Microfluidic devices that are configured to use centrifugal forces to bias particles into one or more capture regions based on their individual sizes are described.

An apparatus includes a pipe through which a multiphase fluid flows, with a transparent window structure formed in the pipe. A collimated light source emits light through the transparent window structure into the pipe having a wavelength at which a component of a desired phase of the multiphase fluid is absorptive. A photodetector is positioned such that the emitted light passes through the multiphase fluid in the pipe to impinge upon the photodetector. The photodetector has an actual dynamic range for collimated light detection. Processing circuitry is configured to continuously adjust a power of the collimated light source dependent upon an output level of the photodetector so as to cause measurement of the emitted light over an effective dynamic range greater than the actual dynamic range, and determine a property of the multiphase fluid as a function of the power of the collimated light source.

A solution for controlling cellulose processing includes performing optically first measurements of the cellulose during the processing, performing second measurements of the cellulose by directing optical radiation to the cellulose, the radiation including at least one beam that is polarized and at least one separate beam is non-polarized, measuring attenuations and parameters of polarization of the radiation interacted with the cellulose and determining size of particles in the cellulose based on at least one comparison of the parameters of polarization and the attenuations. The processing is controlled based on the first measurements until a given threshold of the first measurements has been reached and thereafter controlling the processing based on the second measurements.

A system is provided for the quantitative magnetic separation of magnetic objects (e.g., particles or cells). The system uses magnetic ratcheting over arrays of ferromagnetic elements having gradient spacing manifested in various pitch zones that are encountered by the magnetic objects as they traverse the array. The system can be used to separate and concentrate magnetic objects based on iron oxide content. For cells, different phenotypes may be separated based, for example, on surface expression of proteins or molecules that are bound to magnetic particles. The system includes a substrate or chip having the array of ferromagnetic elements with increasing lateral pitch and an externally driven magnet device that generates a cycling magnetic field. Magnetic objects with higher IOC separate and equilibrate along the array at larger pitches. The system can be used for the differential sorting of particles and cells of interest.

Certain aspects are directed towards systems and techniques for identifying fracture driven interactions. One example method generally includes: accessing well data comprising a series of well data parameters of a first well corresponding to a time when the first well is being hydraulically fractured; accessing well data comprising a series of pressure values for a second well offset from the first well, the series of pressure values corresponding to the time when the first well is being hydraulically fractured; identifying a time for an event from the series of well data parameters; identifying an offset pressure increase in the series of pressure values for the second well; and generating an indication of fracture driven interaction when the offset pressure increase is within a threshold of the event.

A test apparatus can measuring particle plugging of a simulated fracture. The test apparatus can include a first test component having a first surface and a second test component having a second surface. The second test component can be positionable relative to the first test component to create a simulated fracture between the first surface and the second surface. The test apparatus can include a visualization area of at least one of the first test component or the second test component can be positioned between a fluid inlet and a fluid outlet along at least a portion of the simulated fracture.

An evaluation method of abrasive grains used in an ingot-cutting slurry includes: an evaluation solution preparation step in which abrasive grains including polishing grains and impurities are dissolved in a solvent to prepare an evaluation solution; a sedimentation step in which a container containing the evaluation solution is left still to settle the polishing grains; a measurement step in which a turbidity of supernatant of the evaluation solution is measured using the measurement device; and an estimation step in which an amount of the impurities is estimated based on the measurement result of the turbidity of the supernatant.

The system and cuvette insert is disclosed where the insert has a top surface that includes a first and second vertical channel opening. A first vertical channel extends downwardly from the first vertical channel opening and a second vertical channel extending from the second vertical channel opening. The insert also has a side wall into which the viewing chamber is formed. The viewing chamber has an upper viewing chamber wall and a lower viewing chamber wall. These walls define the viewing chamber and may be substantially parallel to the floor of the cuvette into which the insert is inserted. At the end of the viewing chamber is a reflecting wall. The viewing chamber has two ends, with one end in fluid connection with the first vertical channel and the other end in fluid connection with the second vertical channel. The fluid connection between the viewing chamber and the first vertical channel may also include a first lateral channel. Likewise the fluid connection between the viewing chamber and the second vertical channel may include a second lateral channel.

A fluid medium monitoring apparatus of the present invention comprises: a light source unit for irradiating light; a first collimator unit for collimating light irradiated from the light source unit; a flow cell unit in which a fluid medium flows and light is allowed to absorb the wavelength of the fluid medium while proceeding along the moving direction of the fluid medium; and a light detection unit for detecting the wavelength of the light passing through the flow cell unit.

A detector includes a substrate including a first surface and a second surface opposite to the first surface, a funnel-shaped recess extending from the second surface of the substrate to the first surface of the substrate, a conductive layer disposed below the first surface of the substrate, an insulating layer disposed between the substrate and the conductive layer, and a first through via extending through the conductive layer and the insulating layer, and coupled to the funnel-shaped recess.