This invention describes an electrochemical gas sensor that utilizes microfabrication to achieve miniaturization without using a membrane. The sensor is comprised of thin film electrodes and insulators, and micro cavities in them. The micro cavities are filled with a liquid electrolyte that is kept in the micro cavities by surface tension.

A chemical release detection system includes a camera, an output control member, a mitigation member, and a controller in operative communication with the camera, the output control member, and the mitigation member. The camera is configured to detect a chemical release. The output control member is configured to generate commands. The mitigation member is configured to reduce risk generated by the chemical release based on the commands by the output control member. The controller is configured to notify a user of the chemical release, and provide an origin of the release and a direction of the release. The controller controls the operation of the output control member and the mitigation member.

A device determines an oxygen content of a headspace gas in a liquid-filled container. The device contains a piercer, a sampling tube, a piercing head on which the piercer and the sampling tube are disposed, a pump, a ring line, and a sensor unit disposed within the ring line and used to determine the oxygen content and/or an oxygen partial pressure of the headspace gas of the liquid-filled container. The ring line is configured such that the headspace gas of the liquid-filled container can be sampled via the piercer or the piercing head by use of the pump and can be returned into the headspace of the liquid-filled container via the sampling tube.

An electronic device includes a pop-up device configured to be inserted into a main body of the electronic device in an inserted state, including a gas sensor including a sensor block for sensing a gas, and configured to expose the sensor block to an outer portion of the electronic device in a pop-up state; a power supplier arranged on an outer portion of the pop-up device, configured to supply electric power to the gas sensor; and a connection controller configured to control a connection state of the pop-up device, to block supply of electric power to the gas sensor when the pop-up device is in the inserted state and to supply electric power to the gas sensor when the pop-up device is in the pop-up state, including one or more terminals formed on the pop-up device that move together with the pop-up device when the pop-up device moves.

An integrated chemical sensor device includes a chemical sensor comprising at least one transistor and having an external sensing surface electrically coupled to a node of the at least one transistor. There is an initialization circuit connected to the base of the at least one transistor configured to set an operating point for the at least one transistor. There is a temperature sensor control circuit coupled to the chemical sensor circuit. The temperature sensor includes a temperature sensor, an analog-to-digital (A/D) converter coupled to the temperature sensor, and a proportional-to-absolute-temperature (PTAT) circuit configured to generate a PTAT reference voltage for temperature compensation. The temperature sensor control circuit is configured to compensate for a change in temperature of the at least one transistor.

A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including metallic nanowires, nanosized particles of a dichalcogenide, and a mercaptoimidazolyl metal-ligand complex. The sensor can be used to detect volatile compounds that have a double or triple bond.

An amperometric electrochemical sensor for measuring the concentrations of one or more target gas species in a gas sample or gas stream, the sensor having at least one electrochemical cell with first and second surface electrodes, an electrolyte layer and a passive signal amplifying layer (“SAL”) comprising electrically conductive material like platinum, wherein at least a portion of the electrolyte layer is located between the surface electrodes and the SAL such that the SAL is in direct, conductive contact with the electrolyte layer but is not in direct contact with the surface electrodes. Sensor systems and detection methods are also provided.

A device and method for calibrating a delivery device includes providing a container A containing a nitrite, providing a container B containing an acid, releasing the contents of containers A and B, allowing the nitrite and acid to mix, waiting for a predetermined time, allowing air to combine with the mixture, and using NO and traces of NO.sub.2 to check and calibrate NO and NO.sub.2 sensors.

According to one embodiment, an electrochemical device includes an electrochemical element, and a controller. The electrochemical element includes a first electrode, a second electrode, and a first member provided between the first electrode and the second electrode. The controller is electrically connected to the first electrode and the second electrode. The controller is configured to supply a first signal between the first electrode and the second electrode. The first signal includes a waveform repeating in a first period. The waveform includes a first duration of a first voltage of a first polarity, and a second duration of a second voltage of the first polarity. An absolute value of the second voltage is smaller than an absolute value of the first voltage.

A CO.sub.2 mass estimation system includes: an acquisition element acquiring detected values in accordance with concentrations of oxygen, H.sub.2O, and CO.sub.2 contained in an engine exhaust gas output from a gas sensor; a setting element setting an air-fuel ratio of a mixture; and a calculation element calculating the mass of CO.sub.2 contained in the exhaust gas, wherein the calculation element calculates the concentrations of oxygen, H.sub.2O, and CO.sub.2 contained in the exhaust gas based on the sensor detected values, acquires concentrations of oxygen and H.sub.2O in air and the air-fuel ratio, calculates a composition ratio of at least C atoms contained in fuel based on the concentrations in the exhaust gas, the concentrations in the air, and the air-fuel ratio, and estimates the mass of CO.sub.2 contained in the exhaust gas based on the composition ratio and the amount of injection of the fuel into the engine.