| 243 - 243 |
From microreactor design to microreactor process design
Hessel V |
| 255 - 258 |
Process intensification by miniaturization
Charpentier JC |
| 259 - 266 |
Enhancement of chemical selectivity by microreactors
Yoshida J, Nagaki A, Iwasaki T, Suga S |
| 267 - 284 |
Organic synthesis with microstructured reactors
Hessel V, Lowe H |
| 285 - 289 |
Mixing and organic chemistry
Bayer T, Himmler K |
| 290 - 301 |
The application of microreactors for small scale organic synthesis
Watts P, Haswell SJ |
| 303 - 313 |
Microreaction for microfuel processing: Challenges and prospects
Shah K, Ouyang X, Besser RS |
| 314 - 317 |
New scopes in process design using microstructured devices
Kirschneck D, Kober M, Marr R |
| 318 - 323 |
Microreactor technology: A revolution for the fine chemical and pharmaceutical industries?
Roberge DM, Ducry L, Bieler N, Cretton P, Zimmermann B |
| 324 - 330 |
Design of a new micromixer for instant mixing based on the collision of micro segments
Nagasawa H, Aoki N, Mae K |
| 331 - 336 |
Efficient oxidation of aromatics with peroxides under severe conditions using a microreaction system
Yube K, Mae K |
| 337 - 343 |
Ceramic plate heat exchanger for heterogeneous gas-phase reactions
Schmitt C, Agar DW, Platte F, Buijssen S, Pawlowski B, Duisberg M |
| 344 - 352 |
Versatile gas/liquid microreactors for industry
Chambers RD, Fox MA, Holling D, Nakano T, Okazoe T, Sandford G |
| 353 - 361 |
Laminar flow and heat transfer in a periodic serpentine channel
Rosaguti NR, Fletcher DF, Haynes BS |
| 362 - 366 |
A mu-fluidic mixing network
Baier T, Drese KS, Schonfeld F, Schwab U |
| 367 - 375 |
The influence of differences between microchannels on microreactor performance
Delsman ER, de Croon MHJM, Elzinga GD, Cobden PD, Kramer GJ, Schouten JC |
| 376 - 379 |
Integration of microreaction technology into the curriculum
Gorges R, Taubert T, Klemm W, Scholz P, Kreisel G, Ondruschka B |
