An electron multiplier apparatus of the type used in ion detectors, and modifications thereto for extending the operational lifetime or otherwise improving performance. The electron multiplier includes a series of discrete electron emissive surfaces configured to provide an electron amplification chain, the electron multiplier being configured so as to inhibit or prevent a contaminant from entering into, or passing partially through, or passing completely through the electron multiplier. The electron multiplier may include one or more baffles configured so as to decrease vacuum conductance of the electron multiplier compared to the same or similar electron multiplier not having one or more baffles.

An electron multiplier apparatus of the type used in ion detectors, and modifications thereto for extending the operational lifetime or otherwise improving performance. The electron multiplier includes a series of discrete electron emissive surfaces configured to provide an electron amplification chain, the electron multiplier being configured so as to inhibit or prevent a contaminant from entering into, or passing partially through, or passing completely through the electron multiplier. The electron multiplier may include one or more baffles configured so as to decrease vacuum conductance of the electron multiplier compared to the same or similar electron multiplier not having one or more baffles.

A CEM and an ion detector of one embodiment have a structure for enabling ion detection with higher sensitivity than the prior art. A channel electron multiplier includes a channel body, an input-side conductive layer, an output-side conductive layer, and an electrode. The channel body includes a channel, and a resistance layer and an electron emission layer formed on the channel's inner wall surface. The input-side conductive layer is provided on the channel body, and a part thereof extends into the tapered opening. The output-side conductive layer is provided on the tapered opening. The electrode has openings through which charged particles pass, and is disposed on an opposite side of the output end face to the input end face. The electrode and the input-side conductive layer are set to the same potential to eliminate the influence of an external electric field in the tapered opening.

A CEM and an ion detector of one embodiment have a structure for enabling ion detection with higher sensitivity than the prior art. A channel electron multiplier includes a channel body, an input-side conductive layer, an output-side conductive layer, and an electrode. The channel body includes a channel, and a resistance layer and an electron emission layer formed on the channel's inner wall surface. The input-side conductive layer is provided on the channel body, and a part thereof extends into the tapered opening. The output-side conductive layer is provided on the tapered opening. The electrode has openings through which charged particles pass, and is disposed on an opposite side of the output end face to the input end face. The electrode and the input-side conductive layer are set to the same potential to eliminate the influence of an external electric field in the tapered opening.

A first-stage dynode is a first-stage dynode to be used in a photomultiplier tube, and includes a bottom wall portion and a pair of side wall portions extending from both end portions of the bottom wall portion in a predetermined direction to one side. An electron emission surface is formed by a bottom surface of the bottom wall portion on the one side and a pair of side surfaces of the pair of side wall portions on the one side, and each of the pair of side surfaces is a curved surface that is curved in a concave shape in a cross section parallel to the predetermined direction.

A CEM and an ion detector of one embodiment have a structure for enabling ion detection with higher sensitivity than the prior art. A channel electron multiplier includes a channel body, an input-side conductive layer, an output-side conductive layer, and an electrode. The channel body includes a channel, and a resistance layer and an electron emission layer formed on the channel's inner wall surface. The input-side conductive layer is provided on the channel body, and a part thereof extends into the tapered opening. The output-side conductive layer is provided on the tapered opening. The electrode has openings through which charged particles pass, and is disposed on an opposite side of the output end face to the input end face. The electrode and the input-side conductive layer are set to the same potential to eliminate the influence of an external electric field in the tapered opening.

A CEM and an ion detector of one embodiment have a structure for enabling ion detection with higher sensitivity than the prior art. A channel electron multiplier includes a channel body, an input-side conductive layer, an output-side conductive layer, and an electrode. The channel body includes a channel, and a resistance layer and an electron emission layer formed on the channel's inner wall surface. The input-side conductive layer is provided on the channel body, and a part thereof extends into the tapered opening. The output-side conductive layer is provided on the tapered opening. The electrode has openings through which charged particles pass, and is disposed on an opposite side of the output end face to the input end face. The electrode and the input-side conductive layer are set to the same potential to eliminate the influence of an external electric field in the tapered opening.

A first-stage dynode is a first-stage dynode to be used in a photomultiplier tube, and includes a bottom wall portion and a pair of side wall portions extending from both end portions of the bottom wall portion in a predetermined direction to one side. An electron emission surface is formed by a bottom surface of the bottom wall portion on the one side and a pair of side surfaces of the pair of side wall portions on the one side, and each of the pair of side surfaces is a curved surface that is curved in a concave shape in a cross section parallel to the predetermined direction.

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.