An MCP assembly of this embodiment is provided with an MCP unit and a flexible sheet electrode having a structure for facilitating handling thereof as a single body. The flexible sheet electrode is constituted by a mesh area provided with plural openings and a deformation suppressing portion surrounding the mesh area. Both the mesh area and the deformation suppressing portion are comprised of the same conductive material, and physical strength of the deformation suppressing portion is higher than that of the mesh area. With this configuration, the physical strength of an entire flexible sheet electrode is secured even if an opening ratio of the mesh area is increased, so that the handling of the flexible sheet electrode as a single body is facilitated.

A photomultiplier includes a housing including a proximal end and a distal end, an optical window disposed at the proximal end of the housing, an end-wall plate disposed at the distal end of the housing, a feedthrough that penetrates through the end-wall plate, and a gas electron multiplier (GEM) board disposed between the optical window and the end-wall plate.

A photomultiplier includes a housing including a proximal end and a distal end, an optical window disposed at the proximal end of the housing, an end-wall plate disposed at the distal end of the housing, a feedthrough that penetrates through the end-wall plate, and a gas electron multiplier (GEM) board disposed between the optical window and the end-wall plate.

The MCP assembly of this embodiment is formed at least of a conductive upper support member, an MCP unit, an output electrode, a flexible sheet electrode, and a conductive lower support member as a structure for improving handleability of a flexible sheet electrode having a mesh area. The flexible sheet electrode includes the mesh area provided with plural openings. The flexible sheet electrode and the lower support member are physically and electrically connected to each other, and the flexible sheet electrode is sandwiched between the upper support member and the lower support member. As a result, even if the flexible sheet electrode becomes thin as an opening ratio of the mesh area increases, potential is set while the flexible sheet electrode is firmly held in the MCP assembly.

The MCP assembly of this embodiment is formed at least of a conductive upper support member, an MCP unit, an output electrode, a flexible sheet electrode, and a conductive lower support member as a structure for improving handleability of a flexible sheet electrode having a mesh area. The flexible sheet electrode includes the mesh area provided with plural openings. The flexible sheet electrode and the lower support member are physically and electrically connected to each other, and the flexible sheet electrode is sandwiched between the upper support member and the lower support member. As a result, even if the flexible sheet electrode becomes thin as an opening ratio of the mesh area increases, potential is set while the flexible sheet electrode is firmly held in the MCP assembly.

Components of scientific analytical equipment. More particularly, ion detectors of the type which incorporate electron multipliers and modifications thereto for extending the operational lifetime or otherwise improving performance. The ion detector may be embodied in the form of a particle detector having one or more electron emissive surfaces and/or an electron collector surface therein, the particle detector being configured such that in operation the environment about the electron emissive surface(s) and/or the electron collector surface is/are different to the environment immediately external to the detector.

Components of scientific analytical equipment. More particularly, ion detectors of the type which incorporate electron multipliers and modifications thereto for extending the operational lifetime or otherwise improving performance. The ion detector may be embodied in the form of a particle detector having one or more electron emissive surfaces and/or an electron collector surface therein, the particle detector being configured such that in operation the environment about the electron emissive surface(s) and/or the electron collector surface is/are different to the environment immediately external to the detector.

Components of scientific analytical equipment, such as electron multipliers and modifications thereto, for extending the operational lifetime or otherwise improving performance by way of improved construction. A detector includes one or more electron emissive surfaces and one or more detector elements configured to define on one side an environment internal the detector and on the other side an environment external the detector. The one or more detector elements are configured to inhibit or prevent flow of a gas from the environment external the detector to the environment internal the detector. Such detectors may be used in a mass spectrometry instrument, for example.

Components of scientific analytical equipment, such as electron multipliers and modifications thereto, for extending the operational lifetime or otherwise improving performance by way of improved construction. A detector includes one or more electron emissive surfaces and one or more detector elements configured to define on one side an environment internal the detector and on the other side an environment external the detector. The one or more detector elements are configured to inhibit or prevent flow of a gas from the environment external the detector to the environment internal the detector. Such detectors may be used in a mass spectrometry instrument, for example.

The present invention relates to generally to components of scientific analytical equipment. More particularly, the invention relates to ion detectors of the type which incorporate electron multipliers and modifications thereto for extending the operational lifetime or otherwise improving performance. The invention may be embodied in the form of a particle detector having one or more electron emissive surfaces and/or an electron collector surface therein, the particle detector being configured such that in operation the environment about the electron emissive surface(s) and/or the electron collector surface is/are different to the environment immediately external to the detector.