Abstract: A system and method for forming a low cost optical sensor array. The sensor includes an optical fiber; a first nanocomposite thin film along at least a portion of the optical fiber for interrogating a first parameter through a correlated signal having a first wavelength; and a second nanocomposite thin film along at least a portion of the optical fiber for interrogating a second parameter through a correlated signal having a second wavelength different from the wavelength of the first parameter.

Abstract: Disclosed herein are p-n metal oxide semiconductor (MOS) heterostructure-based sensors and systems. The sensors and systems described herein can include sensing element that comprises a first region comprising a p-type MOS material (e.g., NiO) and a second region comprising an n-type MOS material (e.g., In2O3). These sensors and systems can exhibit sensitivity and selectivity to NH3 at ppb levels, while discriminating against CO, NO, or a combination thereof at concentrations a thousand-fold higher (ppm) and spread over a considerable range (0-20 ppm). These sensors and systems can be used to detect and/or quantify NH3 in samples, including biological samples (e.g., breath samples) and combustion gases.

Abstract: A system and method for forming a low cost optical sensor array. The sensor includes an optical fiber; a first nanocomposite thin film along at least a portion of the optical fiber for interrogating a first parameter through a correlated signal having a first wavelength; and a second nanocomposite thin film along at least a portion of the optical fiber for interrogating a second parameter through a correlated signal having a second wavelength different from the wavelength of the first parameter.

Abstract: The disclosure relates to a method for H2 sensing in a gas stream utilizing a hydrogen sensing material. The hydrogen sensing material is comprised of Pd-based or Pt-based nanoparticles having an average nanoparticle diameter of less than about 100 nanometers dispersed in an inert matrix having a bandgap greater than or equal to 5 eV, and an oxygen ion conductivity less than approximately 10?7 S/cm at a temperature of 700° C. Exemplary inert matrix materials include SiO2, Al2O3, and Si3N4 as well as modifications to modify the effective refractive indices through combinations and/or doping of such materials. Additional exemplary matrix materials consist of zeolitic and zeolite-derivative structures which are microporous and/or nanoporous such as the alumino-silicates and the dealuminated zeolite NaA structures.

Abstract: Disclosed herein are p-n metal oxide semiconductor (MOS) heterostructure-based sensors and systems. The sensors and systems described herein can include sensing element that comprises a first region comprising a p-type MOS material (e.g., NiO) and a second region comprising an n-type MOS material (e.g., In2O3). These sensors and systems can exhibit sensitivity and selectivity to NH3 at ppb levels, while discriminating against CO, NO, or a combination thereof at concentrations a thousand-fold higher (ppm) and spread over a considerable range (0-20 ppm). These sensors and systems can be used to detect and/or quantify NH3 in samples, including biological samples (e.g., breath samples) and combustion gases.

Abstract: A method of making a microporous crystal material, comprising: a. forming a mixture comprising NaOH, water, and one or more of an aluminum source, a silicon source, and a phosphate source, whereupon the mixture forms a gel; b. heating the gel for a first time period, whereupon a first volume of water is removed from the gel and micoroporous crystal nuclei form, the nuclei having a framework; and c.(if a membrane is to be formed) applying the gel to a solid support seeded with microporous crystals having a framework that is the same as the framework of the nuclei; d. heating the gel for a second time period. during which a second volume of water is added to the gel; wherein the rate of addition of the second volume of water is between about 0.5 and about 2.0 fold the rate of removal of the first volume of water.

Abstract: Some aspects of the present disclosure relate to a sensor design that exploits the different majority carriers (holes/electrons) in WO3 and Cr2O3 to build sensitivity and selectivity to NO at ppb levels, while discriminating against CO at concentrations a thousand-fold higher (ppm) and spread over a considerable range (0-20 ppm). Practical application of this sensor system for detecting NO in human breath is demonstrated.

Abstract: This disclosure provides methods of making microporous crystals and microporous crystal membranes.