Scientific instruments (such as mass spectrometers) include an electron multiplier and a cross-filed ion detector including an ion impact plate. The electron multiplier receives and amplifies secondary electrons emitted by the impact plate to generate an output signal. The output signal is amplified and subsequently digitized. Amplification is limited so as to keep secondary electrons to a maximum thereby decreasing electron flux and improving instrument life.

Scientific instruments (such as mass spectrometers) include an electron multiplier and a cross-filed ion detector including an ion impact plate. The electron multiplier receives and amplifies secondary electrons emitted by the impact plate to generate an output signal. The output signal is amplified and subsequently digitized. Amplification is limited so as to keep secondary electrons to a maximum thereby decreasing electron flux and improving instrument life.

An ion detector includes: a first electron multiplier for detecting first ions having a first polarity; a second electron multiplier for detecting second ions having a second polarity different from the first polarity; a first anode for capturing electrons emitted from the first electron multiplier; a second anode for capturing electrons emitted from the second electron multiplier; and a switching circuit including a first input terminal electrically connected to the first anode, a second input terminal electrically connected to the second anode, and an output terminal, the switching circuit selectively connecting one of the first input terminal and the second input terminal to the output terminal.

An ion detector includes: a first electron multiplier for detecting first ions having a first polarity; a second electron multiplier for detecting second ions having a second polarity different from the first polarity; a first anode for capturing electrons emitted from the first electron multiplier; a second anode for capturing electrons emitted from the second electron multiplier; and a switching circuit including a first input terminal electrically connected to the first anode, a second input terminal electrically connected to the second anode, and an output terminal, the switching circuit selectively connecting one of the first input terminal and the second input terminal to the output terminal.

Provided are an automatic analyzer and an optical measurement method for correcting a variation in the multiplication factor of a photoelectric element with high accuracy. The automatic analyzer comprises: a photoelectric element which generates electrons by light and outputs a current signal; a voltage application unit which applies a voltage to the photoelectric element; and a processing unit which corrects a variation in the multiplication factor of the photoelectric element, wherein the photoelectric element outputs a pulse signal as the current signal, and the processing unit corrects the variation in the multiplication factor on the basis of the pulse area of the pulse signal.

A photomultiplier tube (PMT) detector assembly includes a PMT and an analog PMT detector circuit. The PMT includes a photocathode configured to emit an initial set of photoelectrons in response to an absorption of photons. The PMT includes a dynode chain with a plurality of dynodes. The dynode chain is configured to receive the initial set of photoelectrons, generate at least one amplified set of photoelectrons, and direct the at least one amplified set of photoelectrons. The PMT includes an anode configured to receive the at least one amplified set of photoelectrons, with a digitized image being generated based on a measurement of the final amplified set of photoelectrons. The digitized image is corrected by applying an output of the signal measured by the analog PMT detector circuit to the digitized image.

A photomultiplier tube (PMT) detector assembly includes a PMT and an analog PMT detector circuit. The PMT includes a photocathode configured to emit an initial set of photoelectrons in response to an absorption of photons. The PMT includes a dynode chain with a plurality of dynodes. The dynode chain is configured to receive the initial set of photoelectrons, generate at least one amplified set of photoelectrons, and direct the at least one amplified set of photoelectrons. The PMT includes an anode configured to receive the at least one amplified set of photoelectrons, with a digitized image being generated based on a measurement of the final amplified set of photoelectrons. The digitized image is corrected by applying an output of the signal measured by the analog PMT detector circuit to the digitized image.

Systems and methods for partial discharge reduction are provided. The systems and methods can receive an input voltage at a high voltage sensor configured within a sealed sensor assembly. The input voltage can be received via a discharge reduction of the sealed sensor assembly. The discharge reduction circuit can reduce an incidence of discharge associated with an ionization breakdown of an air gap between an output circuit of the sealed sensor assembly and an insulator conveying the output circuit through a hermetic barrier of the sealed sensor assembly.

Systems and methods for partial discharge reduction are provided. The systems and methods can receive an input voltage at a high voltage sensor configured within a sealed sensor assembly. The input voltage can be received via a discharge reduction of the sealed sensor assembly. The discharge reduction circuit can reduce an incidence of discharge associated with an ionization breakdown of an air gap between an output circuit of the sealed sensor assembly and an insulator conveying the output circuit through a hermetic barrier of the sealed sensor assembly.

Systems and methods for partial discharge reduction are provided. The systems and methods can receive an input voltage at a high voltage sensor configured within a sealed sensor assembly. The input voltage can be received via a discharge reduction of the sealed sensor assembly. The discharge reduction circuit can reduce an incidence of discharge associated with an ionization breakdown of an air gap between an output circuit of the sealed sensor assembly and an insulator conveying the output circuit through a hermetic barrier of the sealed sensor assembly.