A catalytic reactor includes: a reaction-side flow channel in which a reaction fluid flows; a structured catalyst removably located in the reaction-side flow channel; and a protrusion formed in the structured catalyst or an inner surface of the reaction-side flow channel, having a height forming a clearance between the structured catalyst and the inner surface of the reaction-side flow channel.

A spatially selective surface functionalization device configured to generate a pattern of micro plasmas and functionalize a substrate surface may include: a pattern management system, a patterning head, and a gas delivery system, wherein the gas delivery system provides a primed gas mixture for forming a plasma between the patterning head and a target substrate below the patterning head. A patterning head may generate a distribution of micro plasmas from individual directed beams of electrons with spatial separation. A pattern management system may store and manipulate information about a pattern of surface functionalization and generate instructions for regulating a distribution of micro plasmas that functionalize a substrate surface.

In a flow path chip including a first plate, a second plate joined to the first plate, and a porous body disposed between the first plate and the second plate, the flow path chip having a flow path formed by the first plate and the second plate, wherein the flow path includes a storage portion storing the porous body, the storage portion is defined by a first surface formed by part of a surface of the first plate and a second surface formed by part of a surface of the second plate, at least part of the first surface and at least part of the second surface are each a surface of an easily-deformable layer, and the porous body is sandwiched between the first plate and the second plate in a state that at least part of the easily-deformable layer is deformed.

Methods, systems and apparatuses are disclosed for a Fischer-Tropsch (FT) operation including a first FT stage comprising at least one FT reactor having a first FT catalyst and a first heat transfer surface area to catalyst volume configured to receive a first feed comprising synthesis gas and to convert a first portion of the synthesis gas in the first feed into first FT products. The disclosure also provides for a separation apparatus configured to separate the first FT products into first liquid FT hydrocarbons and first FT tail gas comprising unreacted syngas and for a second FT stage comprising at least one second FT reactor, having a second FT catalyst and a second heat transfer surface area to catalyst volume different from the first heat transfer surface area to catalyst volume, and configured to receive a second feed comprising the first FT tail gas and to convert at least a portion of the second feed into a second FT products.

Provided is an analytical device including: a self-flowing microfluidic system, having a sample extraction location, at least one sample preparation location, and at least one sample analytical chamber; wherein the sample extraction location, the sample preparation location, and the at least one sample analytical chamber are interconnected by at least one microfluidic channel on a first substrate; and a signal readout system, having at least one sample analysis elements, and a data gathering and processing element.

Provided is an analytical device including: a self-flowing microfluidic system, having a sample extraction location, at least one sample preparation location, and at least one sample analytical chamber; wherein the sample extraction location, the sample preparation location, and the at least one sample analytical chamber are interconnected by at least one microfluidic channel on a first substrate; and a signal readout system, having at least one sample analysis elements, and a data gathering and processing element.

A self-flowing microfluidic analytical chip may undergo spontaneous flow of a fluidic sample through microfluidic channels without an internal or external pump or corresponding pumping support hardware for fluid pumping. A self-flowing microfluidic analytical device includes sample preparation locations, sample analysis locations, and sample extraction locations connected by a network of microfluidic channels. Self-flowing characteristics of a microfluidic analytical chip result from maskless patterning of a substrate surface, where sequential passes of a patterning head preserve, rather than destroy, a pattern of surface functionalization. Self-flowing properties may be preserved by avoiding use of mask-removing solvents common to mask-removal steps in traditional microfluidic chip manufacturing processes.

A self-flowing microfluidic analytical chip may undergo spontaneous flow of a fluidic sample through microfluidic channels without an internal or external pump or corresponding pumping support hardware for fluid pumping. A self-flowing microfluidic analytical device includes sample preparation locations, sample analysis locations, and sample extraction locations connected by a network of microfluidic channels. Self-flowing characteristics of a microfluidic analytical chip result from maskless patterning of a substrate surface, where sequential passes of a patterning head preserve, rather than destroy, a pattern of surface functionalization. Self-flowing properties may be preserved by avoiding use of mask-removing solvents common to mask-removal steps in traditional microfluidic chip manufacturing processes.

A spatially selective surface functionalization device configured to generate a pattern of micro plasmas and functionalize a substrate surface may include: a pattern management system, a patterning head, and a gas delivery system, wherein the gas delivery system provides a primed gas mixture for forming a plasma between the patterning head and a target substrate below the patterning head. A patterning head may generate a distribution of micro plasmas from individual directed beams of electrons with spatial separation. A pattern management system may store and manipulate information about a pattern of surface functionalization and generate instructions for regulating a distribution of micro plasmas that functionalize a substrate surface.

A flow control system for a microfluidic device includes: a plurality of fluid flow controllers, each fluid flow controller associated with a respective microfluidic device inlet of the microfluidic device, and wherein each fluid flow controller includes: a controller inlet for receiving a fluid flow, a first fluid channel and a second fluid channel, each of the first and the second fluid channels having a first end connected to the controller inlet and a second end connected to a supply channel, and a valve for selecting the fluid flow to be passed from the controller inlet to the first fluid channel or to the second fluid channel, wherein the first fluid channel has a first flow resistance that smaller than a second flow resistance of the second fluid channel.