Abstract: Apparatuses, systems, and methods for ion traps are described herein. One apparatus includes a number of microwave (MW) rails and a number of radio frequency (RF) rails formed with substantially parallel longitudinal axes and with substantially coplanar upper surfaces. The apparatus includes two sequences of direct current (DC) electrodes with each sequence formed to extend substantially parallel to the substantially parallel longitudinal axes of the MW rails and the RF rails. The apparatus further includes a number of through-silicon vias (TSVs) formed through a substrate of the ion trap and a trench capacitor formed in the substrate around at least one TSV.

Abstract: Methods, apparatuses, and systems for alignment of an optical component are described herein. One method includes forming a pit in a substrate, placing an optical component in the pit, and aligning the optical component such that an edge of the optical component is in physical contact with an alignment edge of the pit.

Abstract: Devices, systems, and methods for ion trapping with integrated electromagnets are described herein. One device includes a plurality of electrodes configured to trap an ion above a surface of the device, a medial coil and a plurality of peripheral coils, each positioned at a respective radial angle associated with the medial coil, wherein the medial coil is configured to generate a first magnetic field having a first orientation, and wherein the peripheral coils are configured to generate a second magnetic field having a second orientation that opposes the first orientation.

Abstract: Devices, methods, and systems for trapping multiple ions are described herein. One device includes two or more ovens wherein each oven includes a heating element and a cavity for emitting atoms of a particular atomic species from an atomic source substance, a substrate having a number of apertures that allow atoms emitted from the atomic source substance to exit the oven and enter an ion trapping area and wherein each oven is positioned at a different ion loading area within the ion trapping area, and a plurality of electrodes that can be charged and wherein the charge can be used to selectively control the movement of a particular ion from a particular loading area to a particular ion trap location.

Abstract: Devices, systems, and methods for ion trapping with integrated electromagnets are described herein. One device includes a plurality of electrodes configured to trap an ion above a surface of the device, a medial coil and a plurality of peripheral coils, each positioned at a respective radial angle associated with the medial coil, wherein the medial coil is configured to generate a first magnetic field having a first orientation, and wherein the peripheral coils are configured to generate a second magnetic field having a second orientation that opposes the first orientation.

Abstract: Stand-off spectrometry systems and methods are described herein. One system includes a laser source configured to emit a single-spectral light, and an optical frequency comb (OFC) coupled to the laser source and configured to generate, using the single-spectral light, a multi-spectral light to determine an absorption spectrum of a substance.

Abstract: Methods, apparatuses, and systems for design, fabrication, and use of an ion trap with variable pitch electrodes are described herein. One apparatus includes an ion trap and a plurality of variable pitch electrodes disposed on the ion trap. A respective electrode of the plurality of electrodes can have a first pitch in a first region of the trap and a second pitch in a second region of the trap.

Abstract: Apparatuses, systems, and methods for ion traps are described herein. One apparatus includes a number of microwave (MW) rails and a number of radio frequency (RF) rails formed with substantially parallel longitudinal axes and with substantially coplanar upper surfaces. The apparatus includes two sequences of direct current (DC) electrodes with each sequence formed to extend substantially parallel to the substantially parallel longitudinal axes of the MW rails and the RF rails. The apparatus further includes a number of through-silicon vias (TSVs) formed through a substrate of the ion trap and a trench capacitor formed in the substrate around at least one TSV.

Abstract: Methods, apparatuses, and systems for design, fabrication, and use of an optical bench, as well as alignment and attachment of optical fibers are described herein. One apparatus includes an apparatus body, a first channel within the apparatus body for positioning of a first optical fiber directed along a first axis and a second channel within the apparatus body for positioning of a second optical fiber directed along a second axis, wherein the first axis is orthogonal to the second axis. The apparatus also includes a third optical fiber directed along the second axis and an optical element positioned along the first channel and second channel to focus a first light beam from the first optical fiber along the first axis and focus a second light beam from the second optical fiber along the second axis.

Abstract: Devices, methods, and systems for ion trapping are described herein. One device includes a through-silicon via (TSV) and a trench capacitor formed around the TSV.

Abstract: Devices, methods, and systems for ion trapping are described herein. One device includes a through-silicon via (TSV) and a trench capacitor formed around the TSV.

Abstract: A device includes a resonator having an oscillating portion with dimensions chosen to lead to a desired resonant frequency. A light source is positioned to provide light along the length of the oscillating portion at a specific wave length. A detector detects a change in oscillation of the resonator responsive to the wave pressure produced by the light source heating a gas. The light source is modulated with a frequency the same as the resonant frequency of the resonator.

Abstract: Generally disclosed herein are transducers that can convert sound energy into electrical signals, such as to detect if a pressure wave includes a specific frequency. Methods of using the transducers and systems that include the transducers are disclosed herein as well. A transducer can include a first probe plate, a second probe plate, a ground plate situated between the first and second probe plates, a first electret film adjacent to a first side of the ground plate and situated between the first and second probe plates, and a second electret film adjacent to a second side of the ground plate and situated between the first and second probe plates, the second side opposite the first side.

Abstract: Generally disclosed herein are transducers that can convert sound energy into electrical signals, such as to detect if a pressure wave includes a specific frequency. Methods of using the transducers and systems that include the transducers are disclosed herein as well. A transducer can include a first probe plate, a second probe plate, a ground plate situated between the first and second probe plates, a first electret film adjacent to a first side of the ground plate and situated between the first and second probe plates, and a second electret film adjacent to a second side of the ground plate and situated between the first and second probe plates, the second side opposite the first side.

Abstract: An approach for making thin flexible circuits. A layer of dielectric may have one or two surfaces coated with metal. The dielectric and the metal may each have a sub-mil thickness. The dielectric may be held in a fixture for fabrication like that of integrated circuits. The metal may be patterned and have components attached. More layers of dielectric and patterned metal may be added to the flexible circuit. Also bond pads and connecting vias may be fabricated in the flexible circuit. The flexible circuit may be cut into a plurality of smaller flexible circuits.

Abstract: An apparatus for detecting gas concentrations includes a coded filter to oscillate proximate a resonant frequency. A photo detector is positioned below the coded filter such that the coded filter selectively blocks light that is directed at the photo detector. Optics are positioned to project spectral information on to the coded filter. A processor analyzes a signal received from the photo detector. The processor is adapted to weight a harmonic attic signal.

Abstract: A device for detecting gas concentrations includes a movable coded filter. An optical element is positioned to receive gas filtered light and spectrally separate the gas filtered light. A photo detector is positioned to receive the spectrally separated light through slits in the moveable coded filter to provide an AC signal representative of a selected gas.

Abstract: Stand-off spectrometry systems and methods are described herein. One system includes a laser source configured to emit a single-spectral light, and an optical frequency comb (OFC) coupled to the laser source and configured to generate, using the single-spectral light, a multi-spectral light to determine an absorption spectrum of a substance.

Abstract: In general, the disclosure is directed to techniques for determining the position of a piston within a linear actuator, such as a hydraulic cylinder, in a more cost effective and less labor-intensive fashion compared to current techniques for determining the position of a piston within a linear actuator. One or more magnets may be operably coupled to the piston, and a linear array of sensors may be disposed along an exterior length of the linear actuator. The sensors may measure the magnetic field generated by the magnet and, based on the measured magnetic field, may determine the location of the piston within the linear actuator.

Abstract: Some embodiments are directed to a photoacoustic sensor. The photoacoustic sensor may comprise: a gas cell with an opening; a light source to generate to radiate a sample gas within the gas cell; an optical microphone to detect the sample gas within the gas cell; and a membrane aligned with the opening of the gas cell to permit sample gas to enter the gas cell. The optical microphone includes a semiconducting laser. The semiconducting laser includes a p-n junction within a cavity of the semiconducting laser. The optical microphone further includes a pressure-sensitive membrane that receives coherent light emitted from the semiconducting laser and directs reflected light back toward the semiconducting laser. During operation of the optical microphone, the pressure-sensitive membrane flexes in response to acoustic pressure waves. The phase of the reflected light is dependent upon a distance of the pressure-sensitive membrane from an aperture of the semiconducting laser.