This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

The present disclosure provides a system for detection and measuring of a radioactive gas within a target environment. In certain embodiments, the system comprises a data processing system and a monitoring device disposed within the target environment. In some forms the monitoring device comprises: a radiation sensor configured to detect the concentration of a radioactive gas in the target environment, a transmitter electrically coupled to the radiation sensor and configured for transmitting a signal to the data processing system, and a receiver for receiving signals from the data processing system, wherein the monitoring device is configured to detect the concentration of the radioactive gas at least every twenty minutes.

The present disclosure provides a system for detection and measuring of a radioactive gas within a target environment. In certain embodiments, the system comprises a data processing system and a monitoring device disposed within the target environment. In some forms the monitoring device comprises: a radiation sensor configured to detect the concentration of a radioactive gas in the target environment, a transmitter electrically coupled to the radiation sensor and configured for transmitting a signal to the data processing system, and a receiver for receiving signals from the data processing system, wherein the monitoring device is configured to detect the concentration of the radioactive gas at least every twenty minutes.

This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

A system for equalizing a pressure in an ionization chamber of a radiation device is provided. The system may include the ionization chamber including: a chamber housing including one or more chamber walls; a chamber volume inside the chamber housing, the chamber volume being filled with a radiation sensitive material; and a pressure adjustment apparatus operably coupled to the chamber volume via at least one wall of the one or more chamber walls, the pressure adjustment apparatus being configured to equalize a first pressure of the radiation sensitive material inside the chamber volume and a second pressure of ambient air outside the chamber housing.

A system for equalizing a pressure in an ionization chamber of a radiation device is provided. The system may include the ionization chamber including: a chamber housing including one or more chamber walls; a chamber volume inside the chamber housing, the chamber volume being filled with a radiation sensitive material; and a pressure adjustment apparatus operably coupled to the chamber volume via at least one wall of the one or more chamber walls, the pressure adjustment apparatus being configured to equalize a first pressure of the radiation sensitive material inside the chamber volume and a second pressure of ambient air outside the chamber housing.

A narrow thermal neutron detector includes a slidably receivable ionization thermal neutron detector module within an overall housing body. An active sheet layer of the ionization thermal neutron detector module can be tensioned across its width. The ionization thermal neutron detector module can include module upper major surface extents and module lower surface extents such that, when installed within the housing body, the module upper major surface extents are in a first spaced apart confronting relationship with housing upper major surface extents to define a first clearance and module lower major surface extents are in a second spaced apart confronting relationship with housing lower major surface extents to define a second clearance to accommodate housing flexing due to ambient pressure change. The housing body can be formed with a single opening for receiving the ionization thermal neutron detection module or with opposing first and second opposing end openings.

A narrow thermal neutron detector includes a slidably receivable ionization thermal neutron detector module within an overall housing body. An active sheet layer of the ionization thermal neutron detector module can be tensioned across its width. The ionization thermal neutron detector module can include module upper major surface extents and module lower surface extents such that, when installed within the housing body, the module upper major surface extents are in a first spaced apart confronting relationship with housing upper major surface extents to define a first clearance and module lower major surface extents are in a second spaced apart confronting relationship with housing lower major surface extents to define a second clearance to accommodate housing flexing due to ambient pressure change. The housing body can be formed with a single opening for receiving the ionization thermal neutron detection module or with opposing first and second opposing end openings.