Abstract: Provided is an apparatus comprising a conductive particle interconnect (CPI) and an electroactive polymer (EAP) structure. The CPI includes an elastomeric carrier and a plurality of conductive particles dispersed therein. The EAP structure is disposed around at least a portion of the CPI. The EAP structure is configured to move between a first position and a second position in response to an electrical field. The CPI is configured to exhibit a first electrical resistance when the EAP structure is in the first position and a second, different electrical resistance when the EAP structure is in the second position.

Abstract: Provided is an apparatus comprising a conductive particle interconnect (CPI). The CPI includes an elastomeric carrier and a plurality of conductive particles dispersed therein. The elastomeric carrier includes an electroactive polymer (EAP) configured to move between a first position and a second position in response to an electrical field. The CPI is configured to exhibit a first electrical resistance when the EAP is in the first position and a second electrical resistance when the EAP is in the second position. The apparatus further comprises one or more electrodes electrically coupled to the CPI. The electrodes are configured to generate the electrical field within the CPI. The apparatus further comprises one or more insulators coupled to the CPI. The one or more insulators are configured to constrain expansion of the CPI in at least one direction.

Abstract: In an example, an apparatus includes a biological analysis component and a control component. The biological analysis component is configured to obtain an expected biological sample value. The expected biological sample value indicates an expected concentration of a material biologically processed by a courier. The biological analysis component is further configured to determine whether a measured biological sample value is associated with the courier based on a comparison of the expected biological sample value to the measured biological sample value. The control component is configured to perform a first set of operations based on the result of the comparison indicating that the measured biological sample value is associated with the courier. The control component is configured to perform a second set of operations based on the result of the comparison indicating that the measured biological sample value is outside an acceptable range of the biological sample value.

Abstract: A process of evaluating performance of a positive crankcase ventilation (PCV) valve is disclosed. The process includes utilizing an optical sensor coupled to the PCV valve to collect baseline valve position data during a calibration phase. The baseline valve position data represents satisfactory PCV valve performance. The process also includes utilizing the optical sensor to collect operational valve position data during an operational phase. The process further includes determining whether a deviation of the operational valve position data from the baseline valve position data satisfies a performance threshold associated with unsatisfactory PCV valve performance. When the deviation satisfies the performance threshold, the process includes communicating an error code to an alert indicator.

Abstract: A fusible via is disclosed. The fusible via includes an upper contact. The fusible via further includes a handle portion having a first end and a second end. The upper contact is disposed on the first end of the handle portion. The handle portion comprises an alloy and a blowing agent. The alloy melts above a predefined solder reflow temperature but below a thermal degradation temperature of the blowing agent. The fusible via further includes a lower contact disposed on the second end of the handle portion.

Abstract: A device, method, and article of manufacture for corrosion monitoring are disclosed. The device includes a corrodible component and a silicone layer positioned over the corrodible component. The method includes providing a corrosion monitoring assembly having a corrodible component and a silicone layer positioned over the corrodible component. The article of manufacture includes a corrosion monitoring assembly having a corrodible component and a silicone layer positioned over the corrodible component.

Abstract: Method, apparatus, and computer program product are provided for determining a maximum temperature to which a perishable good or other temperature sensitive item was exposed. In some embodiments, a capacitance of a circuit provided on a substrate is measured. The circuit includes capacitor(s) each having first and second plates separated from each other by an ionic liquid (IL) in a solid state. The IL melts at a predetermined temperature and flows away from the first and second plates into a void. In some embodiments, the predetermined temperature at which the IL melts is different for each capacitor. For example, each capacitor in the circuit may employ a different N-alkyl bezothiazolium salt. A maximum temperature of exposure is determined based on the measured capacitance. In some embodiments, a decision of whether to discard the perishable good or other temperature sensitive item may be based on the determined maximum temperature.

Abstract: A self-healing polymeric material includes a polymeric matrix material, a plurality of monomer mixture microcapsules dispersed in the polymeric matrix material, and a plurality of light generating microcapsules dispersed in the polymeric matrix material. Each monomer mixture microcapsule encapsulates a mixture of materials that includes monomers and a photoinitiator. Each light generating microcapsule encapsulates multiple reactants that undergo a chemiluminescent reaction. The chemiluminescent reaction generates a photon having a wavelength within a particular emission range that is consistent with an absorption range of the photoinitiator.

Abstract: A self-healing polymeric material includes a polymeric matrix material, wherein dispersed within the polymeric matrix material is a mixture of materials that includes monomers and a photoinitiator, and a plurality of light generating microcapsules dispersed in the polymeric matrix material. Each light generating microcapsule encapsulates multiple reactants that undergo a chemiluminescent reaction. The chemiluminescent reaction generates a photon having a wavelength within a particular emission range that is consistent with an absorption range of the photoinitiator.

Abstract: A multi-compartment microcapsule emits photons when subjected to a stimulus. In some embodiments, the multi-compartment microcapsules have first and second compartments separated by an isolating structure adapted to rupture in response to the stimulus, wherein the first and second compartments contain reactants that come in contact and react to produce photons when the isolating structure ruptures.

Abstract: A multilayer component is coated with a fluorogenic probe designed to give off florescence when in contact with one or more metals in the multilayer component. The fluorogenic probe is exposed to radiation. The intensity and wavelength of the florescence is measured to determine a porosity of the one or more layers of the multilayer component.

Abstract: A self-healing polymeric material includes a polymeric matrix material, a plurality of monomer mixture microcapsules dispersed in the polymeric matrix material, and a plurality of heat generating microcapsules dispersed in the polymeric matrix material. Each monomer mixture microcapsule of the plurality of monomer mixture microcapsules encapsulates a mixture of materials that includes a monomer and a heat-triggered initiator. Each heat generating microcapsule of the plurality of heat generating microcapsules encapsulates multiple reactants that undergo an exothermic chemical reaction. The exothermic chemical reaction generates sufficient heat to cause the heat-triggered initiator to initiate a polymerization reaction.

Abstract: In an example, a method includes obtaining an expected biological sample value at a computing device. The expected biological sample value indicates an expected concentration of a material biologically processed by a courier. The computing device determines whether the measured biological sample value is associated with the courier based on a comparison of the expected biological sample value to the measured biological sample value. The method also includes determining a particular set of operations to be performed at the computing device based on a result of the comparison.

Abstract: A security matrix layer between a first and second conductive shorting layers are located within a printed circuit board (PCB). The security matrix layer includes at least two types of microcapsules with each type of microcapsule containing a different reactant. When the security matrix layer is accessed, drilled, or otherwise damaged, the microcapsules rupture and the reactants react to form at least an electrically conductive material. The electrically conductive material may contact and short the first and second conductive shorting layers.

Abstract: A self-heating solder flux material includes a solder flux material and a multi-compartment microcapsule. The solder flux material includes a solvent carrier, and the multi-compartment microcapsule includes a first compartment, a second compartment, and an isolating structure. The first compartment contains a first reactant, and the second compartment contains a second reactant. The isolating structure separates the first compartment from the second compartment. The isolating structure is adapted to rupture in response to a stimulus.

Abstract: A tamper resistant device comprises an internal component, such as an electronic device, and a latent battery that is connected to the internal component. An activator material is separated from the latent battery by a rupturable barrier that is adapted to rupture, shatter, or otherwise degrade in response to a stimulus associated with a physical tampering event. The activator material is a material that causes the latent battery to output electrical power when in contact with the latent battery. In some examples, the electrical power provided when the activator material contacts the latent battery is used to trigger a security response which can include transmission of an alarm signal and/or erasure of data stored by the internal component.

Abstract: A process includes utilizing a pin array that includes multiple segmented pins for forming selectively plated through holes. The process includes forming a PCB laminate structure that includes multiple spinel-doped core layers and multiple through holes. Each spinel-doped core layer includes a heat-activated spinel material incorporated into a dielectric material. The process includes aligning individual segmented pins of a pin array with corresponding through holes of the PCB laminate structure, where each segmented pin includes heated segment(s) and insulating segment(s). The process includes inserting the segmented pins of the pin array into the corresponding through holes and generating heat within each heated pin segment that is sufficient to form metal nuclei sites in selected regions of the spinel-doped core layers adjacent to portions of the through holes that contain the heated pin segments. The metal nuclei sites function as seed layers to enable formation of selectively plated through holes.

Abstract: A security matrix layer between a first and second conductive shorting layers are located within a printed circuit board (PCB). The security matrix layer includes at least two types of microcapsules with each type of microcapsule containing a different reactant. When the security matrix layer is accessed, drilled, or otherwise damaged, the microcapsules rupture and the reactants react to form at least an electrically conductive material. The electrically conductive material may contact and short the first and second conductive shorting layers.

Abstract: A security matrix layer between a first and second conductive shorting layers are located within a printed circuit board (PCB). The security matrix layer includes at least two types of microcapsules with each type of microcapsule containing a different reactant. When the security matrix layer is accessed, drilled, or otherwise damaged, the microcapsules rupture and the reactants react to form at least an electrically conductive material. The electrically conductive material may contact and short the first and second conductive shorting layers.

Abstract: A fusible via is disclosed. The fusible via includes an upper contact. The fusible via further includes a handle portion having a first end and a second end. The upper contact is disposed on the first end of the handle portion. The handle portion comprises an alloy and a blowing agent. The alloy melts above a predefined solder reflow temperature but below a thermal degradation temperature of the blowing agent. The fusible via further includes a lower contact disposed on the second end of the handle portion.