Abstract: A stretchable sensor is provided. The stretchable sensor includes a first stretchable electrode including a first elastomer and a first conductor dispersed in the first elastomer, a stretchable active layer formed on the first stretchable electrode and including a third elastomer and an ion conductor dispersed in the third elastomer, and a second stretchable electrode formed on the stretchable active layer and including a second elastomer and a second conductor dispersed in the second elastomer. The stretchable sensor is effectively capable of sensing a temperature without being affected by strain and recognizing strain without being affected by temperature.

Abstract: In certain examples, methods and structures are directed to an apparatus having a plurality of stretchable leads, with each of the plurality of stretchable leads including an associated electrode which is to receive electrical signals generated in response to a subject-s heart and to pass the received electrical signals along a respective one of plurality of stretchable leads. The apparatus also includes a patch integrating the stretchable substrate with the plurality of stretchable leads and with the patch having an area for circuitry to reside for collecting the electrical signals passed along each of the plurality of stretchable leads, wherein each of the plurality of stretchable leads is to be on a subject side of the patch. In more particular examples, the circuitry is used to provide a multi-lead ECG based on the electrical signals.

Abstract: A polymer composition includes a conductive polymer and at least one stretchability and electrical conductivity (STEC) enhancer, wherein a content of the STEC enhancer in the composition is at least about 1 wt. % of the composition.

Abstract: In certain examples, methods and semiconductor structures are directed Touched to a strain sensor integrated with a membrane substrate, a pressure sensor, and a plurality of material layers. The material layers are to integrate the strain sensor, the pressure sensor and the membrane substrate, with the pressure and strain sensors operating co-operatively to indicate, in response to a force applied to or towards the pressure sensor, characterization information of the force applied and of deformation of the membrane substrate. In a more specific example, the strain sensor and the membrane substrate are integrated with the aforesaid at least one of the material layers, and at least a portion of the pressure sensor and the membrane substrate are stacked to permit sensing of the force concurrently by the strain sensor and the pressure sensor.

Abstract: A method of making flexible and stretchable semiconductor devices with reduced footprints can include coating a gate electrode layer having a first composition over an elastomer layer, solidifying a portion of the gate electrode layer by irradiation to form a gate electrode, coating a dielectric layer having a second composition over the gate electrode layer, solidifying a portion of the dielectric layer by the irradiation to form a gate dielectric, coating a semiconductor layer having a third composition over the dielectric layer, solidifying a portion of the semiconductor layer by the irradiation to form a device core, coating a terminal layer having the first composition over the dielectric layer, and solidifying a portion of the terminal layer by the irradiation to form a source electrode and a drain electrode contacting the semiconductor layer.

Abstract: A stretchable sensor, electronic skin, and a method of manufacturing the same are proposed. The stretchable sensor includes a first stretchable electrode including a first elastomer and a first conductor dispersed in the first elastomer, a stretchable active layer formed on the first stretchable electrode and including a third elastomer and an ion conductor dispersed in the third elastomer, and a second stretchable electrode formed on the stretchable active layer and including a second elastomer and a second conductor dispersed in the second elastomer. The stretchable sensor and the method of manufacturing the same are effectively capable of sensing a temperature without being affected by strain and recognizing strain without being affected by temperature.

Abstract: A battery includes: 1) an anode; 2) a cathode; and 3) a solid or gel electrolyte disposed between the anode and the cathode, wherein the electrolyte includes a supramolecular polymer formed of, or including, molecules crosslinked through dynamic bonds, and each of the molecules includes an ionic ally conductive domain.

Abstract: Present implementations can include a method of forming an implantable biochemical sensor, by coating a first substrate with a first solution, etching, by a laser, the first substrate to form one or more electrodes in the first substrate, coating a first face of the electrodes with an elastomer solution, coating a second face of the electrodes with the elastomer solution, solidifying the elastomer coating into an elastomer shell at least partially surrounding the electrodes, and removing at least a portion of the elastomer shell to form implantable electrodes.

Abstract: A flexible sensing system includes: a flexible tag device including a first antenna, first sensor and second sensors, first modulation transistor and second modulation transistors connected to both ends of the first antenna, first ring oscillator that drives the first modulation transistor together with the first sensor, and a second ring oscillator that drives the second modulation transistor together with the second sensor; and a reader device that is flexible and includes a second antenna that is inductively coupled with the first antenna, extracts an output signal of the tag device for each frequency bandwidth, and corrects an output signal change of the tag device according to a coupling change between the first antenna and the second antenna.

Abstract: An anode includes: (1) a current collector; and (2) an interfacial layer disposed over the current collector. The interfacial layer includes an ion-conductive organic network including anionic coordination units, organic linkers bonded through the anionic coordination units, and counterions dispersed in the ion-conductive organic network.

Abstract: Various embodiments are directed to sensor apparatuses and methods thereof. An example sensor apparatus includes a plurality of capacitors and sensor circuitry. The plurality of capacitors including a first substrate having a plurality of first electrodes, a second substrate having a second electrode, and a dielectric material, and with the plurality of first electrodes and the second electrode being separated by the dielectric material. The plurality of first electrodes are aligned with respect to the second electrode such that each of plurality of first electrodes form one of the plurality of capacitors with the second electrode. The sensor circuitry is coupled to the plurality of capacitors to differentiate between normal and shear forces applied to apparatus based on a pattern of impedance responses of each of the plurality of capacitors formed by the second electrode and the plurality of first electrodes.

Abstract: A flexible sensing system includes: a flexible tag device including a first antenna, first sensor and second sensors, first modulation transistor and second modulation transistors connected to both ends of the first antenna, first ring oscillator that drives the first modulation transistor together with the first sensor, and a second ring oscillator that drives the second modulation transistor together with the second sensor; and a reader device that is flexible and includes a second antenna that is inductively coupled with the first antenna, extracts an output signal of the tag device for each frequency bandwidth, and corrects an output signal change of the tag device according to a coupling change between the first antenna and the second antenna.

Abstract: An example sensor apparatus includes two inductors with a first elastomer material between and at least one capacitor coupled to the two inductors. The at least one capacitor is configured, while in use, to at least partially wrap a circumference of an object and to exhibit a change in impedance in response to a pressure-manifestation change associated with the object, the change in impedance is to cause a change in the resonant frequency of the two inductors.

Abstract: Example implementations include an implantable device with a first substantially planar panel having a first planar surface and a second planar surface opposite to the first planar surface, at least one electrode portion at the first planar surface, and a panel elasticity corresponding to a tissue elasticity associated with an in vivo nerve, a second substantially planar panel having a first planar surface adhered to the second planar surface of the first panel, at least one sensor portion disposed on the first planar surface of the second panel, and the panel elasticity, and a third substantially planar panel having a first planar surface adhered to the first planar surface of the first panel, and the panel elasticity.

Abstract: A membrane-free electrochemical reactor and fuel-cell having a collection chamber between a first and second chamber, a mesoporous carbon paper cathode between the first chamber and the collection chamber, a mesoporous carbon paper anode between the second chamber and the collection chamber, the cathode is coated with an oxygen reduction reaction catalyst that imparts a two-electron partial reduction reaction to hydrogen peroxide, the anode is coated with an oxygen evolution reaction coating or a hydrogen oxidation reaction coating, oxygen/air input and output ports connected to the first chamber, KOH/water input and output ports connected to the second chamber that are in an open state under an electrolyzer mode, H2/water input and output ports connected to the second chamber that are in an open state under a fuel-cell mode, a second KOH/water input port connected to the collection chamber, and a hydrogen peroxide/KOH/water output port connected to the collection chamber.

Abstract: A method of fabricating polyacrylonitrile (PACN) nanostructured carbon superstructure shapes is provided that includes forming a PACN polymer superstructure shape by using as a monomer, an initiator, and a solvent or incorporation of a different co-monomer for free radical polymerization, and converting the PACN polymer superstructure shape to a nanostructured carbon superstructure analogue using stabilization and carbonization of the PACN polymer superstructure shape, where the stabilization includes heating the PACN polymer superstructure shape to a temperature that is adequate to form a stabilization reaction, where the carbonization includes using a heat treatment.

Abstract: Aspects of various embodiments are directed to sensor apparatuses and methods thereof. An example sensor apparatus includes a capacitor and sensor circuitry. The capacitor includes a first substrate having a first electrode, a second substrate having a second electrode, and a dielectric layer. The dielectric layer has a plurality of apertures arranged in a pattern, the first and second electrode being separated by the dielectric layer and arranged with an overlapping area with respect to one another. The sensor circuitry is coupled to the capacitor and configured and arranged to detect normal and shear forces applied to the sensor apparatus based on changes in capacitance derived from changes in at least one of a distance between the first and second electrodes and the overlapping area of the first and second electrodes.

Abstract: Disclosed are a thin film transistor includes a gate electrode, an active layer including a semiconductor material and a first elastomer, a gate insulator between the gate electrode and the active layer, and a source electrode and a drain electrode electrically connected to the active layer, wherein each of the semiconductor material and the first elastomer has a hydrogen bondable moiety, and the semiconductor material and the first elastomer are subjected to a dynamic intermolecular bonding by a hydrogen bond and a thin film transistor array and an electronic device including the same.

Abstract: Various embodiments are directed to apparatuses and methods involving an elastomer material comprising a flexible polymer backbone with a particular ratio of at least first moieties and second moieties. The first moieties provide a first number of dynamic bonds resulting from interactions between the first moieties and the second moieties provide a second number of dynamic bonds resulting from interactions between the second moieties, the second number of dynamic bonds having a weaker bonding strength than the first number of dynamic bonds. The elastomer material, based on the ratio of the first moieties and second moieties, exhibits autonomous self-healing, a particular toughness, and is stretchable.

Abstract: One example is directed to a reader device having a first resonance circuit and being configured to interrogate one or more other remotely-located resonance circuits, each associated with a second resonance circuit which may be part of a passive sensor circuit. The first resonance circuit is operated to cause the inductively-coupled oscillating signal to be swept over a range of frequencies and therein cause a jump or sudden transition in a frequency of the oscillating signal while the first and second resonance circuits are in sufficient proximity for inductively-coupling via an oscillating signal via their respective resonance circuits. Sensing circuitry may be used to detect the jump or sudden transition in the frequency of the oscillating signal and, by way of or in response to an indication of timing and/or a set of inductively-related parameters, data is conveyed from the sensor to the reader device via the inductively-coupled oscillating signal.