Kyoung-Ik Min

Submillisecond organic synthesis: Outpacing Fries rearrangement through microfluidic rapid mixing

Rapid mixing to race past rearrangement Chemistry relies on encounters between reactive partners. Sometimes one of the partners changes shape during the wait, spoiling the desired outcome. Kim et al. designed a microfluidic device to keep such botched encounters from happening. The device operates at low temperatures to keep individual reactants from isomerizing. It also achieves fast flow rates to maximize encounters between reactants on a microsecond time scale. The authors showcase the device by achieving bimolecular carbon-carbon coupling before one of the reagents can undergo a Fries rearrangement that would shift a neighboring group to the coupling site. Science, this issue p. 691 Bimolecular coupling can outpace a fast unimolecular rearrangement via extremely rapid low-temperature microfluidic mixing. In chemical synthesis, rapid intramolecular rearrangements often foil attempts at site-selective bimolecular functionalization. We developed a microfluidic technique that outpaces the very rapid anionic Fries rearrangement to chemoselectively functionalize iodophenyl carbamates at the ortho position. Central to the technique is a chip microreactor of our design, which can deliver a reaction time in the submillisecond range even at cryogenic temperatures. The microreactor was applied to the synthesis of afesal, a bioactive molecule exhibiting anthelmintic activity, to demonstrate its potential for practical synthesis and production.

Continuous flow synthesis of toxic ethyl diazoacetate for utilization in an integrated microfluidic system

An integrated microfluidic system for multiple reactions and separations of hazardous ethyl diazoacetate is presented. The integrated techniques include: a droplet technique for liquid–liquid and/or gas–liquid separation and in situ generation of the toxic reagent, a dual channel membrane technique based on a cheap polymeric microseparator for liquid–liquid separation, and a capillary microreactor for carrying out cascade reactions in a sequential and continuous manner.

Novel inorganic polymer derived microreactors for organic microchemistry applications

Microreactors fabricated with optically transparent inorganic polymers from two types of precursors using a UV-microimprinting process demonstrated reliable solvent resistance and capability for performing three model organic synthetic reactions, which were compared with batch systems and glass based microreactors.

Monolithic and Flexible Polyimide Film Microreactors for Organic Microchemical Applications Fabricated by Laser Ablation

Glass, silicon, poly(dimethylsil-oxane) (PDMS), and poly(methylmethacrylate) (PMMA)have been used for the fabrication of miniaturized devices.Fabrication with glass or silicon substrates requires relativelycomplex processes, and the fabrication costs are high.Relatively cheap polymers such as PDMS or PMMA arenot suitable for application in organic chemical processesowing to their low chemical stability and easy swelling.

A doubly cross-linked nano-adhesive for the reliable sealing of flexible microfluidic devices

Along with the expansion of microfluidics into many areas of applications such as sensors, microreactors and analytical tools, many other materials besides poly(dimethylsiloxane) (PDMS) have been suggested such as poly(imide) (PI) or poly(ethylene terephthalate) (PET). However, the sealing methods for these materials are not reliable in that many of the methods are specific to the substrate materials. Here, we report a novel robust doubly cross-linked nano-adhesive (DCNA) for bonding of various heterogeneous substrates. By depositing 200 nm of epoxy-containing polymer, poly(glycidyl methacrylate), via initiated chemical vapour deposition (iCVD) onto various substrates and cross-linking them with ethylenediamine, a strong adhesion was obtained between the substrates. This adhesive system was not only able to bond various difficult-to-bond substrates, such as PET or PI, but it could also preserve the complicated morphology of the surfaces owing to the thin nature of the DCNA system. The DCNA allowed fabrication of microfluidic devices using both rigid substrates, such as silicon wafer and glass, and flexible substrates, such as PDMS, PET and PI. The burst pressure of the devices sealed with DCNA exceeded 2.5 MPa, with a maximum burst pressure of 11.7 MPa. Furthermore, the adhesive system demonstrated an exceptional chemical and thermal resistance. The adhesion strength of the adhesive sandwiched between glass substrates remained the same even after a 10 day exposure to strong organic solvents such as toluene, acetone, and tetrahydrofuran (THF). Also, exposure to 200 °C for 15 h was not able to damage the adhesion strength. Using the high adhesive strength and flexibility of DCNA, flexible microfluidic devices that can be completely folded or rolled without any delamination during the operation were fabricated. The DCNA bonding is highly versatile in the sealing of microfluidic systems, and is compatible with a wide selection of materials, including flexible and foldable substrates, even upon sealing few-μm-sized channels.

Micro-total envelope system with silicon nanowire separator for safe carcinogenic chemistry

Exploration and expansion of the chemistries involving toxic or carcinogenic reagents are severely limited by the health hazards their presence poses. Here, we present a micro-total envelope system (μ-TES) and an automated total process for the generation of the carcinogenic reagent, its purification and its utilization for a desired synthesis that is totally enveloped from being exposed to the carcinogen. A unique microseparator is developed on the basis of SiNWs structure to replace the usual exposure-prone distillation in separating the generated reagent. Chloromethyl methyl ether chemistry is explored as a carcinogenic model in demonstrating the efficiency of the μ-TES that is fully automated so that feeding the ingredients for the generation is all it takes to produce the desired product. Syntheses taking days can be accomplished safely in minutes with excellent yields, which bodes well for elevating the carcinogenic chemistry to new unexplored dimensions.

Direct Fabrication of Free-Standing MOF Superstructures with Desired Shapes by Micro-Confined Interfacial Synthesis

Recently, metal-organic frameworks (MOFs) with multifunctional pore chemistry have been intensively investigated for positioning the desired morphology at specific locations onto substrates for manufacturing devices. Herein, we develop a micro-confined interfacial synthesis (MIS) approach for fabrication of a variety of free-standing MOF superstructures with desired shapes. This approach for engineering MOFs provides three key features: 1) in situ synthesis of various free-standing MOF superstructures with controlled compositions, shape, and thickness using a mold membrane; 2) adding magnetic functionality into MOF superstructures by loading with Fe3 O4 nanoparticles; 3) transferring the synthesized MOF superstructural array on to flat or curved surface of various substrates. The MIS route with versatile potential opens the door for a number of new perspectives in various applications.

Covalent Self‐Assembly and One‐Step Photocrosslinking of Tyrosine‐rich Oligopeptides to Form Diverse Nanostructures

We present covalently self-assembled peptide hollow nanocapsule and peptide lamella. These biomimetic dityrosine peptide nanostructures are synthesized by one-step photopolymerization of a tyrosine-rich short peptide without the aid of a template. This simple approach offers direct synthesis of fluorescent peptide nanocages and free-standing thin films. The simple crosslinked peptide lamella films provide robust mechanical properties with an elastic modulus of approximately 30 GPa and a hardness of 740 MPa. These nanostructures also allow for the design of peptidosomes. The approach taken here represents a rare example of covalent self-assembly of short peptides into nano-objects, which may be useful as microcompartments and separation membranes.