EP2498273A1 - Spectromètre de masse - Google Patents

Spectromètre de masse Download PDF

Info

Publication number
EP2498273A1
EP2498273A1 EP11405227A EP11405227A EP2498273A1 EP 2498273 A1 EP2498273 A1 EP 2498273A1 EP 11405227 A EP11405227 A EP 11405227A EP 11405227 A EP11405227 A EP 11405227A EP 2498273 A1 EP2498273 A1 EP 2498273A1
Authority
EP
European Patent Office
Prior art keywords
chamber
ions
interface
mass
mass spectrometer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP11405227A
Other languages
German (de)
English (en)
Inventor
Marc Gonin
Joel Kimmel
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Tofwerk AG
Aerodyne Research Inc
Original Assignee
Tofwerk AG
Aerodyne Research Inc
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Tofwerk AG, Aerodyne Research Inc filed Critical Tofwerk AG
Priority to EP11405227A priority Critical patent/EP2498273A1/fr
Publication of EP2498273A1 publication Critical patent/EP2498273A1/fr
Withdrawn legal-status Critical Current

Links

Images

Classifications

    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/10Ion sources; Ion guns
    • H01J49/14Ion sources; Ion guns using particle bombardment, e.g. ionisation chambers
    • H01J49/145Ion sources; Ion guns using particle bombardment, e.g. ionisation chambers using chemical ionisation
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/04Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components
    • H01J49/0468Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components with means for heating or cooling the sample
    • H01J49/0481Arrangements for introducing or extracting samples to be analysed, e.g. vacuum locks; Arrangements for external adjustment of electron- or ion-optical components with means for heating or cooling the sample with means for collisional cooling
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J49/00Particle spectrometers or separator tubes
    • H01J49/02Details
    • H01J49/06Electron- or ion-optical arrangements
    • H01J49/062Ion guides
    • H01J49/063Multipole ion guides, e.g. quadrupoles, hexapoles

Definitions

  • the invention relates to a mass spectrometer including a chemical ionization source comprising an ion molecule reaction region, a mass analyzer and an interface, coupling the chemical ionization source to the mass analyzer.
  • the invention further relates to a method for feeding ions from a chemical ionization source to a mass analyzer and to a method for using the mass spectrometer for the analysis of ions produced by chemical ionization and for the analysis of ambient ions.
  • MS mass spectrometer
  • mlQ mass-to-charge ratio
  • MS is a device for measuring the mass-to-charge ratio (mlQ) of ions. It can be used for chemical analysis. Mass spectrometers are commonly used for chemical analysis of gaseous, liquid, solid and plasma samples in a broad range of disciplines. All types of MS operate by subjecting charged, gas-phase molecules or atoms (ions) to electric and/or magnetic fields within a reduced pressure (vacuum) environment.
  • a MS generally records data for several chemical species corresponding to a broad range of mlQ. Data are often presented as a histogram of observed signal intensity as a function of mlQ, called a mass spectrum.
  • the mass of an ion is a function of the specific atom(s) comprising the ion.
  • mlQ 18.01 thomson (Th).
  • the mass spectrum of a sample can be used to deduce the identity of the molecules in the sample based on the observed mlQ value(s). For cases where the response of the MS can be appropriately calibrated, MS data can also quantify the concentration of specific molecules within the sample.
  • Mass spectrometer performance is often characterized by mass accuracy and mass resolution. The former quantifies how accurately a MS measures the mlQ of an ion, and the latter quantifies the ability of the MS to distinguish two ions of similar mlQ.
  • a TOFMS includes a TOF analyzer (TOF) that determines the mlQ of an ion by measuring the time required for that ion to travel a known distance after ions are accelerated to a known kinetic energy or by a known impulse. For any ion in a TOF the observed ion time-of-flight will be proportional to the square root of the ion's mlQ.
  • TOF TOF analyzer
  • Orthogonal extraction (0) TOFMS is a well-known implementation of TOFMS.
  • ions to be measured enter the TOF 12 along a primary axis 11 that is orthogonal to the TOF drift axis 14 on which ion velocities are to be measured.
  • ions moving on the primary axis are subjected to an impulse 13 that accelerates them along the drift axis towards a detector 15.
  • the data acquisition system 16 records the time of ion detection relative to the time at which the accelerating impulse occurred.
  • An ideal TOF analyzer refocuses all ions in time, independent on their initial conditions. This means an ion's flight time depends only on its mlQ and not on the ion's position and/or energy at the instance the extraction impulse is applied.
  • flight times are affected by initial ion velocities and initial positions as well as non-idealities in the applied electric fields, and differences in the fields experienced by ions owing to the spatial distribution of the primary beam (which is the collection of ions traveling along the primary axis).
  • OTOFMS performance is improved (made more ideal) by minimizing the spatial spread (width) of the primary beam on the axis parallel to drift and by minimizing the velocity of all ions in the primary beam along the drift axis, prior to acceleration. Minimization of each of these values reduces uncertainty in the drift velocity after acceleration, and therefore uncertainty in the determination of mlQ (mass accuracy and mass resolution).
  • a TOF must operate at a pressure low enough to ensure that ion trajectories are determined by electric fields and not perturbed by collisions with neutral background gas molecules. Such random collisions can slow ions, therefore broadening observed time-of-flight peaks and/or preventing ions from reaching the TOF detector, therefore reducing the sensitivity of the TOF analyzer.
  • the necessary pressure depends on the TOF analyzer geometry, but typical TOF analyzer pressures are below 1x10 -5 mbar.
  • Samples that do not originate in the gas phase must be converted to the gas phase (vaporization or desorption) before analysis.
  • the molecules and/or atoms of the sample must be given a charge (ionized) prior to analysis.
  • Vaporization (if necessary) and ionization of the sample can take place in devices separate from the mass analyzer. We refer to the volume within which ionization takes place and the associated hardware as the ionization source.
  • vaporization and ionization Numerous techniques exist for vaporization and ionization.
  • the two processes may occur in separate steps. For instance, a solid sample may be heated until it is vaporized, and then the resultant gas phase molecules may be ionized by an independent mechanism. Or, the two processes may be coupled and occur in a single step. For instance, a solid sample may be irradiated with an intense laser that causes both vaporization and ionization.
  • a gas-phase analyte molecule acquires a positive or negative charge through collision with a gas-phase reagent ion, R +/- , which can be described by the generic reaction: A + R + / - ⁇ P + / - + B
  • A is the neutral analyte molecule
  • P +/- is a charged product (molecule or non-covalent adduct) of the collisional interaction that includes atoms of A
  • B is a potential byproduct (e.g., molecule, adduct, or electron) of the interaction.
  • Cl methods have been described using a large number of different reagent ions, and ionization mechanisms vary between reagent ions. These mechanisms include, but are not limited to, proton transfer reactions, proton abstraction reactions, electron transfer reactions, and covalent and non-covalent adduct formation. Inter alia, Cl is broadly applied in atmospheric science for the analysis of trace gases.
  • the reagent ion Prior to the chemical ionization step, the reagent ion must be produced by ionization of a neutral reagent molecule.
  • Ionization of the reagent molecule is accomplished in a variety of ways, including, but not limited to, electron ionization of the neutral reagent, discharge ionization of the neutral reagent, or bombardment of the reagent gas with radioactive decay products, such as alpha or beta particles.
  • This reagent ionization may take place in the same volume as or in a separate volume from the volume where the analyte is ionized.
  • the ionization volume of the CI source contains reagent ions at a high pressure, typically between 0.001 and 1000 mbar.
  • IMR ion molecule reaction
  • the CI reaction product will form weakly bound (non-covalent) clusters with other species present in the IMR region, for instance water. In some cases, these weakly bound clusters are the desired product for analysis (i.e., P +/- ).
  • clustering undesirably spreads the production signal across multiple mlQ values, depending on the number of weakly bound complexes.
  • weak binding of neutral molecules, N may be represented as: A + R + / - ⁇ P + / - ⁇ N 1 + P + / - ⁇ N 2 + + P + / - ⁇ N x + B
  • CI implementations include a collisional declustering chamber (CDC), which ions pass through immediately after exiting the IMR region. In this region, non-covalent clusters are broken apart (declustered) in low-energy collisions with neutral, background gas molecules (G).
  • G neutral, background gas molecules
  • the pressure of the CDC and the voltages of the electrodes are adjusted to maximize ion transmission and optimize break-up of non-covalent complexes without causing fragmentation of covalent bonds within the product ion.
  • Certain CDC designs allow voltage and pressure conditions that do not cause the break-up of clusters, therefore enabling analysis based on reagent ion chemistry that forms either non-covalent or covalent product ions.
  • Air ions play a potentially important role in aerosol formation, and there is therefore great interest in characterizing the composition and reactive progression of ambient ions.
  • Air ions can cluster together to form ionic clusters. And, by attachment with trace neutral gases ambient ions or ionic clusters can evolve into aerosols, some of which are charged. We refer to the collection of air ions, ionic clusters, and charged aerosols as ambient ions.
  • Ambient ions can potentially be measured directly by mass spectrometry. See for instance: Junninen, H., Ehn, M., Petäjä, T., Luosujärvi, L., Kotiaho, T., Kostiainen, R., Rohner, U., Gonin, M., Fuhrer, K., Kulmala, M., and Worsnop, D. R.: A high-resolution mass spectrometer to measure atmospheric ion composition, Atmos. Meas. Tech., 3, 1039-1053 .
  • Ionic clusters are similar in nature to the weakly bound clusters sometimes formed in chemical ionization sources. As is the case for Cl, it would be desirable to analyze these ionic clusters with a mass spectrometer capable of both measuring intact clusters or alternatively breaking-up clusters and measuring the constituent ions.
  • the conditions (e.g., geometries and pressures) of ionization sources vary greatly, as do the energy distributions of ions produced by the various sources.
  • Each of these analyzer configurations has rigid physical design constraints (geometry and pressure) as well as specific energetic and spatial requirements for the population of ions to be analyzed.
  • Sensitive analysis requires that ions are efficiently transferred from the ion source to the mass analyzer.
  • the mechanism for coupling the ion source to the mass analyzer must reconcile any pressure differential between the ion source and the analyzer. And, it must appropriately tailor the beam to match the demands of the mass analyzer.
  • This disclosure describes an improved interface for the coupling of a CI ionization source to a mass analyzer.
  • Figure 2 outlines the major components of a CI-MS device, which includes in succession an optional vaporization region 21, the chemical ionization source 22, the interface region 23, and the mass analyzer 24.
  • Figure 3 shows a CL-TOFMS device, including the (optional) vaporization region 21, the chemical ionization source 22, the interface region 23 and the TOF mass analyzer 12 shown in Figure 1 , whereas the TOF drift axis 14 is essentially orthogonal to the primary axis 11 of the ions.
  • a well-known CI-MS design is depicted in more detail in Figure 4 .
  • a neutral gas flows (flow 31) through a region 32 containing an alpha-particle emitting substance, such as Polonium-210 ( 210 Po) or Americium-241 ( 241 Am) to generate reagent ions, which proceed into an ion molecule reaction region (IMR) 33 of a chamber 39.
  • IMR ion molecule reaction region
  • Neutral analyte molecules 34 enter the IMR through a separate, flow-rate-determining aperture 35 and are ionized in collisions with reagent ions.
  • the IMR region is held at a pressure between 10 and 1000 mbar, as determined by the reagent flow rate, analyte flow rate, and the effective speed of the vacuum pump 36 operating on the IMR region.
  • a combination of fluid dynamics and electric fields direct the generated ion population 37, which includes reagent ions, CI product ions, and charged, non-covalent complexes, from the IMR region through an aperture 38 into a collisional declustering chamber (CDC) 40.
  • CDC collisional declustering chamber
  • the IMR is a hollow chamber, having a body held at a constant DC voltage (see for example J. P. Kercher et al: Chlorine activation by N205: simultaneous, in situ detection of CIN02 and N205 by chemical ionization mass spectrometry, Atmos. Meas. Tech., 2, 193, 2009 ; P. Veres et al.: Development of negative-ion proton-transfer chemical-ionization mass spectrometry (NI-PT-CIMS) for the measurement of gas-phase organic acids in the atmosphere, Int. J. Mass Spec., 274, 2008, 48 ).
  • the IMR chamber has axial fields, which direct reagent and product ions towards the exit of the IMR.
  • a vacuum pump 41 attached to the CDC 40 holds this region at pressure lower than or equal to that of the IMR region, typically 1 to 5 mbar.
  • the CDC device is a series of ring electrodes 42 having tunable DC voltages. Ion transmission and dissociation of clusters are optimized by tuning the CDC electrode voltages, the entrance and exit aperture voltages, and the CDC pressure.
  • the de-clustered population of ions 44 passes from the CDC 40 through an exit aperture 43 into a differential vacuum stage 45, with pressure between the CDC and that of the mass analyzer.
  • This stage is typically pumped by a turbo molecular pump 46 and contains an RF-only multipole device 47 (e. g. quadrupole, octopole, or hexapole) or a RF ion funnel for ion focusing.
  • RF-only multipole device 47 e. g. quadrupole, octopole, or hexapole
  • RF ion funnel for ion focusing.
  • Such RF focusing devices are commonly used in MS interfaces to move ions across the transitional stages between regions of high and low pressure.
  • a collection of DC-voltage ion focusing lenses 48 may follow the RF focusing device, within the same vacuum stage.
  • Ions pass from the transitional vacuum stages of the interface into the mass analyzer 24 through a conductance-limiting, electrode aperture.
  • the mass analyzer is often a quadrupole, but may also be a TOF or any other type of mass analyzer.
  • the mass analyzer stage is typically pumped by a turbo molecular pump 49.
  • IMR-CDC-type design we differentiate this IMR-CDC-type design from the type described by, for instance, Hanson, 2003, in which reagent and analyte ions react in a high pressure drift tube, having strong axial electric fields that both direct ion motion and induce declustering of weakly bound clusters, such that no CDC region is necessary.
  • the ions passing into the CDC from the IMR region have varied energy and trajectory, determined primarily by the fluid dynamics of the expansion into the lower pressure region.
  • the electrodes of the CDC are intended to direct ion trajectories through the CDC exit aperture and into the next stage of the interface. Those ions that cannot be appropriately focused go undetected.
  • the motion induced by the fields of the DC ring electrodes 41 is a function of both the initial trajectory and energy of the ion.
  • the motion induced by the fields of the DC ring electrodes 41 is a function of both the initial trajectory and energy of the ion.
  • the interface comprises
  • a method for feeding ions from a chemical ionization source to a mass analyzer comprises the steps of:
  • the ions do not have to be transmitted from the interface vacuum chamber directly into the mass analyzer but there may be further chambers arranged in between the interface vacuum chamber and the mass analyzer, i. e. the device according to the invention comprises the first chamber, the interface vacuum chamber and optionally one or more chambers arranged between the interface vacuum chamber and the mass analyzer.
  • the disclosed interface comprises a RF ion focusing device in the form of a radio frequency (RF) focusing device (RFFD), rather than the more common set of DC ring electrodes, in the CDC region.
  • RF radio frequency
  • Typical frequencies to be applied to electrodes of the RFFD are in the range of about 0.1 - 10 MHz.
  • the disclosed interface differs significantly from hardware described in US 6,987,264 (Analytica of Branford, Inc.) and RE 40,632 (Thermo Finnigan LLC) in both purpose and design.
  • the interface according to the invention is suitable for use with a broader range of IMRs, most notably, IMRs operated at pressures much below atmospheric pressure.
  • the interface according to the invention does not include a capillary for transfer of ions out of the IMR, and in the interface according to the invention, the pressure stage immediately following the IMR contains a RFFD. Whereas, in the mentioned other designs, the first stage does not contain an RFFD.
  • Ions enter the first chamber with a broad range of energies, originating from expansion into the chamber.
  • the RF-fields constrain ion motion near the central axis of the RFFD, and collisions with neutral, background gas molecules effectively dissipate kinetic energy originating from the expansion.
  • the RFFD improves ion transmission into the interface stage following the first chamber relative to the more commonly DC ring electrode assembly. Further, the RFFD more efficiently dissipates ion kinetic energy originating from expansion into the first chamber, improving achieved mass resolving power and mass accuracy in particular for applications where a CI source is a component of an OTOFMS.
  • the sensitivity of a mass spectrometer comprising the inventive interface may be increased independent of the type of mass analyzer used.
  • the mass analyzer is a TOFMS
  • the inventive combination of the first chamber and the interface vacuum chamber allows for a more efficient "cooling" of the ion beam and therefore enables higher mass resolving power in the mass analyzer.
  • collisional declustering happens in the first chamber or the region near the transition between the first and second chamber if a clustered sample is present and if the pressure as well as voltages are chosen in an appropriate range.
  • declustering may be desired or not. Any way, the construction of the inventive interface allows for declustering by choosing suitable parameters.
  • the RFFD is differentiated from RF-only multipole devices commonly used in CI-MS (See, for example, octopole ion guides in Kercher 2009, Veres 2008 and J. D. Crounse et al.: Measurement of gas-phase hydroperoxides by chemical ionization mass spectrometry, Anal Chem 78 (19): 6726 (2006 )), by the combination of facts that (i) it operates in the region immediately following the IMR of the CI source (ii) it operates at pressure greater than 0.01 mbar, and (iii) at least one interface vacuum chamber exists between the first chamber, which contains the RFFD, and the mass analyzer.
  • Possible applications of the interface according to the invention encompass the use for analyses where the sample to be analyzed originates in the gas, liquid, or solid phase.
  • the interface may be used in atmospheric science, e. g. for the following applications:
  • the radio frequency focusing device comprises an ion funnel constituted by a series of ring electrodes to which RF voltages are applied.
  • the ring electrodes may all have the same diameter or the diameter may decrease in the focusing direction.
  • the inner diameter of the funnel may be constant or varied across the ion drift axis.
  • the spacing between adjacent ring electrodes may be constant or varied.
  • the radio frequency focusing device comprises a tube having a resistive structure to which RF voltages are applied.
  • Corresponding tubes are described in European patent application No. 07 405 077.4 of 08 March 2007 of the same applicant.
  • the tube may be made from a resistive material or from an insulating material (e. g. glass) having a resistive coating.
  • the cross-section of the tube may be circular but also e. g. triangular, rectangular or of another shape.
  • an interior of the tube is separated into at least two chambers by the gas conductance limiting aperture or a plurality of gas conductance limiting apertures.
  • Electrodes for both the first chamber as well as the interface vacuum chamber (and possibly for further chambers) may be realised as resistive structures. More than two chambers may be present within the tube, whereas further chambers are divided in particular by further gas conductance limiting apertures.
  • the radio frequency focusing device is a multipole defined by a number of electrodes, in particular a quadrupole, defined by 4 electrodes.
  • multipoles of other orders such as hexapoles or octopoles are also possible.
  • the electrodes of the multipole can have any cross section.
  • the electrodes of the multipole are solid rods with circular cross section.
  • the electrodes of the multipole can be continuous, or discontinuous along the primary ion axis. In the first case, the potential at all points along an electrode will be equal. In the second case, i.e. when the electrodes of the multipole are segmented along the primary ion axis, the potential of the individual segments can be separately adjusted.
  • One such embodiment may use a device similar to the molecule ion reactor described by A.
  • the orientation of the electrodes of the multipole may be parallel to a primary ion axis.
  • the orientation of the electrodes of the multipole is angled such that an inscribed diameter at an entrance of the multipole is different from an inscribed diameter at an exit of the multipole.
  • the inscribed diameter at the entrance of the multipole is greater than the inscribed diameter at the exit.
  • the inscribed diameter at the entrance is smaller than that at the exit.
  • the radio frequency focusing device creates in addition to the RF field(s) at least one DC field oriented along a primary ion axis.
  • the entrance aperture of the first chamber has an independently adjustable DC voltage.
  • the exit aperture of the first chamber has an independently adjustable DC voltage.
  • an adjustable DC bias voltage may be applied to those electrodes.
  • separate adjustable DC bias voltages can be applied to each of the electrodes.
  • the combination of RF and DC voltages can be used to induce dissociation of non-covalent complexes originating from the IMR region or they may be chosen in a combination that does not induce dissociation of non-covalent complexes originating from the IMR region.
  • At least one of said at least one interface vacuum chamber includes an RF-only multipole.
  • the main task of this multipole is ion focusing. If the pressure of the stage is high enough, low energy collisions between ions and neutral background gas in the multipole or trap can dampen the energy distribution of the beam, such that ion trajectories are primarily determined by the forces of the ion optics, and total transmission through the stage is increased.
  • interface vacuum chambers not including RF electrodes but solely DC electrodes (e. g. usual ion lenses) or even no electrodes at all in cases where the ions enter the chamber in a focused state and with sufficient momentum and where the chamber is rather short and has a relatively large exit aperture.
  • DC electrodes e. g. usual ion lenses
  • At least one of said at least one interface vacuum chamber includes a mass filtering device that selectively transmits ions having specific values of m/Q.
  • Suitable filters comprise e. g. multi poles such as quadrupole mass filters.
  • a device follows the mass filtering device that is capable of fragmenting the transmitted ions, in order to enable MS/MS analysis.
  • the interface comprises a further device capable of fragmenting incoming ions.
  • This further device is arranged downstream of the chamber including the mass filtering device. Fragmentation may be induced by choosing the RF and DC voltages applied to respective electrodes in such a way that covalent bonds originating from the IMR region are broken up. This enables MS analysis based on fragments.
  • the inventive interface may be used as an interface or first interface region following the ionization volume in any Cl implementation, especially when the pressure in the ion molecule reaction region (IMR) is 1 mbar or more.
  • IMR ion molecule reaction region
  • the IMR volume is at atmospheric pressure or higher and the CDC is the first reduced pressure stage of the vacuum system.
  • the IMR is pumped by a vacuum pump to achieve a pressure below atmospheric pressure.
  • the IMR is a constrained three-dimensional volume having defined physical boundaries.
  • the IMR volume includes DC electric fields to direct ions into the first chamber of the interface. In some implementations at atmospheric or reduced pressure, the IMR volume includes RF electric fields to direct ions into the first chamber. Other implementations feature DC as well as RF electric fields.
  • the IMR is a flow tube, with no controlled electric fields along the primary beam axis.
  • the IMR body may be constructed from a tube with a resistive structure similar to the radio frequency focusing device mentioned above. In some such implementations, the entire body is held an equal voltage, in other implementations, RF voltages are applied to the resistive structure. Furthermore, DC voltages may be applied in order to generate an axial drift field.
  • the inventive interface is especially suited for mass spectrometers having a time-of-flight mass analyzer.
  • the inventive interface allows for reducing the pressure to such values that ion trajectories within the TOFMS are determined by electric fields and not perturbed by collisions with neutral background gas molecules. Such random collisions can slow ions, therefore broadening observed time-of-flight peaks and/or preventing ions from reaching the TOF detector, therefore reducing the sensitivity of the TOF analyzer.
  • the necessary pressure depends on the TOF analyzer geometry, but typical TOF analyzer pressures are below 1 . 10 -5 mbar.
  • the time-of-flight mass spectrometer is installed in an orthogonal extraction configuration.
  • the spatial spread (width) of the primary beam on the axis parallel to drift as well as the velocity of all ions in the primary beam along the drift axis, prior to acceleration are minimized. Minimization of each of these values reduces uncertainty in the drift velocity after acceleration, and therefore uncertainty in the determination of mlQ (mass accuracy and mass resolution).
  • mass analyzers e. g. a quadrupole mass filter.
  • a single interface and mass analyzer arranged downstream of the interface may be used for the analysis of ions produced by chemical ionization and for the analysis of ambient ions.
  • the chemical ionization source is replaced by an inlet for feeding ambient air, i. e. the interface is used as an interface or first interface region following the inlet for feeding ambient air.
  • the inlet that replaces the chemical ionization source is a conductance limiting "pin hole" aperture, which serves as the boundary between ambient air and the vacuum chamber containing the RFFD.
  • the inlet that replaces the chemical ionization source is a conductance limiting tube, which extends from ambient air into the vacuum chamber containing the RFFD.
  • the inlet that replaces the chemical ionization source may include a vacuum chamber held at a pressure less than or equal to ambient pressure and greater than or equal to the pressure of the first chamber. Sampled air traverses this chamber before entering the first chamber containing the RFFD.
  • the entrance aperture of this vacuum chamber can be a pin hole or a tube.
  • the interface and the mass analyzer arranged downstream of the interface may be used for the analysis of ambient ions. This allows for alternately using the mass spectrometer to analyze the two kinds of ions, whereas any duration can be spent in each analysis configuration.
  • such a method comprises the following steps:
  • the IMR of the chemical ionization source may remain installed, whereas when analyzing ambient ions the volume of the IMR is not used for chemical ionization. Rather, ambient air is sampled directly into the IMR through an aperture and the chemical constitutions of the air traverse the volume of the IMR without being exposed to a reagent ion. Constituents of the air then pass into the RFFD.
  • the IMR volume is held at atmospheric pressure. In other embodiments, the IMR is held at a pressure less than atmospheric pressure and greater than or equal to the pressure of the chamber containing the RFFD.
  • the IMR has no electric fields, such that motion of ambient ions is determined primarily by gas flow. In other embodiments, the IMR has electric fields that guide ambient ions toward the RFFD.
  • the chemical ionization source is removed when analyzing ambient ions, or the inlet for ambient ions is coupled to an aperture of the first chamber separate from the aperture accepting ions from the chemical ionization source.
  • the conditions of the RFFD are adjusted to maximize transmission of intact clusters.
  • the conditions of the RFFD are adjusted to induce break-up of clusters, so that the mass spectrometer analyzes constituents of the clusters.
  • FIG. 5 is a schematic representation of an embodiment of the inventive mass spectrometer comprising an RFFD.
  • a neutral gas flows (flow 31) through a region 32 containing an alpha-particle emitting substance, such as Polonium-210 ( 210 Po) or Americium-241 ( 241 Am) to generate reagent ions, which proceed into an ion molecule reaction region (IMR) 33 of a chamber 39.
  • IMR ion molecule reaction region
  • Neutral analyte molecules 34 enter the IMR through a separate, flow-rate-determining aperture 35 and are ionized in collisions with reagent ions.
  • the IMR region is held at a pressure between 10 and 100 mbar, as determined by the reagent flow rate, analyte flow rate, and the effective speed of the vacuum pump 36 operating on the IMR region.
  • a combination of fluid dynamics and electric fields direct the generated ion population 37, which includes reagent ions, CI product ions, and charged, non-covalent complexes, from the IMR region through an aperture 38 into a further chamber 50.
  • the IMR is a hollow chamber, having a body held at a constant DC voltage (see for example Kercher 2009; Veres 2008).
  • the IMR chamber has axial fields, which direct reagent and product ions towards the exit of the IMR. See for example Zheng, 2010; US 7'375'317 B2 .
  • a vacuum pump 51 attached to the further chamber 50 holds this region at pressure lower than or equal to that of the IMR region, typically 1 to 5 mbar.
  • an RFFD 52 is arranged which is described in more detail below, in connection with Figure 6 . Ion transmission and dissociation of clusters are optimized by tuning the electrode voltages, the entrance and exit aperture voltages, and the pressure within chamber 50.
  • the cooled and/or de-clustered population of ions 54 passes from the chamber 50 through an exit aperture 53 into a differential vacuum stage 45, held at a pressure in between the pressure in chamber 50 and that within the mass analyzer 24.
  • This stage is pumped by a turbo molecular pump 46 and contains an RF-only multipole device 47 (quadrupole, octopole, or hexapole) or a RF ion funnel for ion focusing.
  • RF-only multipole device 47 quadrupole, octopole, or hexapole
  • RF ion funnel for ion focusing.
  • Such RF focusing devices are commonly used in MS interfaces to move ions across the transitional stages between regions of high and low pressure.
  • a collection of DC-voltage ion focusing lenses 48 may follow the RF focusing device, within the same vacuum stage.
  • Ions pass from the transitional vacuum stages of the interface into the mass analyzer 24 through a conductance-limiting, electrode aperture.
  • the mass analyzer is often a quadrupole, but may also be a TOF or ion trap.
  • the mass analyzer stage is pumped by another turbo molecular pump 49.
  • Figure 6a shows a side view and Figure 6b shows a cross sectional view of the preferred embodiment of an RFFD, which is an RF-only quadrupole having parallel, segmented electrodes.
  • the RFFD 61 comprises four parallel multipole electrodes (rods) which are aligned in symmetric manner, such when viewed along the primary ion axis ( Fig 6b ), the rods lie on the corner of a square. Oscillating RF voltages are applied to the electrodes, in a manner that is known as such for quadrupole devices, with rods on opposite corners of the square being electrically connected, and with the two pairs of connected rods receiving RF signals that are exactly out of phase.
  • Each rod 63, 67 is broken into four segments along the primary ion axis. It is to be noted that the number of segments may be less or more than four.
  • DC bias voltages are applied to each rod segment 63, 67, in addition to the RF voltage.
  • the DC voltage of each segment is determined by a DC voltage 64a applied to the front segment, a DC voltage 64b applied to the back segment, and a series of resistors 65 located between successive segments.
  • Each rod 63, 67 has a dedicated collection of resistors 65 and capacitors 66 connected in parallel with the resistors 65.
  • Each segment has a dedicated DC contact 64a 64b not directly connected to the DC lead of any other segment. For instance, there are 4 instances of the front electrode contact 64a shown in Figure 6 , each dedicated to the front segment of one of the 4 rods. Segments in equivalent positions on each rod have the same DC voltage applied.
  • the RF voltages applied to the rods 63, 67 are about 500 V peak-to-peak, used frequencies are in the range of 0.1 - 10 MHz.
  • a first DC ring electrode 62 is positioned before the quadrupole and a second DC ring electrode 70 is positioned after the quadrupole, whereas the centers of the central openings of the DC ring electrodes 62, 70 and the center defined by the quadrupole electrodes 63, 67 lie on a common line.
  • the potential difference between the DC ring electrodes 62, 70 is about 35 V.
  • Figure 7 shows a second embodiment of the inventive mass spectrometer, including a CI source, RFFD, an interface chamber containing an RF-only quadrupole, an interface chamber containing DC focusing optics, and TOF mass analyzer in an orthogonal configuration.
  • a neutral gas flows (flow 31) through a region 32 containing an alpha-particle emitting substance, such as Polonium-210 ( 210 Po) or Americium-241 ( 241 Am) to generate reagent ions, which proceed into an ion molecule reaction region (IMR) 33 of a chamber 39.
  • IMR ion molecule reaction region
  • Neutral analyte molecules 34 enter the IMR through a separate, flow-rate-determining aperture 35 and are ionized in collisions with reagent ions.
  • the IMR region is held at a pressure of about 80 mbar, as determined by the reagent flow rate, analyte flow rate, and the effective speed of the scroll vacuum pump 36 operating on the IMR region.
  • the pumping speed is about 1.5l/s.
  • the axial length of chamber 39 is about 10 cm.
  • a combination of fluid dynamics and electric fields direct the generated ion population 37, which includes reagent ions, Cl product ions, and charged, non-covalent complexes, from the IMR region through a nozzle-shaped aperture 38 with a final diameter of 0.5 mm and with adjustable DC voltage into a further chamber 50.
  • the IMR is a hollow chamber, having a body held at a constant DC voltage (see for example Kercher 2009; Veres 2008).
  • the IMR chamber has axial fields, which direct reagent and product ions towards the exit of the IMR. See for example Zheng, 2010; US 7,375,317 B2 (The Texas A&M University System).
  • a further scroll vacuum pump 51 attached to the chamber 50 has a pumping speed of about 5 l/s and holds this region at a pressure of about 2 mbar.
  • the RFFD 61 as shown in Figure 6 is arranged within the chamber 50.
  • the length of the chamber 50 is about 3 cm. Ion transmission and dissociation of clusters are optimized by tuning the electrode voltages, the entrance and exit aperture voltages, and the pressure within chamber 50.
  • the cooled and/or de-clustered population of ions 54 passes from the chamber 50 through an exit aperture 53 having a diameter of about 1.0 mm with adjustable DC voltage into a differential vacuum stage 45, with a pressure of about 0.015 mbar.
  • This stage is pumped by a turbo molecular pump 46 having a pumping speed of 20 I/s and contains an RF-only quadrupole 47.
  • the RF voltages applied to the quadrupole rods are about 600 V peak-to-peak, used frequencies are in the range of 0.1 - 10 MHz.
  • the length of the stage 45 is about 11 cm. If the pressure of the stage is high enough, low energy collisions between ions and neutral background gas in the multipole or trap can dampen the energy distribution of the beam, such that ion trajectories are primarily determined by the forces of the ion optics, and total transmission through the stage is increased.
  • the ions pass into a further interface chamber 72, held at a pressure of about 3.5 ⁇ 10 -5 mbar by a further turbo molecular pump 73 having a pumping speed of about 1551/s.
  • the further interface chamber 72 comprises a set of DC-voltage focusing lenses 48. Its length is about 3 cm.
  • ions pass into the TOF mass analyzer, installed and operated in an orthogonal extraction configuration.
  • the main chamber of the mass analyzer is connected with a further turbo molecular pump providing a pumping speed of about 200 l/s.
  • Figure 8 shows the essential regions of a mass spectrometer configured for analysis of ambient ions.
  • the device includes in succession an ambient ion interface 81, an interface region 23 and the mass analyzer 24.
  • FIG 9 is a schematic representation of an embodiment of a mass spectrometer configured for analysis of ambient ions, where the IMR of the CI source remains installed but chemical ionization is not active.
  • the assembly is identical to that shown in Figure 7 above.
  • ambient air 91 including ambient ions enters the chamber 39 through the flow-rate-determining aperture 35.
  • the ion molecule reaction region (IMR) of the chamber 39 is inactive, i. e. no substance flows from region 32 into chamber 39 and ions already present in ambient air will finally be analyzed by the time-of-flight mass analyzer (TOF) 12.
  • TOF time-of-flight mass analyzer
  • FIG 10 is a schematic representation of a further embodiment of a mass spectrometer configured for analysis of ambient ions having an inlet including a pumping stage between ambient air and the first interface chamber.
  • the ambient ion interface 81 (inlet) for the ambient air 91 including ambient ions comprises a vacuum chamber 1002, evacuated by a pump 1003 and having a conductance limiting entrance aperture 1001 for feeding the ambient air 91 and a conductance limiting exit aperture 1004 leading into the collisional declustering chamber (CDC) 40.
  • the subsequent stages of the interface exactly correspond to those described above in connection with the embodiment shown in Figure 7 .
  • FIG 11 is a schematic representation of a further embodiment of a mass spectrometer configured for analysis of ambient ions having an ambient ion interface 81 (inlet) consisting of a conductance limiting tube 1101 extending from ambient air directly into the first interface chamber, i. e. the collisional declustering chamber (CDC) 40.
  • the subsequent stages of the interface exactly correspond to those described above in connection with the embodiment shown in Figure 7 .
  • the invention is not limited to the embodiments discussed above. Particularly, the number of additional vacuum stages as well as the ion optical elements disposed within these chambers may be different.
  • the operation parameters such as pressures, voltages, frequencies, etc. are related to the particular embodiments and may be chosen differently with other embodiments of the mass spectrometer or in connection with the analysis of different kinds of analyte molecules.
  • an “entrance aperture” may as well be the “exit aperture” of the preceding chamber, similarly, an “exit aperture” may be constituted by the "entrance” aperture of the following chamber.
  • the invention provides a mass spectrometer that allows for improved mass resolution, sensitivity and accuracy in the mass analyzer.

Landscapes

  • Chemical & Material Sciences (AREA)
  • Analytical Chemistry (AREA)
  • Physics & Mathematics (AREA)
  • Engineering & Computer Science (AREA)
  • Plasma & Fusion (AREA)
  • Other Investigation Or Analysis Of Materials By Electrical Means (AREA)
EP11405227A 2011-03-07 2011-03-07 Spectromètre de masse Withdrawn EP2498273A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
EP11405227A EP2498273A1 (fr) 2011-03-07 2011-03-07 Spectromètre de masse

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
EP11405227A EP2498273A1 (fr) 2011-03-07 2011-03-07 Spectromètre de masse

Publications (1)

Publication Number Publication Date
EP2498273A1 true EP2498273A1 (fr) 2012-09-12

Family

ID=44315113

Family Applications (1)

Application Number Title Priority Date Filing Date
EP11405227A Withdrawn EP2498273A1 (fr) 2011-03-07 2011-03-07 Spectromètre de masse

Country Status (1)

Country Link
EP (1) EP2498273A1 (fr)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108695135A (zh) * 2017-04-10 2018-10-23 托夫沃克股份公司 用于从气溶胶颗粒生成元素离子的离子源和方法
CN109192648A (zh) * 2018-08-09 2019-01-11 金华职业技术学院 一种自由基光产物测试方法
EP3629364A1 (fr) * 2018-09-28 2020-04-01 Ionicon Analytik Gesellschaft m.b.H. Dispositif imr-ms
CN114361004A (zh) * 2021-12-23 2022-04-15 上海裕达实业有限公司 检测多组分样品质谱装置、环境检测装置及食品检测装置
GB2613439A (en) * 2021-10-15 2023-06-07 Thermo Fisher Scient Bremen Gmbh Ion Transport between Ion Optical Devices at different gas pressures

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6987264B1 (en) 1998-01-23 2006-01-17 Analytica Of Branford, Inc. Mass spectrometry with multipole ion guides
US7034292B1 (en) * 2002-05-31 2006-04-25 Analytica Of Branford, Inc. Mass spectrometry with segmented RF multiple ion guides in various pressure regions
US7375317B2 (en) 2004-08-02 2008-05-20 The Texas A&M University System Ion drift-chemical ionization mass spectrometry
USRE40632E1 (en) 1999-12-03 2009-02-03 Thermo Finnigan Llc. Mass spectrometer system including a double ion guide interface and method of operation

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6987264B1 (en) 1998-01-23 2006-01-17 Analytica Of Branford, Inc. Mass spectrometry with multipole ion guides
USRE40632E1 (en) 1999-12-03 2009-02-03 Thermo Finnigan Llc. Mass spectrometer system including a double ion guide interface and method of operation
US7034292B1 (en) * 2002-05-31 2006-04-25 Analytica Of Branford, Inc. Mass spectrometry with segmented RF multiple ion guides in various pressure regions
US7375317B2 (en) 2004-08-02 2008-05-20 The Texas A&M University System Ion drift-chemical ionization mass spectrometry

Non-Patent Citations (9)

* Cited by examiner, † Cited by third party
Title
A. DODONOV ET AL.: "New Technique for Decomposition of Selected Ions in Molecule Ion Reactor Coupled with Ortho-Time-of-flight Mass Spectrometry", RAPID. COMMUN. MASS SPECTROM, vol. 11, 1997, pages 1649, XP002101222, DOI: doi:10.1002/(SICI)1097-0231(19971015)11:15<1649::AID-RCM67>3.0.CO;2-T
D. HANSON ET AL.: "Proton transfer reaction mass spectrometry at high drift tube pressure", INT. J. MASS SPECTROMETRY, vol. 223-224, 2003, pages 507, XP004397021, DOI: doi:10.1016/S1387-3806(02)00924-7
H. JUNNINEN ET AL: "A high-resolution mass spectrometer to measure atmospheric ion composition", ATMOSPHERIC MEASUREMENT TECHNIQUES, vol. 3, 17 August 2010 (2010-08-17), pages 1039 - 1053, XP055004075, DOI: 10.5194/amt-3-1039-2010 *
J. D. CROUNSE ET AL.: "Measurement of gas-phase hydroperoxides by chemical ionization mass spectrometry", ANAL CHEM, vol. 78, no. 19, 2006, pages 6726
J. P. KERCHER ET AL.: "Chlorine activation by N205: simultaneous, in situ detection of CIN02 and N205 by chemical ionization mass spectrometry", ATMOS. MEAS. TECH., vol. 2, 2009, pages 193
J. ZHENG ET AL.: "Atmospheric Pressure-Ion Drift Chemical Ionization Mass Spectrometry for Detection of Trace Gas Species", ANAL. CHEM., vol. 82, no. 17, 2010, pages 7302
JUNNINEN, H., EHN, M., PETAJA, T., LUOSUJARVI, L., KOTIAHO, T., KOSTIAINEN, R., ROHNER, U., GONIN, M., FUHRER, K., KULMALA, M.: "A high-resolution mass spectrometer to measure atmospheric ion composition", ATMOS. MEAS. TECH., vol. 3, pages 1039 - 1053, XP055004075, DOI: doi:10.5194/amt-3-1039-2010
P. VERES ET AL.: "Development of negative-ion proton-transfer chemical- ionization mass spectrometry (NI-PT-CIMS) for the measurement of gas-phase organic acids in the atmosphere", INT. J. MASS SPEC., vol. 274, 2008, pages 48, XP022715340, DOI: doi:10.1016/j.ijms.2008.04.032
W. LINDINGER ET AL.: "On-line monitoring of volatile organic compounds at pptv levels by means of Proton-Transfer-Reaction Mass Spectrometry (PTR-MS) Medical applications, food control and environmental research", INT. J. MASS SPECTROMETRY AND ION PROCESSES, vol. 173, 1998, pages 191, XP004111355, DOI: doi:10.1016/S0168-1176(97)00281-4

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN108695135A (zh) * 2017-04-10 2018-10-23 托夫沃克股份公司 用于从气溶胶颗粒生成元素离子的离子源和方法
CN109192648A (zh) * 2018-08-09 2019-01-11 金华职业技术学院 一种自由基光产物测试方法
CN109192648B (zh) * 2018-08-09 2023-09-15 金华职业技术学院 一种自由基光产物测试方法
EP3629364A1 (fr) * 2018-09-28 2020-04-01 Ionicon Analytik Gesellschaft m.b.H. Dispositif imr-ms
WO2020065013A1 (fr) * 2018-09-28 2020-04-02 Ionicon Analytik Gesellschaft M.B.H Dispositif imr-ms
US11282692B2 (en) 2018-09-28 2022-03-22 Ionicon Analytik Gesellschaft M.B.H. IMR-MS device
GB2613439A (en) * 2021-10-15 2023-06-07 Thermo Fisher Scient Bremen Gmbh Ion Transport between Ion Optical Devices at different gas pressures
CN114361004A (zh) * 2021-12-23 2022-04-15 上海裕达实业有限公司 检测多组分样品质谱装置、环境检测装置及食品检测装置

Similar Documents

Publication Publication Date Title
US6906322B2 (en) Charged particle source with droplet control for mass spectrometry
US8003934B2 (en) Methods and apparatus for ion sources, ion control and ion measurement for macromolecules
US6649907B2 (en) Charge reduction electrospray ionization ion source
US8288716B2 (en) Real-time airborne particle analyzer
US20090095901A1 (en) Chemical ionization reaction or proton transfer reaction mass spectrometry with a quadrupole mass spectrometer
JP2017535040A (ja) 不要イオンを抑制するシステム及び方法
EP1568063A2 (fr) Processus pour concevoir des separateurs de masse et des pieges a ions, procedes pour produire des separateurs de masse et des pieges a ions, spectrometres de masse, pieges a ions et procedes pour analyser des echantillons
March et al. Practical aspects of trapped ion mass spectrometry, volume IV: Theory and instrumentation
US20090095902A1 (en) Chemical ionization reaction or proton transfer reaction mass spectrometry with a time-of-flight mass spectrometer
US11056327B2 (en) Inorganic and organic mass spectrometry systems and methods of using them
EP2498273A1 (fr) Spectromètre de masse
CN108695135A (zh) 用于从气溶胶颗粒生成元素离子的离子源和方法
US7148472B2 (en) Aerosol mass spectrometer for operation in a high-duty mode and method of mass-spectrometry
CN112424902B (zh) 电离源以及使用电离源的系统和方法
Große-Kreul Mass spectrometry of ions from atmospheric pressure plasmas
Jjunju In-Situ Mass Spectrometry Analysis Under Ambient Conditions
Roman et al. Solid Analysis by Mass Spectrometry.
Balcerzak Mass Spectrometric Detectors for Environmental Studies
CN117612925A (zh) 一种复合串联质谱仪
Course How to Select an ICP Mass Spectrometer: The Most Important Analytical Considerations
Bruno et al. Mass Spectrometry I: Principles and Instrumentation
Charipar A discontinuous atmospheric pressure interface for mass spectrometry
Collier Development of a thermal desorption chemical ionization mobility mass spectrometer for the speciation of ultrafine aerosols

Legal Events

Date Code Title Description
PUAI Public reference made under article 153(3) epc to a published international application that has entered the european phase

Free format text: ORIGINAL CODE: 0009012

AK Designated contracting states

Kind code of ref document: A1

Designated state(s): AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR

AX Request for extension of the european patent

Extension state: BA ME

STAA Information on the status of an ep patent application or granted ep patent

Free format text: STATUS: THE APPLICATION IS DEEMED TO BE WITHDRAWN

18D Application deemed to be withdrawn

Effective date: 20130313