Abstract: A liquid chromatography interface is provided having an integrated column/ESI tip assembly including a liquid chromatography separation column, an ESI tip for generating ions having at least one emitting channel, and a temperature-controlled enclosure surrounding the liquid chromatography separation column. The enclosure has at least one opening and the ESI tip is exposed outside the enclosure through the opening. The enclosure has a heating or cooling device providing a substantially homogeneous distribution of temperature throughout an internal space of the enclosure where the liquid chromatography separation column is disposed. The enclosure includes at least one gas flow mixing element to permit heat exchange by directing a flow of gas toward the ESI tip. The integrated column/ESI tip assembly resides within a thermo-stabilized volume of substantially the same temperature from an entrance of the liquid chromatography separation column to the outlet of the ESI tip.

Abstract: A liquid chromatography interface is provided having an integrated column/ESI tip assembly including a liquid chromatography separation column, an ESI tip for generating ions having at least one emitting channel, and a temperature-controlled enclosure surrounding the liquid chromatography separation column. The enclosure has at least one opening and the ESI tip is exposed outside the enclosure through the opening. The enclosure has a heating or cooling device providing a substantially homogeneous distribution of temperature throughout an internal space of the enclosure where the liquid chromatography separation column is disposed. The enclosure includes at least one gas flow mixing element to permit heat exchange by directing a flow of gas toward the ESI tip. The integrated column/ESI tip assembly resides within a thermo-stabilized volume of substantially the same temperature from an entrance of the liquid chromatography separation column to the outlet of the ESI tip.

Abstract: An apparatus for mass analyzing molecules includes a mass spectrometer configured to select precursor ions having a mass to charge ratio range, a metastable species generator configured to generate a metastable species for introduction into the mass spectrometer, and a mass detector configured to detect a mass of the product ions. The apparatus also includes interaction region in the mass spectrometer where the precursor ions are converted into product ions via interaction of the precursor ions with the metastable species. The mass spectrometer includes at least one of a three-dimensional ion trap, a linear ion trap, or an ion guide. The interaction region is located inside the three-dimensional ion trap, the linear trap, or the ion guide; and at least one of the precursor ions or at least one of the product ions are excited by an alternating electric field or collisionally activated to produce additional product ions.

Abstract: An apparatus for analyzing a sample material includes a desorption mechanism configured to desorb molecules from the sample material, a metastable generator separate from the desorption mechanism and configured to generate a metastable species, and an interaction region configured for metastable species ionization of the desorbed molecules so as to produce gas-phase ions of the sample material.

Abstract: A method and system for producing an ion beam from an ion guide. In the method, ions are introduced into the ion guide, a radio frequency trapping field is generated in the ion guide to confine ions in a direction transverse to a longitudinal axis of the ion guide, a DC potential is generated along the longitudinal axis to direct ion motion along the longitudinal axis, a strength of the radio frequency trapping field is reduced toward an ion guide exit of the ion guide, and the ions are transmitted from the ion guide exit to form the ion beam. In the system, an ion guide is configured to transmit ions in a longitudinal axis of the ion guide and configured to trap ions in a direction transverse to the longitudinal axis via a radio frequency trapping field. The ion guide includes a segmented set of electrodes spaced along the longitudinal axis and an ion guide exit at the last of the segmented set of electrodes.

Abstract: An apparatus for mass analyzing molecules includes a mass spectrometer configured to select precursor ions having a mass to charge ratio range, a metastable species generator configured to generate a metastable species for introduction into the mass spectrometer, and a mass detector configured to detect a mass of the product ions. The apparatus also includes interaction region in the mass spectrometer where the precursor ions fragment into product ions via interaction of the precursor ions with the metastable species.

Abstract: A method and an apparatus for collecting ions in which ions are produced from a sample in an ion source. An electric field is provided that is more uniform in an area adjacent the sample than in an area adjacent an inlet to the ion transfer device or that is larger in field strength at the sample than at a point removed from the sample towards the inlet of the ion transfer device. Ions are received into the electric field and transferred through the ion transfer device to a sampling orifice of the mass spectrometer. The apparatus includes an ion transfer device coupled to a sampling orifice of a mass spectrometer. The ion transfer device has an inlet with a surface that extends in a direction from an axis of the ion transfer device. The ion transfer device can extend a distance of at least 10 times an inner diameter of a sampling orifice of the mass spectrometer.

Abstract: A method for ionizing a sample at ambient pressure including providing ionization-assisting molecules on a surface of a substrate, placing sample molecules on the surface of the substrate, and irradiating at least one of the sample molecules and the ionization-assisting molecules to produce ions of the sample molecules at or near atmospheric pressure. Accordingly, the system for ionizing sample molecules at or near atmospheric pressure is disclosed.

Abstract: An apparatus and method for generating ions from an aerosol and transferring the ions into a mass analyzer. In the apparatus and method, an aerosol beam is generated, the aerosol beam is directed to a spatial volume outside the mass analyzer, particles in the aerosol beam are ionized to produce the ions, and the ions are collected into the mass analyzer. As such the apparatus includes respectively an aerosol beam generator, an ion source generator, and an ion collector.

Abstract: A system and method for mass spectrometry in which the system includes at least one ion source which produces ions, a mass spectrometer having an inlet orifice configured to accept the ions, and a capillary ion delivery device which detachably interfaces to the inlet orifice of the mass spectrometer. The method includes producing ions from the ion source, transporting the ions from the ion source to the inlet orifice of the mass spectrometer via the capillary ion delivery device, and mass analyzing the ions in the mass spectrometer.

Abstract: A system and method for mass spectrometry in which the system includes at least one ion source which produces ions, a mass spectrometer having an inlet orifice configured to accept the ions, and a capillary ion delivery device which detachably interfaces to the inlet orifice of the mass spectrometer. The method includes producing ions from the ion source, transporting the ions from the ion source to the inlet orifice of the mass spectrometer via the capillary ion delivery device, and mass analyzing the ions in the mass spectrometer.