A method is disclosed comprising: trapping ions in an ion trap (40); applying a first force on the ions within the ion trap in a first direction, said force having a magnitude that is dependent upon the value of a physicochemical property of the ions; applying a second force on these ions in the opposite direction so that the ions separate according to the physicochemical property value as a result of the first and second forces; and then pulsing or driving ions out of one or more regions of the ion trap.

A method of analysis using mass spectrometry or ion mobility spectrometry that includes producing ions from a sample in a proximity of the sample, transferring the produced ions from the sample to a distance with a flexible or re-configurable ion guide, the flexible or re-configurable ion guide being connected to RF voltages, and separating the produced ions with a mass to charge or mobility analyzer located at the distance to provide spectrometric results; and detecting the separated ions with at least one detector.

An apparatus includes a first pair of opposing electrode arrangements that confine ions between them in a portion of a confinement volume inwardly laterally in a first confinement direction with respect to a longitudinal ion propagation direction, each opposing electrode arrangement including an arrangement of RF electrodes situated to receive an unbiased RF voltage having an alternate phase between adjacent RF electrodes of the arrangement of RF electrodes so as to provide the confining of ions between the first pair of opposing electrode arrangements, and a second pair of opposing electrode arrangements that confine the ions between the second pair in the confinement volume inwardly laterally in a second confinement direction that complements the first confinement direction, each opposing electrode arrangement of the second pair including an arrangement of RF electrodes that receive an unbiased RF voltage having an alternate phase between adjacent RF electrodes.

An ion mobility separator and a method of separating ions according to their ion mobility are disclosed. An RF ion guide is provided having a plurality of electrodes that are arranged to form an ion guiding path that extends in a closed loop. RF voltages are supplied to at least some of the electrodes in order to confine ions within said ion guiding path. A DC voltage gradient is maintained along at least a portion of a longitudinal axis of the ion guide, wherein the voltage gradient urges ions to undergo one or more cycles around the ion guide and thus causes the ions to separate according to their ion mobility as the ions pass along the ion guide. The closed loop ion guide enables the resolution of the ion mobility separator to be increased without necessitating a large device, since the drift length through the device can be increased by causing the ions to undergo multiple cycles around the device.

A device for manipulating charged particles using an axial electric field as they travel along a longitudinal axis of the device is disclosed. The method comprises providing an outer electrode for generating an electric field and providing a plurality of inner electrodes that are separated by gaps of different lengths. The electric field generated by the outer electrode penetrates the gaps between the inner electrodes and the gaps are selected such that the desired potential profile is arranged along the longitudinal axis in order to manipulate the charged particles in the desired manner.

The invention provides a trapped ion mobility separator (TIMS) and methods to operate it wherein an ion region of the TIMS, through which ions travel along an axis from an entrance to an exit, has an elongate cross-sectional profile perpendicular to the axis with a long dimension and a short dimension. First and second counteracting forces on the ions along the axis are provided, wherein at least one of the first and second forces has an effect on the ions that is ion mobility dependent, and wherein at least one of the first and second forces varies spatially along the axis such that ions are trapped and separated by ion mobility. Different embodiments provide the first and second forces using different combinations of gas flow and electric field potential, and employ various electrode structures that provide the system with different advantageous characteristics.

A system is provided that includes: at least one radio frequency (RF) electrode extending along a first direction, the at least one RF electrode configured to generate an RF field, where a first RF electrode of the least one RF electrode is disposed in a substrate, and a plurality of direct current (DC) electrodes that are spaced apart along at least the first direction, the plurality of DC electrodes configured to generate an electric field, where the RF field and the electric field are configured to trap an ion at a first position, the first position being spaced apart from the substrate by a first distance, where each DC electrode of the plurality of DC electrodes has a respective width in the first direction that is less or equal to 0.2 times the first distance.

An ion mobility separator and a method of separating ions according to their ion mobility are disclosed. An RF ion guide is provided having a plurality of electrodes that are arranged to form an ion guiding path that extends in a closed loop. RF voltages are supplied to at least some of the electrodes in order to confine ions within said ion guiding path. A DC voltage gradient is maintained along at least a portion of a longitudinal axis of the ion guide, wherein the voltage gradient urges ions to undergo one or more cycles around the ion guide and thus causes the ions to separate according to their ion mobility as the ions pass along the ion guide. The closed loop ion guide enables the resolution of the ion mobility separator to be increased without necessitating a large device, since the drift length through the device can be increased by causing the ions to undergo multiple cycles around the device.

An ion guide is disclosed comprising a first array of electrodes and a second array of electrodes and one or more apertures or ion exit regions. The first array of electrodes comprises a first plurality of arcuate electrodes arranged in parallel with one another and such that said first plurality of arcuate electrodes at least partially surround said one or more apertures or ion exit regions and/or wherein said second array of electrodes comprises a second plurality of arcuate electrodes arranged in parallel with one another and such that said second plurality of arcuate electrodes at least partially surround said one or more apertures or ion exit regions. The ion guide comprises a first device arranged and adapted to apply an AC or RF voltage to said first array of electrodes and to said second array of electrodes so as to confine ions within said ion guide in a first (z) direction that extends in a direction between said first and second arrays, and a second device arranged and adapted to apply one or more DC voltages to said first array of electrodes and/or to said second array of electrodes so as to urge ions within said ion guide in a second (r) direction towards said one or more apertures or ion exit regions, such that ions within said ion guide are caused to migrate to said one or more apertures or ion exit regions.

The invention provides a trapped ion mobility separator (TIMS) and methods to operate it wherein an ion region of the TIMS, through which ions travel along an axis from an entrance to an exit, has an elongate cross-sectional profile perpendicular to the axis with a long dimension and a short dimension. First and second counteracting forces on the ions along the axis are provided, wherein at least one of the first and second forces has an effect on the ions that is ion mobility dependent, and wherein at least one of the first and second forces varies spatially along the axis such that ions are trapped and separated by ion mobility. Different embodiments provide the first and second forces using different combinations of gas flow and electric field potential, and employ various electrode structures that provide the system with different advantageous characteristics.