Patent application number | Description | Published |
20140209463 | TRAVELING WAVE DIELECTROPHORESIS SENSING DEVICE - The present disclosure is drawn to traveling wave dielectrophoresis sensing devices and associated methods. In an example, a traveling wave dielectrophoresis sensing device can comprise an array of electromagnetic field enhancing nanostructures attached to the substrate, the electromagnetic field enhancing nanostructures including a metal; a plurality of conductive element electrically associated with the electromagnetic field enhancing nanostructures; and a controller for applying alternating and out of phase potential to the plurality of conductive elements to form traveling wave dielectrophoretic forces within the array. | 07-31-2014 |
20140211195 | PLASMON RESONANCE BASED STRAIN GAUGE - A strain gauge or other device may include a deformable medium and discrete plasmon supporting structures arranged to create one or more plasmon resonances that change with deformation of the medium and provide the device with an optical characteristic that indicates the deformation of the medium. | 07-31-2014 |
20140211199 | MULTIPLE CONCURRENT SPECTRAL ANALYSES - According to an example, apparatuses for performing multiple concurrent spectral analyses on a sample under test include an optical system to concurrently direct a plurality of light beams onto analytes at multiple locations on the sample under test, in which the plurality of light beams cause light in either or both of a Raman spectra and a non-Raman spectra to be emitted from the analytes at the multiple locations of the sample under test. The apparatuses also include a detector to concurrently acquire a plurality of spectral measurements of the light emitted from the analytes at the multiple locations of the sample under test. Example methods of performing spectral analysis include use of the apparatuses. | 07-31-2014 |
20150355093 | SURFACE ENHANCED FLUORESCENCE SPECTROSCOPY APPARATUS - According to an example, methods for forming three-dimensional (3-D) nano-particle assemblies may include depositing surface-enhanced spectroscopy (SES) elements onto respective tips of nano-fingers, in which the nano-fingers are arranged in sufficiently close proximities to each other to enable the tips of groups of adjacent ones of the nano-fingers to come into sufficiently close proximities to each other to enable the SES elements on the tips to be bonded together when the nano-fingers are partially collapsed. The methods also include causing the nano-fingers to partially collapse toward adjacent ones of the nano-fingers to cause a plurality of SES elements on respective groups of the nano-fingers to be in relatively close proximities to each other and form respective clusters of SES elements, introducing additional particles that are to attach onto the clusters of SES elements, and causing the clusters of SES elements to detach from the nano-fingers. | 12-10-2015 |
20150355097 | CHEMICAL SENSING DEVICE - The present disclosure is drawn to chemical sensing devices and associated methods. In one example, a chemical sensing device can include a substrate; an elongated nanostructure having an attachment end and a free end opposite the attachment end, the attachment end affixed to the substrate and the free end including a metal; and a metal oxide coating applied to the elongated nanostructure. In one example, a functional group can be attached to the coating via a covalent bond. | 12-10-2015 |
20160003732 | DEVICES TO DETECT A SUBSTANCE AND METHODS OF PRODUCING SUCH A DEVICE - Devices to detect a substance and methods of producing such a device are disclosed. An example device to detect a substance includes an orifice plate defining a first chamber. A substrate is coupled to the orifice plate. The substrate includes nanostructures positioned within the first chamber. The nanostructures are to react to the substance when exposed thereto. A seal is to enclose at least a portion of the first chamber to protect the nanostructures from premature exposure. | 01-07-2016 |
20160003748 | POLARIZATION SELECTIVE SURFACE ENHANCED RAMAN SPECTROSCOPY - Polarization selective surface enhanced Raman spectroscopy (SERS) includes a plurality of nanofingers arranged as a SERS multimer to exhibit a polarization-dependent plasmonic mode and one or both of a stimulus source and a Raman detector. The stimulus source is to illuminate the SERS multimer with a stimulus signal and the Raman detector is to detect a Raman scattering signal emitted by an analyte in a vicinity of the SERS multimer. One or both of the Raman scattering signal has a polarization state dictated by or associated with the polarization-dependent plasmonic mode and the stimulus signal has a polarization state corresponding to the polarization-dependent plasmonic mode. | 01-07-2016 |