Patent ID: 9111736
Filing Date: 2015-08-18
Classification: H01J

Abstract:
1. A mass spectrometer that is a triple quadrupole mass spectrometer in which a first-stage quadrupole mass filter and a second-stage quadrupole mass filter are placed on opposite sides of a collision cell for dissociating ions such that one or more components in a liquid sample are introduced into an ion source in such a manner that a temporal change in a density of the components has a peak shape, are ionized, and are undergone mass spectrometry, wherein tunings to optimize control parameters of various parts are performed based on results of mass spectrometry of known components in a sample, the mass spectrometer comprising: a) a parameter setting means for changing a value of a collision energy for dissociating when the ions are dissociated in the collision cell, at predetermined intervals within a predetermined range, the value of the collision energy being one of the control parameters to be adjusted; b) a result acquisition means for acquiring a mass spectrometry result each time the value of the collision energy is changed by the parameter setting means; and c) a parameter optimization means which is capable of working either in a coarse adjustment mode in which the value of the collision energy is changed at first intervals in a first predetermined range by the parameter setting means or in a fine adjustment mode in which the value of the collision energy is changed at second intervals smaller than the first intervals in a second predetermined range narrower than the first predetermined range, and which, during a period in which a target component in the sample is introduced into the ion source by one sample injection, first, in the coarse adjustment mode determines an approximate value of the collision energy based on the mass spectrometry result obtained by the result acquisition means, after which the parameter optimization means switches to the fine adjustment mode, sets the collision energy range to the neighborhood of the approximate value, and subsequently, in the fine adjustment mode for the second predetermined range set to include the approximate value determined by the coarse adjustment mode determines an optimal value of the collision energy based on the mass spectrometry result obtained by the result acquisition means, and the parameter optimization means obtains the optimal value of the collision energy for each of a plurality of product ions.