A polymerizable liquid crystal compound represented by Chemical Formula 1: wherein in Chemical Formula 1, groups and variables are the same as defined in the detailed description.

A semiconductor device includes a substrate, a first thin film transistor supported on the substrate and having a first active layer that primarily contains a first oxide semiconductor, and second thin film transistor supported on the substrate and having a second active layer that primarily contains a second oxide semiconductor with a higher mobility than the first oxide semiconductor. The first active layer and the second active layer are positioned on the same insulating layer and contact the same insulating layer.

A fixture for preventing deformation of a glass panel of a display module, for receiving and fixing a light guide plate and a glass panel. It comprises an array cell and a color filter cell. The array cell is provided with a metal routing layer. The color filter cell is provided with a color resist layer. The fixture consists and a lower fixing end, with upper ends, the array cell and the color filter cell received in the upper fixing end, while lower ends thereof received in the lower fixing end, so the color resist layer in the color filter cell and the metal routing layer in the array cell are aligned in parallel. By a gap between the glass panel and the inner side face and bottom surface, the glass panel fine tunes properly for quick recovery by virtue of its gravity when deformation occurs.

A method of forming a front frame of an LCD includes: providing a rectangle frame; disposing bending lines on the side frames of the rectangle frame; adhering a layer of buffering material to the part of the side frame that is on the inner side of the bending line, where the part of the side frame that is on the inner side of the bending line refers to the part of the side frame that is between the bending line and the inner edge of the side frame; and stamping and bending the rectangle frame along the bending line. The present invention can align the layer of buffering material with the inner edge of the side frame so that the layer of buffering material does not extend to the open area of the front frame, therefore does not affect the display of the liquid crystal panel.

According to one embodiment, a display device includes a liquid crystal display panel, a cover panel on a display surface of the liquid crystal display panel, a backlight unit opposed to the liquid crystal display panel, a case covering the backlight unit and the liquid crystal display panel, and including at least a part fixed to the cover panel, and an adhesive provided on the cover panel along the liquid crystal display panel. The adhesive includes a surface opposite to the cover panel, a first area on the surface, and a second area on the surface, located on an inner side closer to the liquid crystal display panel than the first area. The part of the case is adhered to the second area.

The present disclosure provides a method for rubbing an alignment layer on a substrate with a plurality of spacers that are arranged in rows and columns and a liquid crystal display panel. The method includes: determining a first rubbing direction and a second rubbing direction in such a manner that the second rubbing direction is an arrangement direction of liquid crystal molecules when the liquid crystal molecules are arranged correctly on the alignment layer, and an angle between the first rubbing direction and the second rubbing direction is greater than or equal to arctan (b/a), where a represents a row pitch between the spacers and b represents a width of one spacer; performing a first rubbing on the alignment layer in the first rubbing direction; and performing a second rubbing on the alignment layer in the second rubbing direction. The second rubbing direction is different from the first rubbing direction.

A display of an electric device includes a plurality of separated transparent electrode blocks, which are configured to provide one or more of supplemental features such as touch recognition. Signal paths between the transparent electrode blocks and the driver for the supplemental feature are implemented with a plurality of conductive lines placed under positioned under one or more planarization layers. The conductive lines implementing the signal paths are routed across the display area, directly toward a non-display area where drive-integrated circuits are located.

Carbon allotropes, a thin-film transistor array substrate comprising the same, and a display device comprising the same are disclosed. The thin-film transistor array substrate comprising a substrate, a gate electrode on the substrate, a gate insulating film on the gate electrode, an active layer positioned on the gate insulating film and comprising a semiconductor material and a plurality of carbon allotropes, and a source electrode and a drain electrode that make contact with the active layer.

A single molecule sensing or detecting device includes a first electrode and a second electrode separated from the first electrode by a gap. The first electrode and the second electrode have an opening formed therethrough. At least one of the first electrode and the second electrode is functionalized with a recognition molecule. The recognition molecule has an effective length L1 and is configured to selectively bind to a target molecule having an effective length L2. The size of the gap is configured to be greater than L2, but less than or equal to the sum of L1 and L2.

The purpose of the present invention is to provide an In—Cu alloy sputtering target member having high compositional homogeneity in the thickness direction. The present invention provides a sputtering target member having a composition containing from 1 to 70 at. % of Cu relative to a total number of atoms of In and Cu, the balance being In and inevitable impurities, wherein the target member fulfills 0.95≦A/B≦1, where A represents a Cu atomic concentration relative to the total number of atoms of In and Cu in one half of a thickness direction; B represents a Cu atomic concentration relative to the total number of atoms of In and Cu in the other half of the thickness direction; and B≧A; and wherein a number of pores having a size of 100 μm or more is less than 10/cm2 on average.

A process train for a floating production storage and offloading installation includes a crude oil storage tank that is equipped with at least one set of electrostatic internals arranged to provide a treatment flow path isolated from a surrounding volume of the electrostatic separator section of the tank. An oil-and-water stream or mixture entering the set of electrostatic internals travels along the treatment flow path and is subjected to an electric field. The treatment flow path is in an upwardly direction toward the oil outlet section and in a downwardly opposite direction toward the water outlet section of the tank. Employing electrostatic internals within the tank permits an allowable inlet water content into the tank of up to 80%, significantly reducing the required topside processing equipment.

Methods and apparatus for treating an exhaust gas in a foreline of a substrate processing system are provided herein. In some embodiments, a method for treating an exhaust gas in an exhaust conduit of a substrate processing system includes: flowing an exhaust gas and a reagent gas into an exhaust conduit of a substrate processing system; injecting a non-reactive gas into the exhaust conduit to maintain a desired pressure in the exhaust conduit for conversion of the exhaust gas; and forming a plasma from the exhaust gas and reagent gas, subsequent to injecting the non-reactive gas, to convert the exhaust gas to abatable byproduct gases.

The invention discloses a composite material used for catalyzing and degrading nitrogen oxide and its preparation method and application thereof. The invention of the hollow g-C3N4 nanospheres/reduced graphene oxide composite-polymer carbonized nanofiber material is prepared as follow: 1) the preparation of silica nanospheres; 2) the preparation of hollow g-C3N4 nanospheres; 3) the preparation of graphene oxide; 4) the preparation of surface modified hollow g-C3N4 nanoparticles preparation; 5) the preparation of composites; 6) the preparation of composite-polymer carbon nanofiber material. The raw materials used in the process is low cost and easy to get; the operation of the invention is simple and convenient without the use of expensive equipment in the whole process; the composite has high adsorption efficiency of ppb level nitrogen oxide with good repeatability.

A process train for a floating production storage and offloading installation includes a crude oil storage tank equipped with at least one set of electrostatic internals. The set of electrostatic internals are arranged to provide a treatment flow path within the crude oil storage tank oblique to a longitudinal centerline of the crude oil storage tank and through an electric field provided by the set of electrostatic internals. Employing these electrostatic internals within the tank permits an allowable inlet water content into the tank of up to 80%, significantly reducing the required topside processing equipment. The process and system also includes, upstream of the tank, two separator vessels arranged in parallel so each receives a portion of an incoming oil-and-water stream, a flash vessel arranged downstream of the two separator vessels, and a degasser vessel. Downstream of the crude oil storage tank is an electrostatic treater.

A system and method for dehydrating crude oil on a floating production storage and offloading installation include a separator vessel to receive an incoming produced water stream, followed by a flash vessel, a treatment block, a crude oil storage tank, and an electrostatic treater. The treatment block includes a low pressure degasser followed by a compact electrostatic separator pre-treater or a compact electrostatic separator pre-treater followed by a low pressure degasser. The flash vessel and/or the low pressure degasser may employ an inlet cyclonic distributor and demisting cyclones, while the electrostatic treater may employ DUAL FREQUENCY® technology. The separator vessel may be a single horizontal two-phase separator/degasser or two vertical two-phase separator/degassers that operate in parallel with each receiving approximately 50 percent of the incoming produced water stream. The final outlet stream preferably contains no more than 0.5 BS&W and 285 milligrams per liter salt.

Methods are provided for production of a composite layer comprising a plastic foil and a layer deposited directly thereon. A method for production of a composite layer comprising a plastic foil and at least one layer deposited directly onto the plastic foil by means of chemical gas-phase deposition within a vacuum chamber may be provided, wherein the plastic foil has a proportion of at least 20 percent by mass of a metal element or of a semiconductor element, wherein during the layer deposition, at least one monomer is supplied into the vacuum chamber and a plasma is formed within the vacuum chamber. After completed deposition of the layer, at least one surface region of the layer is exposed to accelerated electrons.

A magnetically enhanced low temperature high density plasma chemical vapor deposition (LT-HDP-CVD) source has a hollow cathode target and an anode, which form a gap. A cathode target magnet assembly forms magnetic field lines substantially perpendicular to the cathode surface. A gap magnet assembly forms a magnetic field in the gap that is coupled with the cathode target magnetic field. The magnetic field lines cross the pole piece electrode positioned in the gap. The pole piece is isolated from ground and can be connected to a voltage power supply. The pole piece can have negative, positive, floating, or RF electrical potentials. By controlling the duration, value, and sign of the electric potential on the pole piece, plasma ionization can be controlled. Feed gas flows through the gap between the hollow cathode and anode. The cathode can be connected to a pulse power or RF power supply, or cathode can be connected to both power supplies. The cathode target and substrate can be inductively grounded.

An Al—Te—Cu—Zr alloy sputtering target, comprising 20 at % to 40 at % of Te, 5 at % to 20 at % of Cu, 5 at % to 15 at % of Zr and the remainder of Al, wherein a Te phase, a Cu phase and a CuTe phase are not present in a structure of the target. An object of the present invention is to provide an Al—Te—Cu—Zr alloy sputtering target capable of effectively reducing particle generation, nodule formation and the like upon sputtering and further capable of reducing oxygen contained in the target.

A magnetically enhanced HDP-CVD plasma source includes a hollow cathode target and an anode. The anode and cathode form a gap. A cathode target magnet assembly forms magnetic field lines that are substantially perpendicular to a cathode target surface. The gap magnet assembly forms a cusp magnetic field in the gap that is coupled with the cathode target magnetic field. The magnetic field lines cross a pole piece electrode positioned in the gap. This pole piece is isolated from ground and can be connected with a voltage power supply. The pole piece can have a negative, positive, or floating electric potential. The plasma source can be configured to generate volume discharge. The gap size prohibits generation of plasma discharge in the gap. By controlling the duration, value and a sign of the electric potential on the pole piece, the plasma ionization can be controlled. The magnetically enhanced HDP-CVD source can also be used for chemically enhanced ionized physical vapor deposition (CE-IPVD). Gas flows through the gap between hollow cathode and anode. The cathode target is inductively grounded, and the substrate is periodically inductively grounded.

Self-propelling, programmable nanoscopic motors capable of harvesting energy from absorbed photons and undergoing subsequent photoeletrochemical (PEC) reactions are provided. A nanomotor can have a three-dimensional Janus configuration and can sense the direction of a light source. By controlling the zeta potential of different parts of the nanomotor with chemical modifications, the nanomotor can be programmed to show either positive phototaxis or negative phototaxis.

The present document describes an electrophoretic tissue clearing chamber comprising an electrophoresis channel, configured to receive a clarification fluid therethrough; a first clarification fluid inlet, in fluid communication with the electrophoresis channel, configured to be connected to a source of the clarification fluid; a tissue sample holder in fluid communication with the electrophoresis channel, configured to receive a tissue sample to be clarified, and pressurize and homogenously apply the clarification fluid onto the tissue sample; a clarification fluid outlet, in fluid communication with the tissue sample holder, for exit of the clarification fluid from the electrophoretic tissue clearing chamber; and first and a second electrode, opposite one another in the electrophoresis channel, for transmission of an electric field therethrough.

The present disclosure relates to a method for producing a reference electrode, wherein an internal space of the reference electrode is delimited by an outer wall and wherein the internal space contains a reference electrolyte up to a specified height, wherein the reference electrode is introduced into a pressurization chamber, wherein a defined overpressure is applied to the pressurization chamber and, via an opening that is located above the specified height in the outer wall of the reference electrode to the internal space of the reference electrode, and wherein the opening in the outer wall of the reference electrode is closed at the defined overpressure . The present disclosure further relates to a device for carrying out the method.

The concentration measurement method includes: introducing a predetermined amount of the biological sample into the capillary; measuring a temperature of the biological sample by applying a first voltage to the electrode unit when the temperature of the biological sample is measured, the first voltage allowing the temperature measurement to be less affected by increase and reduction in an amount of the analyte contained in the biological sample; measuring the concentration of the analyte contained in the biological sample by applying a second voltage to the electrode unit; measuring an environmental temperature in a surrounding of the biological sample; and correcting the concentration of the measured analyte based on the measured temperature of the biological sample and the measured environmental temperature.

A capillary electrophoresis device including a capillary tube, a suction pump for taking liquid, an intake tube whose end is formed vertically downward, a connection block in which there is an intake flow path that holds the end of the capillary tube and connecting the suction pump to the intake tube, a sample storage unit which contains a sample and has an upward opening into which the tip of the intake tube may be inserted, an intake tube access mechanism to insert the tip of the intake tube into the sample storage unit, and a voltage application mechanism that applies an electric potential difference across the capillary tube.

The present invention generally relates to devices and methods for containing molecules. In some embodiments, the device comprises a nanopore, a pore, and a cavity capable of entropically containing (e.g., trapping) a molecule (e.g., a biomolecule), e.g., for minutes, hours, or days. In certain embodiments, the method comprises urging a molecule into a cavity of a device by application of an electric field, and/or by deposition of fluids having different ionic strengths. The molecule may comprise, in some cases, nucleic acids (e.g., DNA). The molecule, when present in the cavity and/or the nanopore, may be capable of being analyzed, determined, or chemically modified. In some instances, a second molecule (e.g., a second molecule which interacts the first molecule) may also be urged into the cavity. In some embodiments, the interaction of the second molecule with the first molecule (e.g., the second molecule binding to or chemically modifying the first molecule) may be determined by, for example, a change in voltage measured across the device.

In one aspect, a biological sequencing device comprising a cartridge configured to be removed from the instrument is disclosed. In various embodiments the cartridge can include one or more capillaries suitable for capillary electrophoresis, a reservoir and a pump. In various embodiments the reservoir can contain a separation matrix. In various embodiments the pump can load a capillary with separation matrix. In another aspect the biological sequencing device can include one or more capillaries and an integrated valve assembly. In various embodiments the integrated valve assembly can provide a polymer to the one or more capillaries.

The present disclosure relates, in some embodiments, to an apparatus for conducting a capillary electrophoresis assay. The apparatus can comprise a capillary array comprising an anode end and a cathode end, the capillary array provided in a housing further comprising a reservoir configured to house a separation medium and an anode buffer. The system can also comprise an injection mechanism configured to deliver sample to the cathode end of the capillary array, and a temperature control zone, wherein the temperature control zone is configured to control the temperature of the interior of the housing.

There is provided an insulator target which, when mounted on a sputtering apparatus and supplied with AC power, is capable of preventing the discharging from occurring in a clearance between a shield and the target. The insulator target for the sputtering apparatus according to this invention, around which is disposed a shield at the time of assembling the insulator target on the sputtering apparatus, is made up of: a plate-shaped target material to be enclosed by the shield; and, suppose that one surface of the target material is defined as a sputtering surface to be subjected to sputtering, an annular supporting material coupled to an outer peripheral portion of the opposite surface of the target material. The supporting material has an extended portion which is extended outward from a peripheral surface of the target material and which keeps a predetermined clearance to the shield.

A Cu—Ga alloy sputtering target includes, as a component composition, Ga: 0.1 to 40.0 at % and a balance including Cu and inevitable impurities, in which a porosity is 3.0% or lower, an average diameter of circumscribed circles of pores is 150 μm or less, and an average crystal grain size of Cu—Ga alloy particles is 50 μm or less.

Methods and apparatus for processing a substrate are disclosed herein. In some embodiments, a process chamber includes: a chamber body defining an interior volume; a substrate support to support a substrate within the interior volume; a plurality of cathodes coupled to the chamber body and having a corresponding plurality of targets to be sputtered onto the substrate; and a shield rotatably coupled to an upper portion of the chamber body and having at least one hole to expose at least one of the plurality of targets to be sputtered and at least one pocket disposed in a backside of the shield to accommodate and cover at least another one of the plurality of targets not to be sputtered, wherein the shield is configured to rotate about and linearly move along a central axis of the process chamber.

An electrically and magnetically enhanced ionized physical vapor deposition (I-PVD) magnetron apparatus and method is provided for sputtering material from a cathode target on a substrate, and in particular, for sputtering ceramic and diamond-like coatings. The electrically and magnetically enhanced magnetron sputtering source has unbalanced magnetic fields that couple the cathode target and additional electrode together. The additional electrode is electrically isolated from ground and connected to a power supply that can generate positive, negative, or bipolar high frequency voltages, and is preferably a radio frequency (RF) power supply. RF discharge near the additional electrode increases plasma density and a degree of ionization of sputtered material atoms.

Methods and apparatus for processing substrates are provided herein. In some embodiments, a physical vapor deposition chamber includes a first RF power supply having a first base frequency and coupled to one of a target or a substrate support; and a second RF power supply having a second base frequency and coupled to one of the target or the substrate support, wherein the first and second base frequencies are integral multiples of each other, wherein the second base frequency is modified to an offset second base frequency that is not an integral multiple of the first base frequency.

A film formation apparatus and a film-formed workpiece manufacturing method which are capable of forming a film with a uniform thickness on a workpiece like a three-dimensional object that includes a plurality of surfaces by a simple structure are provided. A film formation apparatus includes a target 21 that is a film formation material including a plane SU3, a power supply unit 3 applying power to the target 21, a rotating unit 4 rotating a workpiece W that is a film formation object around a rotation axis AX1, and a revolving unit 5 revolving the rotating unit 4 around a revolution axis AX2 separate from the rotation axis AX1 to repeatedly make the workpiece W to come close to and move apart from the target 21.

The present invention is to provide a photocatalyst electrode for water decomposition exhibiting a high photocurrent density and having reduced dark current. The photocatalyst electrode for water decomposition of the present invention has a photocatalyst layer and a current collector layer that is formed by a vapor deposition method and is disposed on the photocatalyst layer.

In one illustrative embodiment, a test strip with a first planar substrate has coplanar electrodes on a first planar surface and a second planar substrate (which opposes the first surface of the first planar substrate) has coplanar electrodes on a second planar surface. The first planar surface of the first planar substrate having a first sensing area electrically connected to a first electrical contact. The second planar surface of the second planar substrate having a second electrical contact electrically connected to the first electrical contact via a conductive element, the conductive element extending between the first surface of the first planar substrate and the second surface of the second planar substrate without passing through the first planar substrate, the second planar substrate, or any intermediate layers.

The present disclosure relates to metal alloys for biosensors. An electrode is made from the metal alloy, which more specifically can be a nickel-based alloy. The alloy provides physical and electrical property advantages when compared with existing pure metal electrodes.

The present invention provides an ion selective electrode comprising an electrode having a coating deposited on the electrode, wherein the coating comprises one or more aroyl-thiourea ionophores incorporated into a polymer matrix to selectively interact with one or more ions. The aroylthiourea ionophores may be poly-5, poly-6, poly-7, poly-7a, poly-7b, poly-8a, poly-8b or a combination thereof, e.g., a bis(furoylthiourea)benzene derivative, a 2,2'-bith-iophenyl derivative that selectively senses Pb2+ ions. The polymer matrix may be a polyaniline, a polythiophene or the polymer matrix may be an aroylthiourea ionophore inserted into polyvinyl-chloride for Pb2+ and Hg2+ ion sensing.

An SCU as a control device for the gas sensor (first and second NOx sensors) includes an applied voltage switching unit for switching an applied voltage of a pump cell when a deterioration detecting function is performed, and a deterioration rate calculation unit for calculating a deterioration rate of a sensor cell based on a slope during a transient change in an output of the sensor cell according to a switching of the applied voltage by the applied voltage switching unit.

The present disclosure relates to devices and methods for performing isotachophoretic concentration of analytes using a porous matrix, for example, for use in diagnostic assays such as lateral flow assays. For example, the disclosure provides a method of concentrating an analyte in a sample. The method includes providing a device comprising a porous matrix having a first fluid pathway having a first end and extending to a second end, a first electrode, and a second electrode; introducing to the first pathway a first fluid comprising a trailing electrolyte, a second fluid comprising a leading electrolyte and the analyte; and applying a voltage across the first electrode and the second electrode for a time sufficient to provide an ITP plug. As described herein, the devices and methods described herein can be used in conjunction with lateral flow assay techniques to detect and quantify a variety of biochemical and biological analytes, such as nucleic acids, proteins, cells and metabolites.

The present invention provides a system including: a protein having a domain that binds a membranal component; an inlet for sample flow, an Isotachophoresis (ITP) system and a flow generating means connected or coupled to the aqueous parts of the ITP. The invention also provides a method for detecting and or sorting cells with this system.

Provided herein is an apparatus that includes a body with a top surface and a recess in the top surface. The top surface, excluding the recess, is substantially planar. The recess is confined to an area that is defined by an inner diameter of the top surface of the body.

One embodiment is directed to a method for controllably managing pain in the afferent nervous system of a patient having a targeted tissue structure that has been genetically modified to have light sensitive protein, comprising: providing a light delivery element configured to direct radiation to at least a portion of a targeted tissue structure, a light source configured to provide light to the light delivery element, and a controller operatively coupled to light source, wherein the targeted tissue structure comprises a sensory neuron of the patient; and automatically operating the controller to illuminate the targeted tissue structure with radiation such that a membrane potential of cells comprising the targeted tissue structure is modulated at least in part due to exposure of the light sensitive protein to the radiation.

The present invention relates to scaffolds composed of a protein backbone cross-linked by a synthetic polymer. Specifically, the present invention provides PEGylated-thiolated collagen scaffolds and PEGylated albumin scaffolds and methods of generating and using same for treating disorders requiring tissue engineering.

A method and device are provided for simultaneously or near-simultaneously diagnosing and treating tension pneumothorax and/or hemothoraxA Veress-type needle portion includes a hollow needle for puncturing the chest wall over a blunt hollow probe biased by one or more springs to extend distally into the pleural cavity. Openings in the blunt hollow probe connect via a pathway to an automatic check valve, which permits the flow of air and/or fluid only in a proximal direction. Pressure from within the pleural cavity is transmitted to the interior surface of a pressure documenter. If pressure greater than atmospheric pressure is present in the pleural cavity, the pressure documenter will be automatically urged proximally to simultaneously allow air and/or fluid to escape from the pleural space through the device, thus treating the tension pneumothorax and/or hemothorax, as well as providing a stable indicator to positively document the diagnosis of increased pressure.

In one example embodiment, a system for treating a tissue site is disclosed comprising a dressing adapted to contact the tissue site and provide a fluid seal between a therapeutic environment and a local external environment, and a solution source fluidly coupled to the dressing and adapted to deliver an antimicrobial solution comprising a peroxy α-keto carboxylic acid, such as peroxy pyruvic acid, to the tissue interface. The system may further comprise a negative-pressure source fluidly coupled to the dressing and adapted to provide negative pressure to the therapeutic environment after delivery of the antimicrobial fluid to the therapeutic environment. In another example embodiment, a method for treating a tissue site is disclosed comprising positioning a tissue interface to contact the tissue site, covering the tissue interface and the tissue site with a drape to provide a fluid seal between the therapeutic environment and the local external environment, and delivering an antimicrobial solution comprising peroxy α-keto carboxylic acid to the therapeutic environment before providing negative pressure to the therapeutic environment.

A renal failure blood therapy system includes a renal failure blood therapy machine, concentration levels for each of a plurality of solutes removed from a patient's blood at each of the multiple times, a display device configured to display for selection at least one removed blood solute from the plurality of removed blood solutes, and a device programmed to (i) estimate at least one renal failure blood therapy patient parameter using the determined concentration levels for the at least one selected removed blood solute, (ii) determine a plurality of acceptable renal failure blood therapy treatments that meet a predetermined removed blood solute clearance for the at least one selected removed blood solute using the at least one renal failure blood therapy patient parameter, and (iii) enable selection of at least one of the plurality of acceptable renal failure blood therapy treatments for operation at the renal failure blood therapy machine.

An insert for a catheter system can include an insert housing which defines a portion of a fluid pathway of the catheter system, a cartridge positioned within the insert housing in a manner to allow fluid flow along the fluid pathway such that fluid contacts the insert during the fluid flow, and an active agent associated with the cartridge. The active agent and the cartridge can be adapted to release active agent from the cartridge during the fluid flow.

Valves, valved fluid transfer devices and ambulatory infusion devices including the same.

Valves, valved fluid transfer devices and ambulatory infusion devices including the same.

A detection section is used in such a manner that it is inserted into a living body by being guided by an insertion needle to be stuck and inserted into the living body. The detection section includes a first region, a second region, and a third region. The first region is provided in a tip end portion of the detection section and includes an electrode layer (detection electrode). The third region includes a wiring section and has a smaller width than the width of a slit of the insertion needle. The second region is provided between the first region and the third region and has the same width as the width of the third region by gradually decreasing from the width of the first region.