Patent application number | Description | Published |
20080315085 | FAIMS Cell Having an Offset Ion Inlet Orifice - A FAIMS cell has an elongated inner electrode with a longitudinal axis extending along a first direction. The inner electrode has a curved outer surface that defines a circle when viewed in a cross section that is taken in a plane normal to the longitudinal axis, which itself passes through the center of the circle so defined. An outer electrode having an inner surface is disposed in a spaced-apart facing relationship relative to the outer surface of the inner electrode so as to define an analytical gap therebetween. A first ion inlet orifice is defined through a first portion of the outer electrode, and an ion outlet orifice is defined through a second portion of the outer electrode. In particular, the first ion inlet orifice has a first ion injection axis that does not pass through the center of the circle. Furthermore, the second electrode does not have defined through any portion thereof an ion inlet orifice having an ion injection axis that passes through the center of the circle. | 12-25-2008 |
20090045062 | ION TRANSPORT DEVICE AND MODES OF OPERATION THEREOF - A device for transporting and focusing ions in a low vacuum or atmospheric-pressure region of a mass spectrometer is constructed from a plurality of longitudinally spaced apart electrodes to which oscillatory (e.g., radio-frequency) voltages are applied. In order to create a tapered field that focuses ions to a narrow beam near the device exit, the inter-electrode spacing or the oscillatory voltage amplitude is increased in the direction of ion travel. | 02-19-2009 |
20090159796 | Quadrupole FAIMS Apparatus - A combined rf-only/FAIMS apparatus is disclosed for use in mass spectrometry and other applications. The disclosed apparatus includes a plurality of curved electrodes arranged around a central ion transmission channel. FAIMS functionality is removed electronically when not desired by application of radio frequency (rf) waveforms to the curved electrodes. | 06-25-2009 |
20100090104 | ELECTRO-DYNAMIC OR ELECTRO-STATIC LENS COUPLED TO A STACKED RING ION GUIDE - A device for improved transportation and focusing of ions in a low vacuum or atmospheric-pressure region of a mass spectrometer is constructed from one or more electro-dynamic or electrostatic focusing lenses that is/are coupled to the first electrode of a stacked ring ion guide (SRIG) to which oscillatory (e.g., radio-frequency) voltages are applied. Such configurations as disclosed herein, minimizes deleterious field effects and/or repositioning problems of desired ion transfer instruments that utilize such stacked ring ion guides by generally configuring the outlet end of the ion transfer device to a desired position within the electro-dynamic or electro-static focusing lens(es). | 04-15-2010 |
20100276584 | Method and Apparatus for an Ion Transfer Tube and Mass Spectrometer System Using Same - A method for analyzing a sample comprising the steps of: generating ions from the sample within an ionization chamber at substantially atmospheric pressure; entraining the ions in a background gas; transferring the background gas and entrained ions to an evacuated chamber of a mass spectrometer system using an ion transfer tube having an inlet end and an outlet end, wherein a portion of the ion transfer tube adjacent to the outlet end comprises an inner diameter that is greater than an inner diameter of an adjoining portion of the ion transfer tube; and analyzing the ions using a mass analyzer of the mass spectrometer system. | 11-04-2010 |
20110139972 | Methods and Apparatus for Providing FAIMS Waveforms Using Solid-State Switching Devices - A high field asymmetric waveform ion mobility spectrometry (FAIMS) comprises an electrical power supply electrically connected to at least one of the FAIMS electrodes and operable to as to apply a periodic asymmetric square-wave waveform voltage to at least one of the electrodes so as to selectively transmit a type of ion in and through a FAIMS analyzer region to an ion outlet, wherein the electrical power supply is operable so as to vary a time duration of pulses of the asymmetric square-wave waveform so as to control the type of ion selectively transmitted, an efficiency of said selective transmission or the ability to prevent transmission of a different type of ions in and through said analyzer region to the ion outlet. | 06-16-2011 |
20110147576 | Apparatus and Methods for Pneumatically-Assisted Electrospray Emitter Array - An electrospray ion source comprises a source of analyte-bearing liquid; a source of sheath gas; a plurality of liquid conduits, each configured so as to receive a portion of the analyte-bearing liquid; at least one electrode associated with the plurality of liquid conduits for producing electrospray emission of charged droplets from an outlet of each of the liquid conduits; a power supply electrically coupled to the at least one electrode for maintaining the at least one electrodes at an electrical potential; and either one or a plurality of sheath gas conduits, each sheath gas conduit comprising an inlet configured to receive sheath gas and an outlet configured to emit a sheath gas flow that circumferentially surrounds, in at least two dimensions, a portion of the emitted charged droplets. | 06-23-2011 |
20110253890 | FAIMS Having a Displaceable Electrode for On/Off Operation - A system for analyzing ions comprises: an ion source; a FAIMS cell comprising: (a) a gas inlet; (b) an outer electrode having a generally concave inner surface and comprising: (i) an ion inlet operable to receive the ions from the ion source and a carrier gas from the gas inlet; and (ii) an ion outlet; and (c) an inner electrode having a conduit therethrough and having a generally convex outer surface that is disposed in a spaced-apart and facing arrangement relative to the inner surface of the outer electrode for defining an ion separation region therebetween; and a mass analyzer for mass analyzing ions transmitted by the FAIMS cell through the ion outlet, wherein the inner electrode is moveable between a first position and a second position, the first position facilitating movement of the ions through the ion separation region, the second position facilitating movement of the ions through the conduit. | 10-20-2011 |
20110260048 | Ion Transfer Tube for a Mass Spectrometer Having a Resistive Tube Member and a Conductive Tube Member - An ion transfer tube having an ion inlet and an ion outlet comprises: a first tube member comprising an electrically resistive material and having a first end comprising the ion inlet and a second end; a first electrode electrically coupled to the first tube member; a second tube member having a first end in leak-tight contact with the second end of the first tube member and a second end comprising the ion outlet; a second electrode electrically coupled to either the first tube member or the second tube member; and a heater thermally coupled to at least one of the tube members, wherein, in operation, an electrical potential difference applied between the electrodes produces an electric field within the first tube member that urges charged particles through the first tube member into the second tube member and the heater supplies heat to the charged particles within the ion transfer tube. | 10-27-2011 |
20120043460 | Ion Transfer Tube Having Single or Multiple Elongate Bore Segments and Mass Spectrometer System - An ion transfer tube for a mass spectrometer comprises a tube member having an inlet end and an outlet end; and at least one bore extending through the tube member from the inlet end to the outlet end, the at least one bore having a non-circular cross section. A method of forming an ion transfer tube comprises the steps of providing a tube member having a length and an internal bore, the internal bore having a wall of circular cross section; and etching or eroding portions of the tube member adjacent to the wall so as to form an enlarged bore having a non-circular cross section. | 02-23-2012 |
20120104248 | Combined Ion Source for Electrospray and Atmospheric Pressure Chemical Ionization - A ion source for a mass spectrometer comprises: a capillary having a nozzle for emitting a nebulized fluid sample; an electrode of the capillary; a high voltage power supply; a second electrode disposed within or configurable to be disposed within a path of the nebulized fluid sample; and at least one switch for selecting application of an electrical potential provided by the high voltage power supply to either or both of the capillary electrode or the second electrode, wherein the capillary and capillary electrode are configurable so as to ionize the nebulized fluid sample by electrospray ionization and the second electrode is configurable so as to ionize the nebulized sample by atmospheric pressure chemical ionization. | 05-03-2012 |
20120149125 | Ion Population Control for an Electrical Discharge Ionization Source - A method of providing reagent ions to a mass spectrometer comprises delivering a reagent species to a reagent ionization volume via a passageway at a flow rate. Using previously acquired information, an injection time duration is calculated for injecting reagent ions that are formed in the reagent ionization volume into a reaction region of the mass spectrometer. A determination is made as to whether the calculated injection time duration is within a specified range of injection time duration values. When it is determined that the calculated injection time duration falls outside of the specified range of injection time duration values, the flow rate at which the reagent species is delivered to the ionization volume is adjusted. | 06-14-2012 |
20120153141 | Ion Transfer Tube for a Mass Spectrometer System - An ion transfer tube for a mass spectrometer comprises a core member and a first jacket tube member at least partially enclosing the core member and providing one or more channels therethrough. A method of forming an ion transfer tube, comprises: providing a first jacket tube member having a length and an internal bore, the internal bore passing along the length and defining an interior surface of circular cross section; removing at least one portion of the first jacket tube member adjacent to the interior surface so as to form at least one groove, channel, slot, recess or embayment of or in the interior surface; and providing a core member within the bore of the jacket tube member such that remnant portions of the interior surface of circular cross section mate against portions of an exterior surface of the core member. | 06-21-2012 |
20120181424 | FAIMS Having a Displaceable Electrode for On/Off Operation - A system for analyzing ions comprises: an ion source; a FAIMS cell comprising: (a) a gas inlet; (h) an outer electrode having a generally concave inner surface and comprising: (i) an ion inlet operable to receive the ions from the ion source and a carrier gas from the gas inlet; and (ii) an ion outlet; and (c) an inner electrode having a conduit therethrough and having a generally convex outer surface disposed in a spaced-apart and facing arrangement relative to the inner surface of the outer electrode defining at least one annular on separation region therebetween; and a mass analyzer for mass analyzing ions transmitted by the FAIMS cell through the ion outlet, wherein the inner electrode is moveable between a first position and a second position, the first and second positions facilitating movement of the ions through the at least one annular ion separation region and the conduit, respectively. | 07-19-2012 |
20120248304 | Ion Guide with Improved Gas Dynamics and Combined Noise Reduction Device - A mass spectrometry system arrangement includes a curved ion guide, where the curve of the ion guide is positioned such that a portion of the ion optics are visible from at the ion guide entrance, e.g. line of sight or z-axis. There are four electrodes parallel with each other and the central curved axis. Each electrode is equally radially spaced from the curved central axis. For each cross section of the ion guide, the central curved axis being positioned at the origin, the curved electrodes being radially positioned at 45°, 135°, 225°, and 315°. Depending upon the system, a blocking device is positioned external to the ion guide but within the “line of sight” or positioned tangential to the rising section of the bent ion guide. | 10-04-2012 |
20130043385 | Apparatus and Method for a Multi-Stage Ion Transfer Tube Assembly for Use with Mass Spectrometry - An apparatus and method for introducing ions into a vacuum chamber of a mass spectrometer includes producing ions in an ionization chamber of an ion source. The ions are sampled into an intermediate pressure chamber via a first ion transfer tube. In particular, the pressure within the intermediate pressure chamber is maintained at a value that exceeds a maximum pressure for being sampled into the vacuum chamber of the mass spectrometer. Some of the ions are sampled from the intermediate pressure chamber via at least a second ion transfer tube, the at least a second ion transfer tube having an outlet end that is in communication with a low-pressure chamber. In particular, the pressure within the low-pressure chamber is maintained at a value that is less than a maximum pressure for being sampled into the vacuum chamber of the mass spectrometer. Some of the ions are sampled from the low-pressure chamber into the vacuum chamber of the mass spectrometer. | 02-21-2013 |
20130306860 | Control of Gas Flow in High Field Asymmetric Waveform Ion Mobility Spectrometry - A High Field Asymmetric Waveform ion Mobility Spectrometry (FAIMS) apparatus comprises (a) a first and a second gas inlet; a)) an expansion chamber receiving ions from an ion source and the first and second gas flows from the first and second gas inlets, respectively; (c) an outer electrode having a generally concave inner surface and comprising: (i) an ion inlet operable to receive, from the expansion chamber, the ions and a combined gas flow comprising portions of the first and second gas flows; and (ii) an ion outlet; and (d) an inner electrode having a generally convex outer surface that is disposed in a spaced-apart and facing arrangement relative to the inner surface of the outer electrode for defining an ion separation region therebetween, wherein the combined gas flow and a portion of the ions travel through the ion separation region from the ion inlet to the ion outlet. | 11-21-2013 |
20140158904 | Method for Transmitting Ions and Carrier Gas between Mutually Facing Curved Electrodes - A method for transmitting ions entrained in a flowing carrier gas into and through a gap defined by a pair of mutually facing curved electrodes comprises: inputting the ions and flowing gas into the gap through an ion inlet orifice of a first one of the pair of electrodes, the ion inlet orifice comprising an orifice wall, an orifice inlet end and an orifice outlet end, the orifice wall being smoothly convexly curved between the inlet end and the outlet end, wherein a width of the gap and a flow rate of the carrier gas through the ion inlet orifice and gap are such that the gas flow is laminar within the ion inlet orifice and gap. | 06-12-2014 |
20140264007 | Identifying the Occurrence and Location of Charging in the Ion Path of a Mass Spectrometer - A method is described for identifying the occurrence and location of charging of ion optic devices arranged along the ion path of a mass spectrometer. The method includes repeatedly performing a sequence of introducing a beam of discharge ions to a location on the ion path, and subsequently measuring the intensities of opposite-polarity sample ions delivered to a mass analyzer, with the discharge ions being delivered to a location further downstream in the ion path at each successive sequence. | 09-18-2014 |
20140291544 | Combined Ion Source for Electrospray and Atmospheric Pressure Chemical Ionization - An ion source for a mass spectrometer comprises: a capillary having a nozzle for emitting a nebulized fluid sample; an electrode of the capillary; a high voltage power supply electrically coupled to the electrode; a second electrode disposed within or configurable to be disposed within a path of the nebulized fluid sample, wherein the capillary and capillary electrode are configurable so as to ionize the nebulized fluid sample by electrospray ionization and the second electrode is configurable so as to ionize the nebulized sample by atmospheric pressure chemical ionization and wherein the second electrode is moveable between positions such that the second electrode is and is not disposed within the path of the nebulized fluid sample, respectively. | 10-02-2014 |