A chromatography and synthesis column that includes a main tube, a plurality of lower media ports, and an internal groove. The internal groove is formed in an interior surface of the main tube and selectively provides an internal flow path between each of the internal lower media ports. This, in turn, facilitates quick and easy maintenance of the internal lower media ports and other components of the chromatography and synthesis column.

A liquid chromatography apparatus includes a diffusion-bonded separation column comprising a lower substrate comprising titanium, an upper substrate comprising titanium, and a titanium patterned foil disposed between the lower substrate and the upper substrate. The lower substrate, titanium patterned foil, and upper substrate are diffusion bonded together to form a fluid path extending from an inlet port to an outlet port, wherein walls defining the fluid path within the diffusion-bonded separation column include a titanium surface coating.

Exemplary embodiments integrate a tee or valve into an outlet end fitting of a liquid chromatography column. The tee or valve is suitable for providing additional fluidic flow paths to ports of the end fitting and eliminates the need for post-column fluidic conduits connecting to tees or valves to insert fluidic inputs or divert flow to outputs. This integration decreases the distance that eluent from the liquid chromatography column has to travel to reach a detector relative to systems that use external tees or valves while providing tee/valve functionality and reducing the fluidic volume post-column. As a result, the exemplary embodiments help decrease sample dispersion.

A thermal conductivity detector includes: a first flow path (4) in which a filament (2) is arranged; a second flow path (6) provided separately from the first flow path (4); an introduction flow path (8) configured to fluidly communicate between an upstream of the first flow path (4) and an upstream end of the second flow path (6); a sample inlet (10) configured to introduce a sample gas to the introduction flow path (8); a first gas inlet (12) provided between the sample inlet (10) in the introduction flow path (8) and an upstream end of the first flow path (4); a second gas inlet (14) provided between the sample inlet (10) in the introduction flow path (8) and an upstream end of the second flow path (6); a carrier gas supply source (18); a selector (22) configured to selectively introduce the carrier gas from the carrier gas supply source (18) to one of the first gas inlet (12) and the second gas inlet (14); and a detection circuit (24) configured to detect a component in a sample gas via the filament (2), wherein when the carrier gas from the carrier gas supply source (18) is guided to the first gas inlet (12), a reference phase in which only the carrier gas flows through the first flow path (4) is formed, when the carrier gas from the carrier gas supply source (18) is guided to the second gas inlet (14), a sampling phase in which the sample gas flows through the first flow path (4) is formed, and wherein fluid resistance of the first flow path (4) and flow resistance of the second flow path (6) are designed such that a ratio of a difference between a reference flow rate and a sampling flow rate to each of the reference flow rate and the sampling flow rate becomes 15% or less, the reference flow rate being a flow rate of a gas flowing through the first flow path (4) in the reference phase, the sampling flow rate being a flow rate of gases flowing through the first flow path (4) in the sampling phase.

Chromatography and synthesis columns, assemblies, components, and methods of assembly and disassembly are disclosed including a support assembly having lifting mechanisms in each of the legs to raise and lower a frame secured to the column, a swing arm and/or carriage guiding movement of a bottom plate of the column, a bolt-free coupling between the main tube and bottom plate of the column, and upper and lower slurry ports in the main tube of the column.

Provide is a novel microcolumn that contains a packing material and can be connected to a capillary tube. A connection structure includes a connector or a microcolumn and a plurality (e.g., two) of capillary tubes. The connecting structure is configured such that the microcolumn (or connector) and the capillary tube are in fluid communication. In one embodiment, the connection structure can be configured to be liquid-tight (to prevent liquid from flowing out from the interior of the structure to the exterior).

The present disclosure relates to methodologies, systems, and apparatus for controlling fluid flow within a chromatography system. The chromatography system includes a mobile phase pump configured to pump a liquid mobile phase through a column and a restrictor positioned downstream of the column and upstream of a detector. The system also includes a valve configured to operate in at least two positions. In a first position, the valve is configured to direct the output of the column to bypass the valve and reach the detector, while in the second position the valve directs the output of the column to waste.

A gas chromatograph with a positioning system for the inlet liner and the column includes a column and the positioning system for the inlet liner and the column. The column is configured for gas chromatography. Wherein, the positioning system for the inlet liner and the column is configured to position the inlet liner and the column with respect to one another. The positioning system for the inlet liner and the column is configured to repeatably and optimally position the inlet liner and the column with respect to one another. The positioning system for the inlet liner and the column positions the inlet liner in a perpendicular orientation to the column.

Chromatographic systems for size exclusion chromatography (SEC) are provided that comprise an inlet, an outlet, an analytic column having a first interior volume that has a first length and a first cross-sectional area normal to the first length, the first interior volume containing a first stationary phase, and a guard column having a second interior volume that has a second length and a second cross-sectional area normal to the second length, the second interior volume containing a second stationary phase. The inlet is in fluid communication with the guard column, the guard column is in fluid communication with the analytic column, and the analytic column is in fluid communication with the outlet. Moreover, the second length is smaller than the first length, and the second cross-sectional area is smaller than the first cross-sectional area.

The present disclosure relates to methodologies, systems, apparatus, and kits for introducing a sample within a chromatography system. A makeup pump is configured to pump a makeup fluid through a first restrictor into the chromatography system upstream of the column and downstream of a mobile phase pump. The first restrictor is located upstream of a column and downstream of makeup pump and a sample fluid pump. Decreasing an output volume of the makeup pump can direct a sample fluid from the sample fluid pump through the first restrictor to the column. Increasing an output volume of the makeup pump can direct the sample fluid to a second restrictor located downstream of the makeup pump and in parallel with the column and the detector.