A gas-containing liquid generating apparatus according to an aspect of the present invention includes a gas/liquid mixing module configured to mix a gas and a liquid to generate a gas-containing liquid, a first injection module configured to inject the gas-containing liquid supplied from the gas/liquid mixing module, and a second injection module configured to inject the gas-containing liquid supplied from the first injection module to generate bubbles in the gas-containing liquid, wherein the first injection module includes a containing portion configured to contain the gas-containing liquid, a cylindrical portion having a channel configured to inject the gas-containing liquid into the containing portion, and a protruding portion provided on an inner wall surface of the cylindrical portion so as to protrude into the channel.

A microfluidic device comprises: a first channel through which a first raw material fluid flows; a second channel through which a second raw material fluid flows; a synthesis channel portion that joins the first channel and the second channel to cause the first raw material fluid and the second raw material fluid to react with each other to generate nuclei, thereby obtaining a fluid containing particles obtained by growing the nuclei; and a vibration applicator that applies vibration to the fluid flowing through the synthesis channel portion, in which the synthesis channel portion includes a mixing channel portion that is a merging portion of the first channel and the second channel, a stagnation channel portion that communicates with a downstream side of the mixing channel portion and to which vibration is applied by the vibration applicator.

A slurry treatment material containing solid particles mixed in liquid is finely pulverized, without using dispersion media, by flowing the treatment material into a vessel and through an annular fine gap formed between an inner wall of the vessel and an outer periphery face of a rotatable body mounted within the vessel. Rotation of the rotatable body subjects the treatment material to compression, expansion and shearing treatments. After passing through the annular fine gap, the treatment material flows into an ultrasonic chamber where it is irradiated with ultrasonic waves that break up and disintegrate agglomerated clumps of solid particles that may be present in the treatment material.

A fluidic device includes a base structure, a wall structure, and a cover structure bounding a fluidic passage containing a functionalized active region of at least one bulk acoustic wave (BAW) resonator structure. One or more of the wall structure, the cover structure, or a portion of the base structure includes multiple features (e.g., protrusions and/or recesses) configured to interact with fluid flowing within the fluidic passage to promote mixing between constituents of the fluid. Methods for fabricating a fluidic device, as well as methods for biological or chemical sensing using a fluidic device, are further provided.

This invention relates to a method and an apparatus for energizing and aerating fluids, comprising the step of subjecting a starting liquid to a process in order to produce an energized liquid the molecules of which are clustered and can have a specific wavelength, magnetic field, and hydrating properties.

Water charging machine wherein the water being treated is moved through a geometric series of spheres, creating a series of waterfall-like events within this invention. Oxygen may be introduced into the stream of water either upstream of this invention, or into the inside of this invention, or both, to provide a long shelf life incorporation of the gaseous oxygen into the water through vortex and waterfall actions. The water and oxygen is also exposed to a negative or positive magnetic field and a piezoelectric field as it travels through this invention, to provide a substantial Zeta potential.