about
Continuous-Flow Synthesis of the Anti-Malaria Drug ArtemisininThe synthesis of active pharmaceutical ingredients (APIs) using continuous flow chemistryFlow "Fine" Synthesis: High Yielding and Selective Organic Synthesis by Flow MethodsStrategic Application of Residence-Time Control in Continuous-Flow ReactorsContinuous Flow Metathesis for Direct Valorization of Food Waste: An Example of Cocoa Butter TriglycerideMicrowave and continuous flow technologies in drug discovery.Photochemistry with laser radiation in condensed phase using miniaturized photoreactorsCommon origins of RNA, protein and lipid precursors in a cyanosulfidic protometabolism.Triple-channel microreactor for biphasic gas-liquid reactions: Photosensitized oxygenations.Highly functionalized biaryls via Suzuki-Miyaura cross-coupling catalyzed by Pd@MOF under batch and continuous flow regimes.A polystyrene-supported 9-amino(9-deoxy)epi quinine derivative for continuous flow asymmetric Michael reactions.Nanomanufacturing of Tobacco Mosaic Virus-Based Spherical Biomaterials Using a Continuous Flow Method.Characterization and modeling of multiphase flow in structured microreactors: a post microreactor case study.Continuous flow of nitroso Diels-Alder reaction.Simple and rapid hydrogenation of p-nitrophenol with aqueous formic acid in catalytic flow reactorsRaman spectroscopy as a tool for monitoring mesoscale continuous-flow organic synthesis: Equipment interface and assessment in four medicinally-relevant reactions.Continuous-Flow Synthesis and Derivatization of Aziridines through Palladium-Catalyzed C(sp(3) )-H Activation.Rapid and efficient trifluoromethylation of aromatic and heteroaromatic compounds using potassium trifluoroacetate enabled by a flow system.Cross-coupling in flow.Efficient and selective chemical transformations under flow conditions: The combination of supported catalysts and supercritical fluidsApplication of metal-based reagents and catalysts in microstructured flow devices.Homogeneous photocatalytic reactions with organometallic and coordination compounds--perspectives for sustainable chemistry.Merging chemical synthesis and biosynthesis: a new chapter in the total synthesis of natural products and natural product libraries.Tools for chemical synthesis in microsystems.Photochemical transformations accelerated in continuous-flow reactors: basic concepts and applications.From stereodynamics to high-throughput screening of catalysed reactions.Diazo compounds in continuous-flow technology.Continuous flow photolysis of aryl azides: Preparation of 3H-azepinones.The Eschenmoser coupling reaction under continuous-flow conditions.Microphotochemistry: 4,4'-Dimethoxybenzophenone mediated photodecarboxylation reactions involving phthalimides.Lessons from the synthetic chemist nature.Nanocatalysis in Flow.Koch-Haaf reaction of adamantanols in an acid-tolerant hastelloy-made microreactor.Continuous preparation of carbon-nanotube-supported platinum catalysts in a flow reactor directly heated by electric current.Multistep flow synthesis of vinyl azides and their use in the copper-catalyzed Huisgen-type cycloaddition under inductive-heating conditionsTaming hazardous chemistry by continuous flow technology.Multi-step continuous-flow synthesis.Unlocking the potential benefits of flow chemistry in the drug-discovery process.Continuous-flow processes for the catalytic partial hydrogenation reaction of alkynes.Continuous-flow enantioselective α-aminoxylation of aldehydes catalyzed by a polystyrene-immobilized hydroxyproline.
P2860
Q22061979-5F97F19D-2F67-4335-B4CA-51AF0E8D6684Q26783484-4C1FDCBC-441F-4CC1-A0A1-70C7305653C8Q26785737-D6F0BBEF-EAC5-4B0F-A0D7-5A691BF654BFQ26801617-328E4030-CE8C-4FCE-BD32-03FFBF0CA373Q28608529-1D5076AA-F610-4A54-A390-32C8F3691BEFQ34419675-B4D2A30F-97F0-4B07-A8B5-81DB2CE22EA6Q34423611-B2223337-AFF0-40D0-AAF2-E9BF7582C39EQ34468399-9E1F41D8-A86F-4726-8A65-DF6DEF9DF0BCQ35206088-BB23A808-A242-4DBC-B50E-A2BF22427997Q35447048-47C949CB-3EE9-45AA-AD10-09FAF40F7C80Q35568943-6E701E13-96DB-441B-951B-D5C7F961252DQ35589913-9CDA3998-5A22-4550-9FA6-4EDF85D14E39Q35678896-27B5D701-26DB-4946-8532-3EFC61A8E9E2Q35862751-D3F2B0C3-AE94-4B75-BDFF-C88107B8D173Q36982331-9DFEAACF-9CAB-440F-979B-E94CDBA9E05EQ37186154-27BA5796-969B-43BB-B15D-90483C5D26F8Q37391735-36633550-893C-4C8C-9E84-8EF7D249FA15Q37418628-F2288D0F-ADC3-4D21-B3AE-51F6414480B6Q37914019-E22D6EB2-6B64-4297-9094-03F741B5301AQ37951444-33786F80-A44B-4129-A051-9C3006E0F981Q37978589-8DA9A000-7FCF-4B17-8EF5-273C5FD63DFFQ37979737-88622FBC-D9AE-48FF-850A-8F9EF152A7B0Q37996334-3F5DEA10-285B-4642-AD00-98D9AEE4BC5DQ38215232-2A2A27C6-95CA-4934-BF4B-902C275D161BQ38233279-E036BDA4-92E7-455E-A6E4-59CE2F781DE7Q38237789-12EAA59A-317E-47CD-9C24-9A1FDD9FA817Q38285577-0DF9A166-1141-47FC-983E-DCDF5C9E217CQ38325537-9B166B13-E730-4B23-90F3-779CBFD757AFQ38364612-86A36701-AB2A-4575-8BE6-2645A2300BDCQ38365240-1AC4CB0F-C9F2-40B1-BE33-AF2C0E2AF089Q38366491-3AF89FC6-3DE3-4FD2-BC23-FDACB348C6F3Q38543468-5EE2FD99-1FD5-4671-93D6-1069FB2D22B0Q38586646-323AFDDD-7649-40A9-9AE6-7CBD50B36869Q38818927-E178A40C-3ECB-409D-9CB6-E884EE4A1931Q38898752-0AA134C1-F666-4588-9F32-B11FA84EEB50Q38907371-E7282F41-1F13-4CEF-B4DA-CF5A79B2D27DQ39096340-CDBFF675-AFFE-4B8B-AEE2-2DE51A36E786Q39170518-86653D17-8CA2-4009-A560-FFC4A2D0EFB2Q39305793-9BD33316-FB7A-4474-8C32-1938E868D4C4Q40213572-03804101-DF5C-4BD1-BAAE-931E951A786A
P2860
description
2011 nî lūn-bûn
@nan
2011年の論文
@ja
2011年学术文章
@wuu
2011年学术文章
@zh-cn
2011年学术文章
@zh-hans
2011年学术文章
@zh-my
2011年学术文章
@zh-sg
2011年學術文章
@yue
2011年學術文章
@zh
2011年學術文章
@zh-hant
name
Ten key issues in modern flow chemistry.
@en
Ten key issues in modern flow chemistry.
@nl
type
label
Ten key issues in modern flow chemistry.
@en
Ten key issues in modern flow chemistry.
@nl
prefLabel
Ten key issues in modern flow chemistry.
@en
Ten key issues in modern flow chemistry.
@nl
P2093
P2860
P356
P1476
Ten key issues in modern flow chemistry.
@en
P2093
Andreas Kirschning
Jens Wegner
Sascha Ceylan
P2860
P304
P356
10.1039/C0CC05060A
P407
P577
2011-03-15T00:00:00Z