A method for concentrating and crystallizing fermentable carboxylic acids, salts, and mixtures thereof may involve the use of carboxylic acids that have a defined temperature dependence of the solubility and of the osmotic pressure. The carboxylic acids may be concentrated by a membrane method and subsequently crystallized out by a cooling crystallization and isolated. In some examples, the membrane method may involve nanofiltration, reverse osmosis, and/or membrane distillation for separation into a concentrate and a permeate. Similarly, an apparatus for implementing such methods may include a nanofiltration, reverse osmosis, and/or membrane distillation unit for concentrating the carboxylic acid, and at least one cooling crystallization unit for crystallizing the carboxylic acid.”

An experiment system and method for accurate controlling of macromolecular crystallization process. The system has a platform-equipped horizontal moving slot and channel dedicated backwash module, a droplet adding control module, an observing module, a user observation computer system, and an experimental condition control module. A high-precision movement knob of the x-axis platform and the y-axis platform of the system and the accurate position control of a syringe needle are used to ensure that the macromolecular solution can be added into the correct positions of convex or concave. The crystallization induction period of the target crystal form is determined by the real-time data of the high-speed microcamera, and the crystal cultivation environment is adjusted in real time. This is simple and easy to operate, high in productivity, can be applied to the conventional experimental replication.

Methods for forming alane are described. The method includes addition of toluene at a temperature above the crystallization temperature of alane to a lower temperature solution that includes alane adduct, ether, and toluene. Upon the addition, a crystallization mixture is formed that is at or near the crystallization temperature of alane. The alane of the mixture crystallizes over a period of time to form a high purity alane polymorph.

Apparatus and methods are disclosed for separating salts, minerals, organic matter and other impurities from seawater, brackish water, wastewater or other water resources by freezing contained water in a downward vertical direction. Generally, feed water is pumped into a tank and a refrigerant contacts the upper surface of the feed water to form a layer of ice. During this process, salt and other impurities are rejected from the ice layer into the feed water below. By continuing this process, the feed water will freeze in a downward direction as the ice layer thickens. Salt and other impurities will continue to be rejected into the feed water and may be drained from the tank through a drain pipe after a block of ice is formed. Additional feed water may then be pumped into the tank to raise the block of ice for removal or ejection from the tank. The block of ice may then be melted to provide product water. Multiple tanks may be arranged in multiple levels using shared pipes and conveyor platforms to increase efficiency, scale and production.

A method of cannabinoid preservation includes separating a cannabinoid ethanol (EtOH) mixture from a cannabis extract through a filtration process; forming a slurry by combining a crystalline compound with the cannabinoid EtOH mixture; heating and agitating the slurry in a pressurized chamber to form a colloidal cannabinoid EtOH mixture; distributing the colloidal cannabinoid EtOH mixture into a tray to form an evenly distributed mixture layer; forming an evaporation vessel for the evenly distributed mixture layer through the attachment of a detachable cover to the tray; positioning and heating the evaporation vessel within a heating chamber; performing a rapid cools process as the evenly distributed mixture layer approaches approaches saturation temperature; repeating the rapid cooling process until crystal formation is detected within the evenly distributed mixture layer; and/or removing the evaporation vessel from the heating chamber upon detection of crystal formation.

The present invention relates to a method for preparing psicose by effectively utilizing a psicose crystallization mother liquor obtained in a psicose crystallization process, and specifically, relates to a method of preparation of psicose by putting a psicose crystallization mother liquor obtained in a psicose crystallization process into one or more kinds of processes selected from the group consisting of activated carbon treatment, ion purification process, simulated moving bed chromatography separation process and concentration process of psicose fraction to recycle.

Microfluidic devices and methods for investigating crystallization and/or for controlling a reaction or a phase transition are disclosed. In one embodiment, the microfluidic device includes a reservoir layer; a membrane disposed on the reservoir layer; a wetting control layer disposed on the membrane; and a storage layer disposed on the wetting control layer, wherein the wetting control layer and the storage layer define a microfluidic channel comprising an upstream portion, a downstream portion, a first fluid path in communication with the upstream and the downstream portions, and a storage well positioned within the first fluid path, wherein the wetting control layer includes a fluid passageway in communication with the storage well and the membrane, and wherein the wetting control layer wets a first fluid introduced into the microfluidic channel, the first fluid comprising a hydrophilic, lipophilic, fluorophilic or gas phase as the continuous phase in the microfluidic channel.

The invention relates to recombinant microorganisms and methods for producing mogroside compounds and mogroside precursors.

The invention relates to recombinant microorganisms and methods for producing mogroside compounds and mogroside precursors.

Embodiments of the invention provide a composition of a particulate coformulation which includes particles containing an active substance and an additive, wherein each particle contains a relative additive concentration increasing radially outwards from a particle center to a particle surface along a finite gradient. In one example, the particle surface is an additive-rich surface without a distinct physical boundary between the particle center and the particle surface. The relative additive concentration may have a continuous rate of change across the finite gradient. In some examples, an active substance:additive ratio of the particle surface is sufficiently low to form a protective surface layer around the active substance. Generally, the particle surface is free of the active substance.