Systems and methods for confining droplets within a microfluidic channel as well as systems and methods for packing droplets are provided. More specifically, a system and method are provided for controlling the introduction and removal of oil into a microfluidic channel in order to control where drops are allowed to flow within that channel.

Systems and methods for confining droplets within a microfluidic channel as well as systems and methods for packing droplets are provided. More specifically, a system and method are provided for controlling the introduction and removal of oil into a microfluidic channel in order to control where drops are allowed to flow within that channel.

A fluid flow-through device and a photochemical reactor. The fluid flow-through device (1) includes an outer tube (2) having an outer surface (21) and an inner surface (22); and an inner tube (3) having an outer surface (31) and an inner surface (32), the inner tube being disposed inside the outer tube and forming a channel of a fluid by the inner surface of the outer tube and the outer surface, with a distance between the inner surface of the outer tube and the outer surface of the inner tube in a thickness direction of the outer tube being from 100 nm to 5 mm. The photochemical reactor includes the fluid flow-through device and a photocatalyst disposed on at least one surface of the inner surface of the outer tube and the outer surface of the inner tube.

A continuous flow reactor for the efficient synthesis of nanoparticles with a high degree of crystallinity, uniform particle size, and homogenous stoichiometry throughout the crystal is described. Disclosed embodiments include a flow reactor with an energy source for rapid nucleation of the procurors following by a separate heating source for growing the nucleates. Segmented flow may be provided to facilitate mixing and uniform energy absorption of the precursors, and post production quality testing in communication with a control system allow automatic real-time adjustment of the production parameters. The nucleation energy source can be monomodal, multimodal, or multivariable frequency microwave energy and tuned to allow different precursors to nucleate at substantially the same time thereby resulting in a substantially homogenous nanoparticle. A shell application system may also be provided to allow one or more shell layers to be formed onto each nanoparticle.

Systems and methods taught herein enable simultaneous forward and side detection of light originating within a microfluidic channel disposed in a substrate. At least a portion of the microfluidic channel is located in the substrate relative to a first side surface of the substrate to enable simultaneous detection paths with respect to extinction (i.e., 0) and side detection (i.e., 90). The location of the microfluidic channel as taught herein enables a maximal half-angle for a ray of light passing from a center of the portion of the microfluidic channel through the first side surface to be in a range from 25 to 90 degrees in some embodiments. By placing at least the portion of the microfluidic channel proximate to the side surface of the substrate, a significantly greater proportion of light emitted or scattered from a particle within the microfluidic channel can be collected and imaged on a detector as compared to conventional particle processing chips.

Systems and methods enable simultaneous forward and side detection of light originating within a microfluidic channel disposed in a substrate. At least a portion of the microfluidic channel is located in the substrate relative to a first side surface of the substrate to enable simultaneous detection paths with respect to extinction and side detection. The location of the microfluidic channel enables a maximal half-angle for a ray of light passing from a center of the portion of the microfluidic channel through the first side surface to be in a range from 25 to 90 degrees in some embodiments. By placing at least the portion of the microfluidic channel proximate to the side surface of the substrate, a significantly greater proportion of light emitted or scattered from a particle within the microfluidic channel can be collected and imaged on a detector as compared to conventional particle processing chips.

The present disclosure concerns a micro-flow system for synthesis of a compound, comprising a tubing reactor configured to flow a reactant within its lumen thereof, an actuator for regulating the flow of the reactant in the lumen and a heterogeneous catalyst in fluid communication with the lumen. The present disclosure also concerns a method of micro-flow synthesising a compound using the micro-flow system.