Abstract: The present invention presents a device and methods of use thereof in combined electrohydrodynamic concentration and plasmonic detection of a charged species of interest using a flow-through nanohole array. The device comprises microchannels, which are linked to a substrate with arrays of through nanoholes, wherein the substrate comprises two layers, wherein one of the layers is made of insulator material and one of the layers is made of metal, whereby induction of an electric field across the nanohole array results in the species of interest concentrating inside the nanoholes and in the vicinity of the nanohole arrays. The induction of an electric field is achieved by means of an external electric field source, which is applied to the fluid containing the species of interest, resulting in electroosmotic (EO) flow. An additional pressure driven fluid flow in the microchannels, co-directional to the EO flow is applied by external means.
Type:
Grant
Filed:
May 18, 2011
Date of Patent:
March 1, 2016
Assignee:
UVic Industry Partnerships Inc.
Inventors:
Carlos Escobedo, David A. Sinton, Reuven Gordon, Alexandre Brolo
Abstract: The invention includes novel anion exchange membranes formed by in situ polymerization of at least one monomer, polymer or copolymer on a woven support membrane and their methods of formation. The woven support membrane is preferably a woven PVC membrane. The invention also includes novel cation exchange membranes with or without woven support membranes and their methods of formation. The invention encompasses a process for using the membranes in electrodialysis of ionic solutions and in particular industrial effluents or brackish water or seawater. The electrodialysis process need not include a step to remove excess ions prior to electrodialysis and produces less waste by-product and/or by-products which can be recycled.
Type:
Grant
Filed:
April 19, 2004
Date of Patent:
June 9, 2009
Assignee:
Seventy-Seventh Meridian Corporation, LLC
Inventors:
Tejraj Aminabhavi, Padmakar V. Kulkarni, Mahadevappa Y. Kariduraganavar
Abstract: A process and system for purifying water is disclosed. For example, in one embodiment, the process may be used to remove a divalent salt, such as calcium sulfate, from a water source in order to prevent the divalent salt from precipitating during the process. The water source, for instance, may be fed to an ion separating device, such as an electrodialysis device. In the electrodialysis device, an ion exchange takes place between the divalent salt and another salt, such as a monovalent salt to produce two concentrated salt streams that contain salts having greater solubility in water than the divalent salt. In one embodiment, the two salt streams that are produced may then be combined to precipitate the divalent salt in a controlled manner. During the process, various other components contained within the water feed stream may also be removed from the stream and converted into useful products. In one particular embodiment, the process is configured to receive a byproduct stream from a reverse osmosis process.
Abstract: Method of pre-treating a sample for metal analysis, the sample including a volatile alkali, by permeating the volatile alkali through a gas permeable membrane, dissolving the volatile alkali in an absorbent, passing ions through a first cation exchange membrane in electrical contact with an anode, reacting the volatile alkali with the ions, and passing the reacted volatile alkali through a second cation exchange membrane in electrical contact with a cathode, whereby the volatile alkali is removed from the sample.