A microfluidic chip has been used to prepare fibres of a porous polymer with high structural order, setting a precedent for the generation of a wide variety of materials using this reagent mixing approach that provides unique materials not accessible easily through bulk processes. The reaction between 1,3,5-tris(4-aminophenyl)benzene and 1,3,5-benzenetricarbaldehyde in acetic acid under continuous microfluidic flow conditions leads to the formation of a highly crystalline and porous covalent organic framework (hereafter denoted as MF-COF-1), consisting of fibrillar micro-structures, which have mechanical stability that allows for direct drawing of objects on a surface ; Financial support from Spanish Government (Projects MAT2013-46753-C2-1-P and CTQ2014-53486-R) and FEDER are acknowledged. A. A. and J. P. L. would like to thank the financial support from the Swiss National Science Foundation (SNSF) through the project no. 200021_160174
Microfluidic technologies are highly adept at generating controllable compositional gradients in fluids, a feature that has accelerated the understanding of the importance of chemical gradients in biological processes. That said, the development of versatile methods to generate controllable compositional gradients in the solid‐state has been far more elusive. The ability to produce such gradients would provide access to extensive compositional libraries, thus enabling the high‐throughput exploration of the parametric landscape of functional solids and devices in a resource‐, time‐, and cost‐efficient manner. Herein, the synergic integration of microfluidic technologies is reported with blade coating to enable the controlled formation of compositional lateral gradients in solution. Subsequently, the transformation of liquid‐based compositional gradients into solid‐state thin films using this method is demonstrated. To demonstrate efficacy of the approach, microfluidic‐assisted blade coating is used to optimize blending ratios in organic solar cells. Importantly, this novel technology can be easily extended to other solution processable systems that require the formation of solid‐state compositional lateral gradients. ; The authors would like to acknowledge financial support from the Spanish Ministry of Economy, Industry and Competitiveness through the "Severo Ochoa" Programme for Centers of Excellence in R&D (SEV‐2015‐0496) and project reference PGC2018‐095411‐B‐I00 as well as the European Research Council (ERC) under grant agreement no. 648901. J.P.‐L. acknowledges the European Research Council Starting Grant microCrysFact (ERC‐2015‐STG No. 677020) and the Swiss National Science Foundation (200021_181988) and ETH Zürich. R. R.‐T. acknowledges the support from Generalitat de Catalunya and the COFUND programme of the Marie Curie Actions of the 7th R&D Framework Programme of the European Union (BP‐B 00256). X.R.‐M. acknowledges the departments of Physics, Chemistry and Geology of the Autonomous University of Barcelona (UAB) as coordinators of the PhD programme in Materials Science. X.R.‐M. and C.F. acknowledge Nicole Kleger‐Schai from ETH Zürich for her valuable help in using the rheometer. X.R.‐M. and M.C.‐Q. acknowledge Dr. Joan M. Cabot from the University of Tasmania for fruitful discussions on 3D printing. D.B.A. thanks the University of Nottingham Beacon Propulsion Futures. ; Peer reviewed
Microfluidic technologies are highly adept at generating controllable compositional gradients in fluids, a feature that has accelerated the understanding of the importance of chemical gradients in biological processes. That said, the development of versatile methods to generate controllable compositional gradients in the solid-state has been far more elusive. The ability to produce such gradients would provide access to extensive compositional libraries, thus enabling the high-throughput exploration of the parametric landscape of functional solids and devices in a resource-, time-, and cost-efficient manner. Herein, the synergic integration of microfluidic technologies is reported with blade coating to enable the controlled formation of compositional lateral gradients in solution. Subsequently, the transformation of liquid-based compositional gradients into solid-state thin films using this method is demonstrated. To demonstrate efficacy of the approach, microfluidic-assisted blade coating is used to optimize blending ratios in organic solar cells. Importantly, this novel technology can be easily extended to other solution processable systems that require the formation of solid-state compositional lateral gradients. ; Funding Agencies|Spanish Ministry of Economy, Industry and Competitiveness through the "Severo Ochoa" Programme for Centers of Excellence in RD [SEV-2015-0496, PGC2018-095411-B-I00]; European Research Council (ERC)European Research Council (ERC) [648901]; European Research Council Starting Grant microCrysFact (ERC-2015-STG) [677020]; Swiss National Science FoundationSwiss National Science Foundation (SNSF) [200021_181988]; ETH ZurichETH Zurich; Generalitat de CatalunyaGeneralitat de Catalunya; COFUND programme of the Marie Curie Actions of the 7th R&D Framework Programme of the European Union [BP-B 00256]