Publications on ThalesNano instruments and applications
| Origin of the rate enhancement and enantiodifferentiation in the heterogeneous enantioselective hydrogenation of 2,2,2-trifluoroacetophenone over Pt/alumina studied in continuous-flow fixed-bed reactor system |
Szőllősi, Gy.; Cserényi, Sz.; Bucsi, I.; Bartók, T.; Fülöp, F.; Bartók, M.; Origin of the rate enhancement and enantiodifferentiation in the heterogeneous enantioselective hydrogenation of 2,2,2-trifluoroacetophenone over Pt/alumina studied in continuous-flow fixed-bed reactor system, Applied Catalysis A: General; 2010; 382; 263-271 |
| De Novo Design of a Picomolar Nonbasic 5-HT1B Receptor Antagonist |
Nugiel, D.A.; Krumrine, J.R.; Hill, D.C.; Damewood, J.R.; Bernstein, P.R.; Sobotka-Briner, C.D.; Liu, J.W.; Zacco, A.; Pierson, M.E.; De Novo Design of a Picomolar Nonbasic 5-HT1B Receptor Antagonist; J. Med. Chem.; 2010; 53; 1876-1880 |
| Synthesis of Unique Scaffolds via Diels-Alder Cycloadditions of Tetrasubstituated Cyclohexadienes |
Jones, A. L.; Snyder, J.K.; Synthesis of Unique Scaffolds via Diels-Alder Cycloadditions of Tetrasubstituated Cyclohexadienes; Organic Letters, 2010, 12 (7); 1592-1595 |
| A Flow Process Using Microreactors for the Preparation of a Quinolone Derivate as a Potent 5HT1B Antagonist; |
Qian, Z.; Baxendale, I.R.; Ley, S.V.; A Flow Process Using Microreactors for the Preparation of a Quinolone Derivate as a Potent 5HT1B Antagonist; Synlett, 2010, 4, 505-508 |
| Continuous Flow Organic Synthesis under High-Temperature/Pressure Conditions |
Razzaq, T., Kappe, O.C.; Continuous Flow Organic Synthesis under High-Temperature/Pressure Conditions; Chem. Asian J.; 2010; 5 (6); 1274-1289 |
| Mechanistic Insights into Copper(I)-Catalyzed Azide-Alkyne Cycloadditions using Continuous Flow Conditions |
Fuchs, M.; Goessler, W.; Pilger, C.; Kappe, O.C.; Mechanistic Insights into Copper(I)-Catalyzed Azide-Alkyne Cycloadditions using Continuous Flow Conditions; Adv. Synth. Catal.; 2010; 352; 323-328 |
| ReactIR Flow Cell: A New Analytical Tool for Continuous Flow Chemical Processing |
Carter, C. F.; Lange, H.; Ley, S.V.; Baxendale, I. R.; Wittkamp, B.; Goode, J. G.; Gaunt, N. L.; ReactIR Flow Cell: A New Analytical Tool for Continuous Flow Chemical Processing; Org. Process Res. Dev.;2010; 14; 393-404 |
| Lipase-catalyzed kinetic resolution of 2-methylene-substituated cycloalkanols in batch and continuous-flow modes |
Tomin, A.; Hornyánszky, G.; Kupai, K.; Dorkó, Zs.; Ürge, L.; Darvas, F.; Poppe, L.; Lipase-catalyzed kinetic resolution of 2-methylene-substituated cycloalkanols in batch and continuous-flow modes; Process Biochemistry, 2010, 45, 859-865 |
| Translating High-Temperature Microwave Chemistry to Scalable Continuous Flow Processes |
Damm, M.; Glasnov, T.N.; Kappe, O.C.; Translating High-Temperature Microwave Chemistry to Scalable Continuous Flow Processes; Org. Process Res. Dev.; 2010; 14; 215-224 |
| A Multistep Continuous-Flow System for Rapid On-Demand Synthesis of Receptor Ligands |
Petersen, T.P.; Ritzen, A.; Ulven, T.,; A Multistep Continuous-Flow System for Rapid On-Demand Synthesis of Receptor Ligands, Organic Letters, 2009, 11(22); 5134-5137 |