
Synthesis of pigments in a three-stage microreactor pilot plant-an experimental technical report
Wille C, Gabski HP, Haller T, Kim H, Unverdorben L, Winter R |
| 187 - 194 |
Direct monitoring of biochemical processes using micro-structured heat power detectors
Lerchner J, Wolf A, Huttl R, Wolf G |
| 195 - 199 |
gamma-Ray-initiated dispersion polymerization of PMA in microreactor
Chang ZQ, Liu G, Fang F, Tian YC, Zhang ZC |
| 201 - 216 |
Digital reaction technology by micro segmented flow - components, concepts and applications
Kohler JM, Henkel T, Grodrian A, Kirner T, Roth M, Martin K, Metze J |
| 217 - 224 |
Fast temperature cycling in microstructure devices
Brandner JJ, Emig G, Liauw MA, Schubert K |
| 225 - 235 |
Design of a molybdenum high throughput microreactor for high temperature screening of catalytic coatings
Mies MJM, Rebrov EV, de Croon MHJM, Schouten JC |
| 237 - 240 |
Electrochemical effects related to synthesis in micro reactors operating under electrokinetic flow
Watts P, Haswell SJ, Pombo-Villar E |
| 241 - 250 |
A microreactor-based system for the study of fast exothermic reactions in liquid phase: characterization of the system
Schneider MA, Maeder T, Ryser P, Stoessel F |
| 251 - 260 |
Generation of metal nanoparticles in a microchannel reactor
Wagner J, Kirner T, Mayer G, Albert J, Kohler JM |
| 261 - 268 |
A simple method of self assembled nano-particles deposition on the micro-capillary inner walls and the reactor application for photo-catalytic and enzyme reactions
Nakamura H, Li XY, Wang HZ, Uehara M, Miyazaki M, Shimizu H, Maeda H |
| 269 - 276 |
Production of titania nanoparticles by using a new microreactor assembled with same axle dual pipe
Takagi M, Maki T, Miyahara M, Mae K |
| 277 - 284 |
Preparation of functionalized nanostructures on microchannel surface and their use for enzyme microreactors
Miyazaki M, Kaneno J, Kohama R, Uehara M, Kanno K, Fujii M, Shimizu H, Maeda H |
| 285 - 294 |
Exploring the flow of immiscible fluids in a square vertical mini-channel by direct numerical simulation
Ghidersa BE, Worner A, Cacuci DG |
| 295 - 302 |
Porous media simplified simulation of single- and two-phase flow heat transfer in micro-channel heat exchangers
Imke U |
| 303 - 314 |
Modeling of electric-field driven transport processes in microdevices for immunoassay
Pribyl M, Snita D, Hasal P, Marek M |
| 315 - 322 |
Numerical and experimental investigations on liquid mixing in static micromixers
Engler M, Kockmann N, Kiefer T, Woias P |
| 323 - 331 |
Mixing in microreactors: effectiveness of lamination segments as a form of feed on product distribution for multiple reactions
Aoki N, Hasebe S, Mae K |
| 333 - 338 |
Investigations on the compatibility of chemically oxidized silicon (SiOx)-surfaces for applications towards chip-based polymerase chain reaction
Felbel J, Bieber I, Pipper J, Kohler JM |
| 339 - 345 |
Characterisation of electrically powered micro-heat exchangers
Henning T, Brandner JJ, Schubert K |
| 347 - 356 |
Numerical simulation of temperature distribution inside microfabricated free flow electrophoresis module
Matsumoto H, Komatsubara N, Kuroda C, Tajima N, Shinohara E, Suzuki H |
| 357 - 365 |
Introduction of image analysis for the quantification of the boiling flow heat transfer
Ferret C, Falk L, D'Ortona U, Chenu A, Veenstra TT |
| 367 - 372 |
Interface configuration of the two layered laminar flow in a curved microchannel
Yamaguchi Y, Takagi F, Watari T, Yamashita K, Nakamura H, Shimizu H, Maeda H |
| 373 - 378 |
Characterisation of residence time and residence time distribution in chip reactors with modular arrangements by integrated optical detection
Gunther M, Schneider S, Wagner J, Gorges R, Henkel T, Kielpinski M, Albert J, Bierbaum R, Kohler JM |
| 379 - 390 |
Flow distribution in different microreactor scale-out geometries and the effect of manufacturing tolerances and channel blockage
Amador C, Gavriilidis A, Angeli P |
| 391 - 396 |
A model for predicting axial mixing during gas-liquid Taylor flow in microchannels at low Bodenstein numbers
Salman W, Gavriilidis A, Angeli P |
| 397 - 402 |
CFD-based optimal design of manifold in plate-fin microdevices
Tonomura O, Tanaka S, Noda M, Kano M, Hasebe S, Hashimoto L |
| 403 - 407 |
Optimization of interdigital micromixers via analytical modeling -exemplified with the SuperFocus mixer
Drese KS |
| 409 - 419 |
Experimental approaches to a better understanding of mixing performance of microfluidic devices
Panic S, Loebbecke S, Tuercke T, Antes J, Boskovic D |
| 421 - 429 |
Numbering-up of micro devices: a first liquid-flow splitting unit
Schenk R, Hessel V, Hofmann C, Kiss J, Lowe H, Ziogas A |
| 431 - 438 |
Development of an automated microreaction system with integrated sensorics for process screening and production
Ferstl W, Loebbecke S, Antes J, Krause H, Haeberl M, Schmalz D, Muntermann H, Grund M, Steckenborn A, Lohf A, Hassel J, Bayer T, Kinzl M, Leipprand I |
| 439 - 445 |
Chip modules for generation and manipulation of fluid segments for micro serial flow processes
Henkel T, Bermig T, Kielpinski M, Grodrian A, Metze J, Kohler JM |
| 447 - 453 |
Microfluidic lab-on-a-chip systems based on polymers - fabrication and application
Guber AE, Heckele M, Herrmann D, Muslija A, Saile V, Eichhorn L, Gietzelt T, Hoffmann W, Hauser PC, Tanyanyiwa J, Gerlach A, Gottschlich N, Knebel G |
| 455 - 463 |
Enhanced mass transfer using a novel polymer/carrier microreactor
Schonfeld H, Hunger K, Cecilia R, Kunz U |
| 465 - 468 |
A micro plasma reactor for fluorinated waste gas treatment
Sichler P, Buttgenbach S, Baars-Hibbe L, Schrader C, Gericke KH |
| 469 - 475 |
Novel multifunctional microreaction unit for chemical engineering
Keoschkerjan R, Richter M, Boskovic D, Schnurer F, Lobbecke S |
