Patent Description:
In mass spectrometry, sample molecules are converted into ions using an ion source, in an ionization step, and then detected by a mass analyzer, in mass separation and detection steps. For most atmospheric pressure ion sources, ions pass through an inlet aperture prior to entering an ion guide in a first vacuum chamber. The ion guide transports and focuses ions from the ion source into a subsequent vacuum chamber, and a radio frequency signal can be applied to the ion guide to provide radial focusing of ions within the ion guide. However, during transportation of the ions through the ion guide, ion losses can occur. Therefore, it is desirable to increase transport efficiency of the ions along the ion guide and prevent the loss of ions during transportation to attain high sensitivity.

<CIT> discloses an ion source and an ion guide chamber.

<CIT> discloses an ion guide arrangement.

In view of the foregoing, the applicant's teachings provide a mass spectrometer apparatus comprising an ion source for generating ions from a sample in a high-pressure region. A first vacuum chamber has an inlet aperture for passing the ions from the high-pressure region into the first vacuum chamber and an exit aperture for passing ions from the first vacuum chamber. The apparatus also comprises at least one ion guide. The at least one ion guide is positioned in the chamber between the inlet aperture and an exit aperture so that when an RF voltage, provided by an RF power supply, is applied to the at least one ion guide, the ions are radially confined within the internal volume of the at least one ion guide and focused and directed to the exit aperture. The at least one ion guide has an entrance end and an exit end. In various embodiments, the at least one ion guide can comprise a predetermined cross section and length defining an internal volume. In various embodiments, the predetermined cross section of the at least one ion guide can form an inscribed circle. In various embodiments, the entrance end comprises an opening with an inscribed circle that is larger than the inscribed circle that comprises the exit end. In various embodiments, the inscribed circle at the entrance end has a diameter of between about <NUM> and about <NUM>. In various embodiments, the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various embodiments, the entrance end of the ion guide has a diameter of between about <NUM> and about <NUM>. In various embodiments, the inscribed circle at the exit end has a diameter of between about <NUM> and about <NUM>. In various embodiments, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>. The at least one ion guide comprises a plurality of electrodes arranged around a central axis defining an ion channel. Each of the plurality of electrodes is tapered, and a planar surface of each of the plurality of tapered electrodes faces the interior of the at least one ion guide, the surface gradually being narrowed and tilting inward to provide a smaller inscribed radius at the exit. In various embodiments, the surface of each of the plurality of tapered electrodes can be any suitable shape. In various embodiments, the surface can be curved. In various embodiments, the surface can be convex or concave. A power supply can provide an RF voltage to the at least one ion guide.

In various embodiments, there is a greater resistance to the radial flow of gas from the interior to the exterior of the ion guide at the exit end than at the entrance end. The spacing between adjacent electrodes is essentially constant over the length of the ion guide. In various embodiments, the spacing between adjacent electrodes is between about <NUM> to about <NUM>. Each of the plurality of electrodes gradually becomes thicker towards the narrower exit end of the ion guide, the thickness being in the direction approximately perpendicular to the central axis. In various embodiments, each of the plurality of electrodes can be approximately four times thicker at the exit end than at the entrance end. In various embodiments, the length of the electrodes comprises between about <NUM> to about <NUM>. In various embodiments, the diameter of the inlet aperture can be between about <NUM> to about <NUM>. In various embodiments, the diameter of the exit aperture can be about <NUM> to about <NUM>. In various embodiments, the at least one ion guide can be attached to a printed circuit board. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr to about <NUM> torr. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr. In various embodiments, the at least one ion guide can comprise a multipole. In various embodiments, the multipole can comprise any suitable number of electrodes. In various embodiments, the multipole can comprise any even number of electrodes. In various embodiments, the multipole can be selected from an ion guide having four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes. In various embodiments, twelve electrodes are provided that are separated by a gap of approximately <NUM> and have a thickness in the direction approximately perpendicular to the central axis that increases from approximately <NUM> at the entrance end to approximately <NUM> at the exit end.

The applicant's teachings provide a method of performing mass analysis. The method comprises providing an ion source for generating ions from a sample in a high-pressure region. There is provided a first vacuum chamber having an inlet aperture for passing the ions from the high-pressure region into the first vacuum chamber and an exit aperture for passing ions from the first vacuum chamber. The method also comprises providing at least one ion guide. The at least one ion guide is positioned in the chamber between the inlet aperture and an exit aperture so that when an RF voltage, provided by an RF power supply, is applied to the at least one ion guide, the ions are radially confined within the internal volume of the at least one ion guide and focused and directed to the exit aperture. In various embodiments, the method comprises a second vacuum chamber following the first vacuum chamber, where the pressure in the second vacuum chamber is lower than the pressure in the first vacuum chamber. A second ion guide in the second vacuum chamber can be provided to further focus the ions through the second vacuum chamber. The at least one ion guide has an entrance end and an exit end. In various embodiments, the entrance end comprises an opening with an inscribed circle that is larger than the inscribed circle that comprises the exit end. In various embodiments, the inscribed circle at the entrance end has a diameter of between about <NUM> and about <NUM>. In various embodiments, the inscribed circle at the exit end has a diameter of between about <NUM> and about <NUM>. In various embodiments, the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various embodiments, the entrance end of the ion guide has a diameter of between about <NUM> and about <NUM>. In various embodiments, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>. The at least one ion guide comprises a plurality of electrodes arranged around a central axis defining an ion channel. Each of the plurality of electrodes are tapered, and a planar surface of each of the plurality of tapered electrodes is facing the interior of the at least one ion guide, the surface gradually being narrowed and tilted inward to provide a smaller inscribed radius at the exit. In various embodiments, the surface of each of the plurality of tapered electrodes can be any suitable shape. In various embodiments, the surface can be curved. In various embodiments, the surface can be convex or concave. A power supply provides an RF voltage to the at least one ion guide.

In various embodiments, there is a greater resistance to the radial flow of gas from the interior to the exterior of the ion guide at the exit end than at the entrance end. The spacing between adjacent electrodes is essentially constant over the length of the ion guide. In various embodiments, the spacing between adjacent electrodes is between about <NUM> to about <NUM>. Each of the plurality of electrodes gradually becomes thicker towards the narrower exit end of the ion guide, the thickness being in the direction approximately perpendicular to the central axis. In various embodiments, each of the plurality of electrodes can be approximately four times thicker at the exit end than at the entrance end. In various embodiments, the length of the electrodes comprises between about <NUM> to about <NUM>. In various embodiments, the diameter of the inlet aperture can be between about <NUM> to about <NUM>. In various embodiments, the diameter of the exit aperture can be about <NUM> to about <NUM>. In various embodiments, the at least one ion guide can be attached to a printed circuit board. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr to about <NUM> torr. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr. In various embodiments, the at least one ion guide can comprise a multipole. In various embodiments, the multipole can have any even number of electrodes. In various embodiments, the multipole can comprise any suitable number of electrodes. In various embodiments, the multipole can be selected from an ion guide having four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes. In various embodiments, twelve electrodes are provided that are separated by a gap of approximately <NUM> and have a thickness in the direction approximately perpendicular to the central axis that increases from approximately <NUM> at the entrance end to approximately <NUM> at the exit end.

The skilled person in the art will understand that the drawings, described below, are for illustration purposes only. The drawings are not intended to limit the scope of the applicant's teachings in any way.

In the drawings, like reference numerals indicate like parts.

It should be understood that the phrase "a" or "an" used in conjunction with the applicant's teachings with reference to various elements encompasses "one or more" or "at least one" unless the context clearly indicates otherwise. An apparatus for performing mass analysis is provided. Reference is first made to <FIG>, which shows schematically a mass spectrometer, generally indicated by reference number <NUM> according to various embodiments of the applicant's teachings. The mass spectrometer <NUM> comprises an ion source <NUM> for generating ions <NUM> from a sample of interest, not shown. In various embodiments, the ion source <NUM> can be positioned in a high-pressure region containing a background gas, while the ions <NUM> travel towards a first vacuum chamber <NUM>, in the direction indicated by the arrow <NUM>. The ions enter the chamber <NUM> through an inlet aperture <NUM>, where the ions are entrained by a supersonic flow of gas, typically referred to as a supersonic free jet expansion as described, for example, in applicant's <CIT> and<CIT>.

In various embodiments, the ions <NUM> can travel towards a first vacuum chamber <NUM>, in the direction indicated by the arrow <NUM>. In various embodiments, a vacuum pump <NUM> can provide suitable vacuum to first vacuum chamber <NUM>. In various embodiments, the first vacuum chamber can comprise a pressure between about <NUM> torr to about <NUM> torr. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr. The pressure in the first vacuum chamber <NUM> can be maintained by pump <NUM>, and power supply <NUM> can be connected to the at least one ion guide <NUM> to provide RF voltage in a known manner for radially confining, focusing, and passing ions <NUM> from the first vacuum chamber <NUM>. The first vacuum chamber <NUM> comprises an inlet aperture <NUM> for passing the ions into the first vacuum chamber <NUM> and an exit aperture <NUM> located downstream from the inlet aperture <NUM>. In various embodiments, the exit aperture <NUM> can separate the first vacuum chamber <NUM> from the next or second vacuum chamber <NUM> which can house a further ion guide <NUM>, as exemplified in <FIG>, <FIG> and <FIG>. In various embodiments, the pressure of the second vacuum chamber can be between about <NUM> torr and about <NUM> torr. In various embodiments, a vacuum pump 42b can provide suitable vacuum to second vacuum chamber <NUM>. In various embodiments, subsequent vacuum chambers, <NUM> and <NUM>, can be provided with respective vacuum pumps, 42c and 42d. Vacuum chambers <NUM> and <NUM> can house an ion guide <NUM> or mass analyzer <NUM>. Vacuum chamber <NUM> can further comprise stubby rods <NUM>. In various embodiments, one or more power supplies can supply voltages to ion guides <NUM> and <NUM>.

In various embodiments, declustering voltages can be provided between apertures and RF ion guides in order to decluster ions. Declustering voltages can comprise DC voltage differences between ion optical elements such as metal plates containing apertures and RF ions guides, or between two RF ion guides, the DC voltage difference acting to increase the velocity of ions in the background gas, exciting the ions by means of collisions to remove any residual neutral clusters that remain on the ions, or even to fragment ions if so desired. The DC voltage differences can be provided to various ion optical elements by DC power supplies (not shown) in a known manner. The DC voltage differences, sometimes referred to as declustering voltages, can be controlled in order to control the amount of declustering or fragmentation, as is known in the art. In various embodiments, declustering or fragmentation voltages can be provided, for example, between the plate containing the inlet aperture <NUM> and the first RF ion guide <NUM>, between ion guide <NUM> and the plate containing exit aperture <NUM>, or between exit aperture <NUM> and RF ion guide <NUM>, or between the vacuum chambers <NUM> and <NUM>. In various embodiments, more than one declustering voltage in more than one location can be applied. In various embodiments, RF ion guides <NUM> or <NUM> can comprise two or more segments. In various embodiments, declustering voltages can be provided between two or more segments of RF ion guides located in any of said vacuum chambers <NUM>, <NUM>, <NUM> or <NUM>. In various embodiments, declustering voltages can be provided between any ion optical element such as a plate aperture or ion focusing lens or RF ion guide, and any adjacent ion optical elements through which the ions are directed.

As shown in <FIG>, the at least one ion guide <NUM> of <FIG>, between the inlet <NUM> and exit apertures <NUM> of vacuum chamber <NUM> and having an entrance end <NUM> and an exit end <NUM>, comprises a plurality of electrodes arranged around a central axis defining an ion channel. The plurality of electrodes are tapered, a planar surface of each of the plurality of tapered electrodes facing the interior of the at least one ion guide, and the surface gradually being narrowed and tilting inward to provide a smaller inscribed radius at the exit end. In various embodiments, the surface of each of the plurality of tapered electrodes can be any suitable shape. In various embodiments, the surface can be curved. In various embodiments, the surface can be convex or concave. A power supply can provide an RF voltage to the at least one ion guide. <FIG> shows a top view or view from the entrance of the multipole as well as a single electrode <NUM>.

Each of the plurality of electrodes gradually becomes thicker towards the narrower exit end of the ion guide, the thickness being in the direction approximately perpendicular to the central axis of the ion guide. In various embodiments, each of the plurality of electrodes is approximately four times thicker at the exit end than at the entrance end.

The spacing between adjacent electrodes is essentially constant over the length of the ion guide. In various embodiments, the spacing between adjacent electrodes can be between about <NUM> to about <NUM>.

In various embodiments, the gas flow through inlet aperture <NUM> comprises a free jet expansion, in which the gas and ions are directed at high velocities through a barrel-shaped region into the interior of the RF ion guide as described, for example, in applicant's <CIT> and <CIT>. In various embodiments, the entrance diameter of RF ion guide <NUM> can be selected to be at least <NUM>% of the diameter of the barrel shock of the free jet. This ensures that a large proportion of the ions that are entrained in the free jet is captured by the RF ion guide, and can be focused by the RF fields in the ion guide. The large gas flow that is also contained within the boundaries of the free jet escapes through the gaps between the electrodes of the RF ion guide and is pumped away by vacuum pump <NUM> in order to maintain the vacuum pressure in chamber <NUM>. This gas flow from the interior of the ion guide to the vacuum pump <NUM> comprises a radial gas flow.

There is a greater resistance to the radial flow of gas from the interior to the exterior of the ion guide at the exit end than at the entrance end. As shown in <FIG>, the width of the gap G (dimension indicated by the distance between the two single-ended solid arrows) between adjacent electrodes, combined with the thickness of the electrodes T (dimension indicated by the double-ended solid arrows) in a direction perpendicular to the axis of the ion guide, comprises a channel through which the gas 37a, indicated by the dotted arrows, must flow to escape from the interior of the ion guide. The resistance to radial gas flow is greater at the exit end of the ion guide because the electrodes <NUM> are thicker at the exit end than at the entrance end, thereby reducing the gas conductance or increasing the resistance to radial gas flow. The thicker channel comprises a greater resistance to gas flow than does a thinner channel, thereby reducing the radial gas flow outward at the exit end than at the entrance end. This reduces the tendency of the gas to drag the ions outward through the gaps of the ion guide, thereby improving the ability of the RF ion guide to contain the ions within the ion guide, and to focus the ions through the exit aperture <NUM>.

In various embodiments, the ion guide can comprise twelve electrodes, each electrode separated from adjacent electrodes by a gap of approximately <NUM>. In various embodiments, the twelve electrodes can have a thickness T in the direction approximately perpendicular to the central axis that increases from approximately <NUM> at the entrance end to approximately <NUM> at the exit end. In various embodiments, the thickness T is approximately <NUM> times greater at the exit than at the entrance.

In various embodiments, the length of the electrodes is between about <NUM> to about <NUM>. In various embodiments, the diameter of the inlet aperture <NUM> is about <NUM> to about <NUM>. In various embodiments, the diameter of the exit aperture <NUM> is about <NUM> to about <NUM>. In various embodiments , the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various embodiments, the diameter of the entrance end of the ion guide can be selected to be at least <NUM>% of the diameter of the diameter of the free jet. In various embodiments, the entrance end of the ion guide can have a diameter of between about <NUM> and about <NUM>. In various embodiments, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>.

In various embodiments, the pressure of the first vacuum chamber can be between about <NUM> torr to about <NUM> torr. In various embodiments, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr.

In various embodiments, the at least one ion guide can comprise a multipole. In various embodiments, the multipole can comprise any suitable number of electrodes. In various embodiments, the multipole can comprise any even number of electrodes. In various embodiments, the multipole is selected from four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes. In various embodiments, the multipole can comprise odd numbers of electrodes by suitably adjusting the phase of the RF voltages between poles as is known in the art.

In various embodiments, the at least one ion guide can comprise a series of multipole ion guides. In various embodiments, the series of multipole ion guides can comprise any suitable configuration of rods. In various embodiments, as exemplified in <FIG>, the at least one guide <NUM> can comprise the plurality of electrodes of <FIG>, and the at least second ion guide <NUM> can comprise flat, T-shaped rods <NUM>. In various embodiments, the T-shaped rods can have flat surfaces that can face the interior of the ion guide. In various embodiments, the at least second ion guide can have an entrance end diameter that is larger than the exit end diameter. As shown in <FIG>, the stems of the T-shaped electrodes can be tilted so that the exit end diameter is smaller than the entrance end diameter. In various embodiments, the at least second ion guide can have an entrance end diameter that can be selected to capture the ion beam that is emitted from the first ion guide. In various embodiments, the second ion guide can comprise electrodes that are round, flat, rectangular, oval, T-shaped, or any other suitable shape. In various embodiments, the second ion guide can comprise a ring guide or ion funnel as is known in the art. <FIG> shows a top view of the multipole of the first ion guide <NUM> and a top view of the multipole of the second ion guide <NUM>. In various embodiments, the second ion guide may converge toward the exit as shown in <FIG>, or may be straight so that the entrance and exit ends are of the same diameter. In various embodiments, the first ion guide and second ion guide can have RF frequencies of between about <NUM> and about <NUM>. In various embodiments, the first ion guide can have an RF frequency of about <NUM>, and the second ion guide can have an RF frequency of about <NUM>. In various embodiments, the ion guides can have voltages between about <NUM> volts and about <NUM> volts. As is known in the art, the RF voltages of the ion guides can be adjusted to provide optimum transmission of different m/z values of the ions. In various embodiments, the RF voltages of the ion guides can be scanned as a function of the m/z value of the first mass filter or scanned in order to provide the desired or suitable transmission efficiency. In various embodiments, the RF voltage of the ion guides can be selected to reduce the transmission efficiency of ions of selected mass range in order to reduce the ion flux. For example, in some cases, it is desirable to reduce the ion current in order to reduce space charge effects in parts of the mass spectrometer system further downstream or to reduce saturation effects on the ion detector, the RF voltage of any of the ion guides in the mass spectrometer can be used to throttle the intensity of the ion beam by suitably increasing or decreasing the RF voltage or the RF frequency from the value that provides maximum transmission.

In various embodiments, the RF voltage of the second ion guide can be selected to be a fixed percentage or ratio of the RF voltage of the first ion guide. In various embodiments, the RF voltage of the second ion guide can be provided by dividing the RF voltage from the first ion guide through a capacitive divider as is known in the art.

In various embodiments, the at least one ion guide can comprise a first ion guide <NUM> followed by at least a second ion guide <NUM> wherein the at least second ion guide <NUM> comprises a smaller diameter than the first ion guide <NUM>. In various embodiments, the series of multipole ion guides can include any number of electrodes, including quadrupole, hexapole, octapole, higher number of poles, or any combination thereof. In various embodiments, the second ion guide, <NUM>, can be located in a separate vacuum chamber, separated from the first vacuum chamber by an aperture plate, <NUM>, as shown in <FIG>. The pressure in the second chamber can be at a lower pressure than the pressure in the first vacuum chamber. In various embodiments, the pressure in the first vacuum chamber can be in the range of about <NUM> torr to about <NUM> torr. In various embodiments, the pressure in the second vacuum chamber can be in the range of between about <NUM> torr to about <NUM> torr.

In various embodiments, the second ion guide can be located in the same vacuum chamber, at the same pressure, as the first ion guide. In various embodiments, the at least first and second ion guides can be mounted on a single flange as a unit which can be removed for service or replacement. Each ion guide can be separately removable from the flange. The flange can accommodate the RF connections and the capacitive divider so that connection to the RF power supply can be provided by inserting the flange into position, the RF connections being made by a suitable series of electrical plugs and sockets on the mounting chamber.

As shown in <FIG>, in an example, the at least one ion guide <NUM> of <FIG>, between the inlet <NUM> and exit apertures <NUM> of vacuum chamber <NUM> and having an entrance end <NUM> and an exit end <NUM>, can comprise a plurality of planar electrodes <NUM> defining an ion channel, each of the plurality of planar electrodes being folded, or bent, along the length of the ion guide to form a gradually narrowing planar surface <NUM> that faces the interior of the at least one ion guide. In various aspects, the planar surface can become narrower towards the end of each of the electrodes. In various aspects, each of the plurality of electrodes can be tapered. In various aspects, a second planar surface, <NUM>, is approximately orthogonal to the axis of the ion guide. In various aspects, a power supply can provide an RF voltage to the at least one ion guide.

In various aspects, the plurality of electrodes can be folded at about <NUM> degrees. In various aspects, the length of the electrodes can be between about <NUM> to about <NUM>. In various aspects, the spacing between adjacent electrodes can be constant and can be between about <NUM> to about <NUM>. In various aspects, the diameter of the inlet aperture can be between about <NUM> to about <NUM>. In various aspects, the diameter of the exit aperture can be between about <NUM> to about <NUM>. In various aspects, the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various aspects, the entrance end of the ion guide has a diameter of between about <NUM> and about <NUM>. In various aspects, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>. In various aspects, the electrodes of the at least one ion guide can be individually attached or soldered to a printed circuit board at the entrance end and a printed circuit board at the exit end. The printed circuit boards can provide a mechanical mounting for the electrodes and can provide electrical connections to the electrodes. Electrical components such as capacitors or resistors which supply RF and DC voltages to the electrodes of the ion guide can be mounted or soldered on the printed circuit board. The printed circuit board can contain all circuit connections and tracks as is known in conventional printed circuit boards in order to reduce the need to use wires to connect individual components. In various aspects, the aperture plates containing the apertures such as aperture <NUM> in <FIG> can be mounted on the printed circuit board. In various aspects, the printed circuit board can form part of the vacuum barrier between adjacent chambers. In various aspects, the pressure of the first vacuum chamber can be between about <NUM> torr to about <NUM> torr. In various aspects, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr. In various aspects, the electrodes can be comprised of metal. In various aspects, the electrodes can be formed from sheet or shim metal. In various aspects, the at least one ion guide can comprise a multipole. In various aspects, the multipole can comprise any suitable number of electrodes. In various aspects, the multipole can comprise any even number of electrodes. In various aspects, the multipole can be selected from four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes. In various aspects, a power supply can provide an RF voltage to the at least one ion guide.

<FIG> shows a flat blade, which can comprise a thin, flat piece of metal that can be folded or bent along a line, as shown in <FIG>, to form a planar surface.

In various aspects, the at least one ion guide can comprise a series of multipole ion guides as shown in <FIG>. In the example shown in <FIG>, the at least one guide <NUM> can comprise a plurality of electrodes of <FIG>, and the at least second ion guide <NUM> can comprise quadrupole rods <NUM> or any other type of rods. In various aspects, the at least one ion guide can comprise a first ion guide <NUM> followed by at least a second ion guide <NUM> wherein the at least second ion guide <NUM> comprises a smaller diameter than the first ion guide <NUM>. In various aspects, the at least one ion guide and the subsequent series of ion guides can comprise planar electrodes or rods or a combination thereof. In various aspects, the series of multipole ion guides can include any number of electrodes, including quadrupole, hexapole, octapole, higher number of poles, or any combination thereof.

In various embodiments, a method is provided for performing mass analysis comprising providing an ion source for generating ions from a sample in a high pressure region. A vacuum chamber is provided comprising an inlet aperture for passing the ions from the high-pressure region into the vacuum chamber and an exit aperture for passing ions from the vacuum chamber. At least one ion guide is provided between the inlet and exit apertures, and the at least one ion guide can comprise an entrance end and an exit end. The at least one ion guide has a plurality of electrodes arranged around a central axis defining an ion channel, each of the plurality of electrodes being tapered, a planar surface of each of the plurality of tapered electrodes can face the interior of the at least one ion guide, and the surface being gradually narrowed and tilting inward to provide a smaller inscribed radius at the exit end. In various embodiments, the surface of each of the plurality of tapered electrodes can be any suitable shape. In various embodiments, the surface can be curved. In various embodiments, the surface can be convex or concave. A power supply is provided for providing an RF voltage to the at least one ion guide.

In various embodiments, there is a greater resistance to the flow of radial gas from the interior to the exterior of the ion guide at the exit end than at the entrance end. The resistance to gas flow is greater at the exit end of the ion guide because the electrodes are thicker at the exit end than the entrance end, thereby reducing the gas conductance or increasing the resistance to the radial gas flow.

Each of the plurality of electrodes gradually becomes thicker towards the narrower exit end of the ion guide, the thickness being in the direction approximately perpendicular to the central axis. In various embodiments, each of the plurality of electrodes can be approximately four times thicker at the exit end than at the entrance end.

In various embodiments, the length of the electrodes can between about <NUM> to about <NUM>. In various embodiments, the diameter of the inlet aperture is about <NUM> to about <NUM>. In various embodiments, the diameter of the exit aperture is about <NUM> to about <NUM>. In various embodiments, the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various embodiments, the entrance end of the ion guide has a diameter of between about <NUM> and about <NUM>. In various embodiments, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>.

In various embodiments, the at least one ion guide can be attached to a printed circuit board.

In various embodiments, the at least one ion guide can comprise a multipole. In various embodiments, the multipole can comprise any suitable number of electrodes. In various embodiments, the multipole can comprise any even number of electrodes. In various embodiments, the multipole is selected from four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes. In various embodiments, twelve electrodes are provided that are separated by a gap of approximately <NUM> and have a thickness in the direction approximately perpendicular to the central axis that increases from approximately <NUM> at the entrance end to approximately <NUM> at the exit end.

In various embodiments, the at least one ion guide can comprise a series of multipole ion guides. In various embodiments, the at least one guide <NUM> can comprise the plurality of electrodes of <FIG>, and the at least second ion guide <NUM> can comprise quadrupole rods. In various embodiments, the at least one ion guide can comprise a first ion guide followed by at least a second ion guide wherein the at least second ion guide comprises a smaller diameter than the first ion guide. In various embodiments, the at least one ion guide and the subsequent series of ion guides can comprise planar electrodes or rods or a combination thereof. In various embodiments, the series of multipole ion guides can include any number of electrodes, including quadrupole, hexapole, octapole, higher number of poles, or any combination thereof.

In an example, a method is provided for performing mass analysis comprising generating ions from a sample in a high pressure region. In various aspects, the ions can pass into a vacuum chamber comprising an inlet aperture for passing the ions from the high-pressure region into the vacuum chamber. In various aspects, an exit aperture can be provided for passing ions from the vacuum chamber. In various aspects, there is provided at least one ion guide between the inlet and exit apertures, the at least one ion guide can have an entrance end and an exit end, the at least one ion guide can have a plurality of planar electrodes defining an ion channel, each of the plurality of planar electrodes being folded, or bent, along the length of the ion guide to form a gradually narrowing planar surface that faces the interior of the at least one ion guide. In various aspects, the planar surface can become narrower towards the end of each of the electrodes. In various aspects, each of the plurality of electrodes can be tapered. In various aspects, a second planar surface is approximately orthogonal to the axis of the ion guide. In various aspects, an RF voltage can be applied to the at least one ion guide.

In various aspects, the plurality of planar electrodes can be folded at about <NUM> degrees. In various aspects, the length of the electrodes comprises between about <NUM> to about <NUM>. In various aspects, the spacing between the plurality of electrodes can be constant and can be between about <NUM> to about <NUM>. In various aspects, the diameter of the inlet aperture can be between about <NUM> to about <NUM>. In various aspects, the diameter of the exit aperture can be between about <NUM> to about <NUM>. In various aspects, the size of the inlet and exit apertures can dictate the diameter of the entrance and exit ends of the ion guide. In various aspects, the entrance end of the ion guide has a diameter of between about <NUM> and about <NUM>. In various aspects, the exit end of the ion guide has a diameter between about <NUM> and about <NUM>. In various aspects, the at least one ion guide can be attached to a printed circuit board. In various aspects, the first vacuum chamber can have a pressure between about <NUM> torr to about <NUM> torr. In various aspects, the first vacuum chamber can have a pressure between about <NUM> torr and about <NUM> torr. In various aspects, the electrodes can be comprised of metal.

In various aspects, the at least one ion guide comprises a multipole. In various aspects, the multipole can comprise any even number of electrodes. In various aspects, the multipole is selected from four electrodes, six electrodes, eight electrodes, ten electrodes, twelve electrodes, fourteen electrodes, and sixteen electrodes.

In various aspects, the at least one ion guide can comprise a series of multipole ion guides. In various aspects, the at least one guide <NUM> can comprise the plurality of electrodes of <FIG>, and the at least second ion guide <NUM> can comprise quadrupole rods. In various aspects, the at least second ion guide can be comprised of T-shaped electrodes. In various aspects, the at least one ion guide can comprise a first ion guide followed by at least a second ion guide wherein the at least second ion guide comprises a smaller diameter than the first ion guide. In various aspects, the at least second ion guide can comprise an entrance end diameter that is larger than the exit end diameter. In various aspects, the at least one ion guide and the subsequent series of ion guides can comprise planar electrodes or rods or a combination thereof. In various aspects, the series of multipole ion guides can comprise any number of electrodes, including quadrupole, hexapole, octapole, higher number of poles, or any combination thereof.

While the applicants' teachings have been particularly shown and described with reference to specific illustrative embodiments, it should be understood that various changes in form and detail may be made without departing from the scope of the claims. Therefore, all embodiments that come within the scope of the claims are claimed. The descriptions and diagrams of the methods of the applicants' teachings should not be read as limited to the described order of elements unless stated to that effect.

Claim 1:
A mass spectrometer (<NUM>) comprising:
a. an ion source (<NUM>) for generating ions (<NUM>) from a sample in a high pressure region;
b. a first vacuum chamber (<NUM>) comprising an inlet aperture (<NUM>) for passing the ions from the high-pressure region into the vacuum chamber, and an exit aperture (<NUM>) for passing ions from the vacuum chamber;
c. at least one ion guide (<NUM>) between the inlet and exit apertures, the at least one ion guide having an entrance end (<NUM>) and an exit end (<NUM>), the at least one ion guide having a plurality of electrodes arranged around a central axis defining an ion channel, each of the plurality of electrodes being tapered, wherein each of the plurality of tapered electrodes has a planar surface facing the interior of the at least one ion guide, and the surface gradually being narrowed and tilted inward to provide a smaller inscribed radius at the exit, wherein adjacent electrodes are separated by a gap, the gap having a width G at said planar surface; and
d. a power supply (<NUM>) for providing an RF voltage to the at least one ion guide;
characterized in that:
the width G is constant along the length of the ion guide and a thickness T of the electrodes gradually increases towards the exit end of the ion guide, wherein the thickness T is defined by the thickness of the respectively adjacent electrodes in the region where the width G is constant along the direction approximately perpendicular to the central axis.