Abstract: A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Abstract: A method of analyzing a sample, the method includes separating precursor ions from the sample into narrow mass range groups based on mass-to-charge ratio; fragmenting the ions from each group to create groups of fragment ions; and mass analyzing fragment ions from each group of fragment ions using a long transient time mass analyzer, wherein the separation and fragmentation are decoupled from the mass analyzing and the cycle time of the high transient mass analyzer is greater than about five times longer than the cycle time of a narrow mass range scan time, and wherein the separation and fragmentation has a high duty cycle and the mass analyzing has a high duty cycle.

Abstract: A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Abstract: An electrospray ion source for a mass spectrometer comprises: (i) a plurality of N electrospray emitters within an ionization compartment, wherein N?2; (ii) a mixing chamber; (iii) a plurality of N inlets, each inlet comprising a conduit configured to receive charged particles from a respective one of the electrospray emitters and to emit the charged particles into the mixing chamber; (iv) an outlet port either facing or within an intermediate-vacuum compartment; and (v) a heater in thermal contact with at least a portion of the mixing chamber.

Abstract: An ion mobility device includes a plurality of electrodes and a current source. The plurality of electrodes arranged along an axis extending from a first end to a second end. The plurality of electrodes configured to receive a gas flow at the second end and provide for an expansion of the gas flow from the second end to the first end such that a first gas velocity at the second end is greater than a second gas velocity at the first end. The current source is configured to apply a first potential to the plurality of electrodes to generate a first electric field during a trapping and equilibration time period; and apply a second potential to the electrodes during an ejection time period to generate a second electric field, the second electric field being greater than the first electric field.

Abstract: A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Abstract: A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Abstract: An electrospray ion source for a mass spectrometer comprises: (i) a plurality of N electrospray emitters within an ionization compartment, wherein N?2; (ii) a mixing chamber; (iii) a plurality of N inlets, each inlet comprising a conduit configured to receive charged particles from a respective one of the electrospray emitters and to emit the charged particles into the mixing chamber; (iv) an outlet port either facing or within an intermediate-vacuum compartment; and (v) a heater in thermal contact with at least a portion of the mixing chamber.

Abstract: A mass selective ion trapping device includes a linear ion trap and a RF control circuitry. The ion trap includes a plurality of trap electrodes configured for generating a quadrupolar trapping field in a trap interior and for mass selective ejection of ions from the trap interior. The RF control circuitry is configured to apply a balanced AC voltage to the trap electrodes during a first period of time such that an AC voltage applied to a first pair of trap electrodes is of the same magnitude and of opposite sign to an AC voltage applied to a second pair of trap electrodes; apply unbalanced RF voltage to the second pair of trap electrodes during a second period of time; ramp the balanced AC voltage down and the unbalanced RF voltage up during a transition period; and eject ions from the linear ion trap after the second period of time.

Abstract: A method of analyzing a sample, the method includes separating precursor ions from the sample into narrow mass range groups based on mass-to-charge ratio; fragmenting the ions from each group to create groups of fragment ions; and mass analyzing fragment ions from each group of fragment ions using a long transient time mass analyzer, wherein the separation and fragmentation are decoupled from the mass analyzing and the cycle time of the high transient mass analyzer is greater than about five times longer than the cycle time of a narrow mass range scan time, and wherein the separation and fragmentation has a high duty cycle and the mass analyzing has a high duty cycle.

Abstract: A method of analyzing a sample, the method includes separating precursor ions from the sample into narrow mass range groups based on mass-to-charge ratio; fragmenting the ions from each group to create groups of fragment ions; and mass analyzing fragment ions from each group of fragment ions using a long transient time mass analyzer, wherein the separation and fragmentation are decoupled from the mass analyzing and the cycle time of the high transient mass analyzer is greater than about five times longer than the cycle time of a narrow mass range scan time, and wherein the separation and fragmentation has a high duty cycle and the mass analyzing has a high duty cycle.

Abstract: An ion separation device comprising a plurality of electrodes arranged in a two-dimensional grid, a gas supply configured to provide a gas flow along the first direction, and an ion inlet arranged to receive ions. The plurality of electrodes is configured to create one or more pseudopotential barriers of increasing magnitude along a first direction. A drag force is applied to the ions by the gas flow is opposed by a pseudopotential gradient of the plurality of electrodes.

Abstract: A method of analyzing a sample, the method includes separating precursor ions from the sample into narrow mass range groups based on mass-to-charge ratio; fragmenting the ions from each group to create groups of fragment ions; and mass analyzing fragment ions from each group of fragment ions using a long transient time mass analyzer, wherein the separation and fragmentation are decoupled from the mass analyzing and the cycle time of the high transient mass analyzer is greater than about five times longer than the cycle time of a narrow mass range scan time, and wherein the separation and fragmentation has a high duty cycle and the mass analyzing has a high duty cycle.

Abstract: An apparatus for separating ions includes an electrode arrangement having a length extending between first and second ends. The first end is configured to introduce a beam of ions into an ion transmission space of the arrangement. An electronic controller applies an RF potential and a DC potential to an electrode of the electrode arrangement, for generating a ponderomotive RF electric field and a mass-independent DC electric field. The application of the potentials is controlled such that a ratio of the strength of the ponderomotive RF electric field to the strength of the mass-independent DC electric field varies along the length of the electrode arrangement. The generated electric field supports extraction of ions having different m/z values at respective different positions along the length of the electrode arrangement. Ions are extracted in one of increasing and decreasing sequential order of m/z ratio with increasing distance from the first end.

Abstract: An apparatus for separating ions includes an electrode arrangement having a length extending between first and second ends. The first end is configured to introduce a beam of ions into an ion transmission space of the arrangement. An electronic controller applies an RF potential and a DC potential to an electrode of the electrode arrangement, for generating a ponderomotive RF electric field and a mass-independent DC electric field. The application of the potentials is controlled such that a ratio of the strength of the ponderomotive RF electric field to the strength of the mass-independent DC electric field varies along the length of the electrode arrangement. The generated electric field supports extraction of ions having different m/z values at respective different positions along the length of the electrode arrangement. Ions are extracted in one of increasing and decreasing sequential order of m/z ratio with increasing distance from the first end.

Abstract: An ion transport device of a mass spectrometer includes a plurality of pole rod arranged in first and second parallel rows and a controller. The controller is configured to apply voltages in a repeating voltage pattern to the pole rods of the first row and apply a common voltage to the pole rods of the second row thereby creating a plurality of potential wells capable of capturing ions, wherein each ion transport cell receives the same pattern of voltages; move the repeating voltage pattern along the pole rods of the first row to move captured ions within and between the plurality of ion transport cells along the ion transport device; and apply at least one ejection voltage to one or more electrodes to cause ions to be ejected from the ion transport device.

Abstract: An apparatus for separating ions includes an electrode arrangement having a length extending between first and second ends. The first end is configured to introduce a beam of ions into an ion transmission space of the arrangement. An electronic controller applies an RF potential and a DC potential to an electrode of the electrode arrangement, for generating a ponderomotive RF electric field and a mass-independent DC electric field. The application of the potentials is controlled such that a ratio of the strength of the ponderomotive RF electric field to the strength of the mass-independent DC electric field varies along the length of the electrode arrangement. The generated electric field supports extraction of ions having different m/z values at respective different positions along the length of the electrode arrangement. Ions are extracted in one of increasing and decreasing sequential order of m/z ratio with increasing distance from the first end.

Abstract: A device and associated method are disclosed for interfacing an ion trap to a pulsed mass analyzer (such as a time-of-flight analyzer) in a mass spectrometer. The device includes a plurality of separate confinement cells and structures for directing ions into a selected one of the confinement cells. Ions are ejected from the ion trap in a series of temporally successive ion packets. Each ion packet (which may consist of ions of like mass-to-charge ratio), is received by the ion interface device, fragmented to form product ions, and then stored and cooled in the selected confinement cell. Storage and cooling of the ion packet occurs concurrently with the receipt and storage of at least one later-ejected ion packet. After a predetermined cooling period, the ion packet is released to the mass analyzer for acquisition of a mass spectrum.

Abstract: A system for analyzing a sample includes a linear ion trap, an insert DC electrode, a voltage controller, and an RF control circuitry. The linear ion trap includes a first pair of trap electrodes and a second pair of trap electrodes spaced apart from each other and surrounding a trap interior. An electrode of the second pair of trap electrodes includes a trap exit. The insert DC electrode is positioned adjacent to the trap exit. The voltage controller applies a DC voltage to the insert DC electrode. The RF control circuitry applies a main RF voltage to the first pair of trap electrodes, applies a portion of the main RF to the second pair of trap electrodes, increases the main RF applied to the first pair of trap electrodes, and applies an auxiliary RF voltage to the second pair of trap electrodes.

Abstract: A system for analyzing a sample includes a linear ion trap, an insert DC electrode, a voltage controller, and an RF control circuitry. The linear ion trap includes a first pair of trap electrodes and a second pair of trap electrodes spaced apart from each other and surrounding a trap interior. An electrode of the second pair of trap electrodes includes a trap exit. The insert DC electrode is positioned adjacent to the trap exit. The voltage controller applies a DC voltage to the insert DC electrode. The RF control circuitry applies a main RF voltage to the first pair of trap electrodes, applies a portion of the main RF to the second pair of trap electrodes, increases the main RF applied to the first pair of trap electrodes, and applies an auxiliary RF voltage to the second pair of trap electrodes.