A mass spectrometer is disclosed comprising a rotatable isolation valve (1) having a curved, spherical, cylindrical or concave portion. At least a portion of an ion guide (2) is positioned so as to extend within a swept volume of the isolation valve (1) enabling the ion guide (2) to be positioned close to a second downstream ion guide (3) and for ions to be transmitted from the first (2) ion guide to the second ion guide (3) with high ion transmission efficiency.

The invention relates to hybrid IMS/MS systems and provides hybrid IMS/MS system comprising an RF funnel, an ion mobility analyzer and a mass analyzer wherein the RF funnel is arranged non-collinearly to the ion mobility analyzer, preferably a TIMS analyzer (TIMS=trapped ion mobility spectrometry).

A device includes a first surface, a second surface and a controller. The second surface is adjacent to the first surface. The first and the second surfaces define a first ion channel therebetween. The first ion channel extends along a first direction. The second surface includes a first plurality of electrodes including a first electrode and a second electrode spaced apart from the first electrode along a second direction lateral to the first direction. The first plurality of electrodes extends along the first direction. The first electrode is configured to receive a first voltage signal and generate at least a portion of a pseudopotential that inhibits ions in the first ion channel from approaching the second surface. The second plurality of electrodes is located between the first electrode and the second electrode and arranged along the first direction. The second plurality of electrodes are configured to receive a second voltage signal to generate a first traveling drive potential that travels along the first direction. The first traveling drive potential is configured to guide ions along the first ion channel. The device further includes a controller electrically coupled to the first and the second surface. The controller is configured to generate the first voltage signal and the second voltage signal.

A mass spectrometer is disclosed comprising an ion mobility spectrometer or separator and an ion guide arranged downstream of the ion mobility spectrometer or separator. A plurality of axial potential wells are created in the ion guide so that ions received from the ion mobility spectrometer or separator become confined in separate axial potential wells. The potential wells maintain the fidelity and/or composition of ions received from the ion mobility spectrometer or separator. The potential wells are translated along the length of the ion guide.

Apparatus include a plurality of electrode arrangements spaced apart from each other opposite an ion propagation axis and defining an ion transfer channel that extends along the ion propagation axis that tapers between an input end that is situated to receive ions and an output end that is situated to couple the received ions to an input end of an ion guide. Methods include positioning a plurality of electrode arrangements at oblique angles opposite an ion propagation axis so as to form a ion transfer channel that tapers between an input end and an output end, and coupling the output end of the ion transfer channel to an input end of an ion optical element so as to direct ions in the ion transfer channel into the ion optical element. Related systems are also disclosed.

Provided is an ion transport device 1 including: a drift tube 10 having a plurality of ring-shaped electrodes 11 arranged in an axial direction; a housing 30 containing the drift tube 10; a drift-tube support member 21 supporting the drift tube 10 in relation to the housing 30; a detector 20 fixed to the drift tube 10 and configured to detect ions; and a vibration damper 22 provided on the drift-tube support member 21 and configured to absorb vibration which the drift-tube support member 21 receives from the housing 30. By such a configuration, an occurrence of noise in a detection signal of the detector 20 due to an influence of the vibration can be prevented.

The present invention provides for a differential electrochemical mass spectrometry (DEMS) cell comprising a working electrode chamber configured such that an electrolyte enters the working electrode chamber through a channel running through the working electrode.

The invention provides a mass spectrometer, an ion optical device, and a method for ion manipulation in a mass spectrometer. The mass spectrometer includes a mass analyzer; and an ion guiding device, including two electrode arrays positioned in parallel with each other, each electrode array including at least two ring electrodes concentrically disposed or at least three linear electrode assemblies having a radial distribution; and a power supply means, configured to apply a voltage on at least a part of the ring electrodes, to form a radio-frequency electric field and a DC electric field. By means of the radio-frequency electric field and the DC electric field, ions are allowed to be stored in a region between the two arrays, and controlled to be sequentially released along a radial direction according to a preset mass-to-charge ratio requirement, then exit the ion guiding device and enter the mass analyzer for mass analysis.

A ring stacked accelerator for use in a mass spectrometer includes a plurality of ring shaped plates arranged in a stack and is electrically coupled to a voltage divider that allows a substantially homogeneous electric field to be produced when the stack is energized. The voltage divider can include resistors and capacitors, where the capacitors are chosen to compensate for parasitic capacitances experienced by the plates. The ring stacked accelerator can be energized using an RF pulse. The ring stack accelerator can include one or more balancing capacitors for correcting effects that cause nonlinearity.

A mass spectrometer is disclosed comprising an ion mobility spectrometer or separator and an ion guide arranged downstream of the ion mobility spectrometer or separator. A plurality of axial potential wells are created in the ion guide so that ions received from the ion mobility spectrometer or separator become confined in separate axial potential wells. The potential wells maintain the fidelity and/or composition of ions received from the ion mobility spectrometer or separator. The potential wells are translated along the length of the ion guide.