TIME-OF-FLIGHT MASS SPECTROMETER

Abstract

A voltage applied to an exit gate electrode forming a potential barrier and temporarily trapping ions within the inner space of the ion guide is higher than a voltage at an ion guide's exit end. A higher voltage is applied to the exit gate electrode for a lower m/z value of the measurement target ion, to push back the ion which has slowly moved along a potential gradient and reached the exit end of the ion guide. An ion having a lower m/z value is more likely to be located in a farther region from the exit end and forced to travel a longer distance when voltage applied to the exit gate electrode is lowered. A lower m/z value also means a higher travelling speed toward the orthogonal accelerator, whereby m/z dependency of the time required for travel from the ion guide to the orthogonal accelerator eventually becomes low.

Claims

1. An orthogonal acceleration time-of-flight mass spectrometer including an orthogonal accelerator for accelerating incident ions in an orthogonal direction to an axis of incidence of the ions and a separating-detecting section in which the accelerated ions are separated according to their mass-to-charge ratios and detected, the mass spectrometer further comprising: a) an ion trap for temporarily trapping ions as a measurement target, including an ion guide for converging ions into an area near an ion beam axis by a radio-frequency electric field and an exit gate electrode placed on an outside of an exit end of the ion guide, with the ion guide having a potential distribution sloped downward in a travelling direction of the ions on the ion beam axis; b) a voltage supplier for applying a DC voltage to the exit gate electrode; and c) a controller for controlling the voltage supplier in such a manner that a trapping DC voltage which is higher than at least a potential at the exit end of the ion guide is applied to the exit gate electrode while trapping the ions as a measurement target within an inner space of the ion guide, and a releasing DC voltage which is lower than the potential at the exit end of the ion guide is applied to the exit gate electrode at a time of releasing the ions from the ion guide, where the controller changes the trapping DC voltage according to the mass-to-charge ratio or mass-to-charge ratio range of the ions as the measurement target.

2. An orthogonal acceleration time-of-flight mass spectrometer including: an ion trap section for capturing incident ions by an effect of an electric field and subsequently imparting acceleration energy to the ions at a predetermined timing to eject the ions at substantially a same point in time; and a separating-detecting section in which the ions ejected from the ion trap section are separated according to their mass-to-charge ratios and detected, the mass spectrometer further comprising: a) an ion trap for temporarily trapping ions as a measurement target, including an ion guide for converging ions into an area near an ion beam axis by a radio-frequency electric field and an exit gate electrode placed on an outside of an exit end of the ion guide, with the ion guide having a potential distribution sloped downward in a travelling direction of the ions on the ion beam axis; b) a voltage supplier for applying a DC voltage to the exit gate electrode; and c) a controller for controlling the voltage supplier in such a manner that a trapping DC voltage which is higher than at least a potential at the exit end of the ion guide is applied to the exit gate electrode while trapping the ions as the measurement target within an inner space of the ion guide, and a releasing DC voltage which is lower than the potential at the exit end of the ion guide is applied to the exit gate electrode at a time of releasing the ions from the ion guide, where the controller changes the trapping DC voltage according to the mass-to-charge ratio or mass-to-charge ratio range of the ions as the measurement target.

3. The time-of-flight mass spectrometer according to claim 1, wherein: the controller additionally changes the releasing DC voltage according to the mass-to-charge ratio or mass-to-charge ratio range of the ions as the measurement target.

4. An orthogonal acceleration time-of-flight mass spectrometer including an orthogonal accelerator for accelerating incident ions in an orthogonal direction to an axis of incidence of the ions and a separating-detecting section in which the accelerated ions are separated according to their mass-to-charge ratios and detected, the mass spectrometer further comprising: a) an ion trap for temporarily trapping ions as a measurement target, including an ion guide for converging ions into an area near an ion beam axis by a radio-frequency electric field and an exit gate electrode placed on an outside of an exit end of the ion guide, with the ion guide having a potential distribution sloped downward in a travelling direction of the ions on the ion beam axis; b) a voltage supplier for applying a DC voltage to the exit gate electrode; and c) a controller for controlling the voltage supplier in such a manner that, while trapping the ions as the measurement target within an inner space of the ion guide, a trapping DC voltage which is higher than at least a potential at the exit end of the ion guide is applied to the exit gate electrode, the DC voltage applied to the exit gate electrode is changed for a predetermined period of time so as to increase the potential at the exit gate electrode before releasing the ions from the ion guide, and subsequently, a releasing DC voltage which is lower than the potential at the exit end of the ion guide is applied to the exit gate electrode.

5. An orthogonal acceleration time-of-flight mass spectrometer including: an ion trap section for capturing incident ions by an effect of an electric field and subsequently imparting acceleration energy to the ions at a predetermined timing to eject the ions at substantially a same point in time; and a separating-detecting section in which the ions ejected from the ion trap section are separated according to their mass-to-charge ratios and detected, the mass spectrometer further comprising: a) an ion trap for temporarily trapping ions as a measurement target, including an ion guide for converging ions into an area near an ion beam axis by a radio-frequency electric field and an exit gate electrode placed on an outside of an exit end of the ion guide, with the ion guide having a potential distribution sloped downward in a travelling direction of the ions on the ion beam axis; b) a voltage supplier for applying a DC voltage to the exit gate electrode; and c) a controller for controlling the voltage supplier in such a manner that, while trapping the ions as the measurement target within an inner space of the ion guide, a trapping DC voltage which is higher than at least a potential at the exit end of the ion guide is applied to the exit gate electrode, the DC voltage applied to the exit gate electrode is changed for a predetermined period of time so as to increase the potential at the exit gate electrode before releasing the ions from the ion guide, and subsequently, a releasing DC voltage which is lower than the potential at the exit end of the ion guide is applied to the exit gate electrode.

6. The time-of-flight mass spectrometer according to claim 1, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

7. The time-of-flight mass spectrometer according to claim 2, wherein: the controller additionally changes the releasing DC voltage according to the mass-to-charge ratio or mass-to-charge ratio range of the ions as the measurement target.

8. The time-of-flight mass spectrometer according to claim 2, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

9. The time-of-flight mass spectrometer according to claim 3, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

10. The time-of-flight mass spectrometer according to claim 4, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

11. The time-of-flight mass spectrometer according to claim 5, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

12. The time-of-flight mass spectrometer according to claim 7, wherein: the ion trap is a linear ion trap placed within a collision cell which dissociates an ion.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0053] FIG. 1 is an overall configuration diagram of a Q-TOFMS as the first embodiment of the present invention.

[0054] FIG. 2A is a detailed configuration diagram of the section between the collision cell and the orthogonal accelerator in FIG. 1, and FIG. 2B is a schematic diagram of the potential distribution on the axis C.

[0055] FIGS. 3A and 3B are diagrams illustrating the behavior of an ion within the inner space of the ion guide in the Q-TOFMS of the first embodiment.

[0056] FIG. 4 is a configuration diagram assumed in a simulation calculation of the motion of an ion in the Q-TOFMS of the first embodiment.

[0057] FIG. 5 is a chart showing the result of a simulation of the relationship between the releasing DC voltage and the travel time, with the initial position of the ion changed according to the mass-to-charge ratio.

[0058] FIG. 6 is a schematic diagram of the potential distribution on the axis C in a Q-TOFMS as the second embodiment of the present invention.

[0059] FIG. 7 is a timing chart of the voltage applied to the exit gate electrode and the voltage applied for orthogonal acceleration in the Q-TOFMS of the second embodiment.

[0060] FIG. 8 is a configuration diagram assumed in a simulation calculation for the motion of an ion in the Q-TOFMS of the second embodiment.

[0061] FIG. 9 is a chart showing the result of a simulation of the relationship between the push-back voltage and the travel time for ions with different mass-to-charge ratios.

[0062] FIG. 10A is a detailed configuration diagram of the collision cell and the orthogonal accelerator in a conventional Q-TOFMS, FIG. 10B is a chart showing the potential distribution on the axis C, and FIG. 10C is a timing chart of the voltage applied to the exit gate electrode and the orthogonal acceleration voltage.

DESCRIPTION OF EMBODIMENTS

[0063] A Q-TOFMS as the first embodiment of the present invention is hereinafter described with reference to the attached drawings.

[0064] FIG. 1 is an overall configuration diagram of the Q-TOFMS of the first embodiment. The Q-TOFMS of the present embodiment has the configuration of a multi-stage differential pumping system including an ionization chamber 2 maintained at substantially atmospheric pressure and a high-vacuum chamber 6 evacuated to the highest degree of vacuum, between which three chambers, named the first through third intermediate vacuum chambers 3, 4 and 5, are provided within a chamber 1.

[0065] The ionization chamber 2 is provided with an ESI spray device 7 for electrospray ionization (ESI). When a sample liquid containing a target compound is supplied to the ESI spray device 7, ions originating from the target compound are generated from the droplets which have been given imbalanced electric charges and sprayed from the tip of the spray device 7. It should be noted that the ionization method is not limited to this technique. For example, if the sample is a liquid, an atmospheric pressure ionization method different from the ESI can be used, such as APCI or PESI. If the sample is in a solid form, the MALDI or similar method can be used. For a gasified sample, the EI or similar method is available.

[0066] The generated various ions are sent through a heated capillary 8 into the first intermediate vacuum chamber 3, where the ions are converged by an ion guide 9 and sent through a skimmer 10 into the second intermediate vacuum chamber 4. The ions are further converged by an octapole ion guide 11 and sent into the third intermediate vacuum chamber 5. The third intermediate vacuum chamber 5 contains a quadrupole mass filter 12 and a collision cell 13 within which a quadrupole ion guide 14 functioning as the linear ion trap is provided. The various ions derived from the sample are introduced into the quadrupole mass filter 12, where only an ion having a specific mass-to-charge ratio corresponding to the voltage applied to the quadrupole mass filter 12 travels through this filter. This ion is introduced into the collision cell 13 as the precursor ion. Due to a collision with a CID gas supplied from an external source into the collision cell 13, the precursor ion is dissociated and various product ions are thereby generated.

[0067] The ion guide 14 functions as a linear ion trap. The generated product ions are temporarily trapped within the inner space of the ion guide 14. At a predetermined timing, the trapped ions are released from the collision cell 13. Being guided by an ion transport optical system 16, the ions are introduced through an ion passage opening 15 into the high-vacuum chamber 6. The ion transport optical system 16 lies in both the third intermediate vacuum chamber 5 and the high-vacuum chamber 6 across the ion passage opening 15. The high-vacuum chamber 6 contains an orthogonal accelerator 17 serving as the ion ejection source, a flight space 20 provided with a reflector 21 and back plate 22, as well as an ion detector 23. The ions introduced into the orthogonal accelerator 17 along the X axis are accelerated in the Z-axis direction at a predetermined timing and begin to fly. The ions initially fly freely and are then repelled by a reflecting electric field created by the reflector 21 and back plate 22. Subsequently, the ions once more fly freely and eventually reach the ion detector 23. The time of flight from the point in time where an ion leaves the orthogonal accelerator 17 to the point in time where it arrives at the ion detector 23 depends on the mass-to-charge ratio of the ion. Accordingly, a data processor (not shown), which receives detection signals from the ion detector 23, calculates the mass-to-charge ratio of each ion based on its time of flight and creates, for example, a mass spectrum.

[0068] FIG. 2A is a detailed configuration diagram of the section between the collision cell 13 and the orthogonal accelerator 17 in FIG. 1, and FIG. 2B is a schematic diagram of the potential distribution on the axis C (which in the present case is the ion beam axis).

[0069] The ion guide 14 consists of four rod electrodes. As shown in FIG. 2A, these four rod electrodes (it should be noted that only two rod electrodes placed in the Z-axis direction across the axis C are shown in FIG. 2A) are not parallel to the axis C; they are arranged in an inclined form so that their distance from the axis C gradually increases in the travelling direction of the ions (in the figure, rightward). The rear end face of the collision cell 13 serves as the exit gate electrode 132. This exit gate electrode 132 and the ion guide 14 effectively function as the linear ion trap.

[0070] The ion transport optical system 16 is composed of a plurality of (in this example, five) disc-shaped plate electrodes arrayed along the axis C, each of which has a circular opening at its center. The orthogonal accelerator 17 includes an entrance electrode 171, pushing electrode 172 and grid-like extracting electrode 173. Under the command of a controller 30, an ion guide voltage generator 31 applies a predetermined voltage to each rod electrode of the ion guide 14, an exit gate electrode voltage generator 32 applies a predetermined voltage to the exit gate electrode 132, an ion transport optical system voltage generator 33 applies a predetermined voltage to each plate electrode included in the ion transport optical system 16, and an orthogonal accelerator voltage generator 34 applies predetermined voltages to the entrance electrode 171, pushing electrode 172 and extracting electrode 173, respectively.

[0071] In the Q-TOFMS of the present embodiment, the product ions generated by fragmenting an ion introduced into the collision cell 13 are temporarily trapped within the inner space of the ion guide 14. Then, the trapped ions are ejected from the collision cell 13 and introduced through the ion transport optical system 16 into the orthogonal accelerator 17 for mass spectrometry. The operation of this process is hereinafter described with reference to FIGS. 3A and 3B as well as FIGS. 2A and 2B. FIGS. 3A and 3B are diagrams illustrating the behavior of an ion within the inner space of the ion guide 14. It should be noted that the present example is the case where the measurement target ion is a positive ion. It is evident that the polarity of each voltage only needs to be reversed when the measurement target ion is a negative ion.

[0072] When ions are trapped within the inner space of the ion guide 14, the ion guide voltage generator 31 applies, to each of the four rod electrodes constituting the ion guide 14, a voltage generated by adding a radio-frequency voltage and a DC voltage. The radio-frequency voltage serves to form a quadrupole radio-frequency electric field which focuses the ions into an area near the ion beam axis C, while the DC voltage mainly serves to form a potential distribution along the ion beam axis C. In this stage, the exit gate electrode voltage generator 32 applies, to the exit gate electrode 132, a predetermined level of DC voltage that is higher than the voltage at the exit end of the ion guide 14.

[0073] The solid line U.sub.1 in FIG. 2B schematically represents the potential distribution on the ion beam axis C within the inner space of the ion guide 14 when ions are trapped within the same inner space. When the aforementioned voltages are applied, the potential distribution within the inner space of the ion guide 14 gently slopes from the entrance end down to the exit end. Meanwhile, as shown by a plurality of single-dotted chain lines U.sub.2 in FIG. 2B, the potential at the exit gate electrode 132 is higher than the potential at the exit end of the ion guide 14, whereby a potential barrier is formed between the exit end (located at point P.sub.1 in FIG. 2B) of the ion guide 14 and the exit gate electrode 132 (located at point P.sub.2 in FIG. 2B).

[0074] Due to the gentle downward slope of the potential distribution formed within the inner space of the ion guide 14, the ions trapped within the ion guide 14 move in the travelling direction of the ions (rightward in FIGS. 2A and 2B). Upon reaching the exit end of the ion guide 14, the ions are pushed back by the potential barrier. The controller 30 controls the exit gate electrode voltage generator 32 so that the voltage applied to the exit gate electrode 132 is changed according to the mass-to-charge ratio of the measurement target ion. Specifically, a higher level of voltage is applied to the exit gate electrode 132 for a lower mass-to-charge ratio of the measurement target ion. By this operation, a higher potential barrier is formed for a lower mass-to-charge ratio of the measurement target ion. The plurality of single-dotted chain lines U.sub.2 in FIG. 2B represent potential barriers with different heights.

[0075] FIG. 3A conceptually shows the behavior of an ion in the case where a high potential barrier is formed, i.e. when the mass-to-charge ratio of the ion is comparatively low, while FIG. 3B conceptually shows that of an ion in the case where a low potential barrier is formed, i.e. when the mass-to-charge ratio of the ion is comparatively high.

[0076] The ion pushed by the potential barrier ascends the potential slope indicated by the solid line U.sub.1 to a point where its kinetic energy becomes zero. Upon reaching this point, the ion turns its direction and once more descends the potential slope. As shown in FIG. 3A, a higher potential barrier has a steeper slope of the barrier and a greater amount of energy to push back the ion, so that the pushed ion returns to a farther position (indicated by point P.sub.3) from the exit end of the ion guide 14. By comparison, when the potential barrier is low as shown in FIG. 3B, the barrier has a gentler slope and a smaller amount of energy to push back the ion, so that the pushed ion returns no farther than a closer position (indicated by point P.sub.3′) to the exit end of the ion guide 14.

[0077] In other words, by changing the voltage applied to the exit gate electrode 132 in the previously described manner according to the mass-to-charge ratio of the measurement target ion, it is possible to make ions with lower mass-to-charge ratios tend to gather at closer positions to the entrance end of the ion guide 14 within the inner space of the ion guide 14, and to make ions with higher mass-to-charge ratios tend to gather at farther positions from the exit end of the ion guide 14 within the inner space of the ion guide 14. In this manner, when ions are trapped within the inner space of the ion guide 14, the location where the ions tend to gather is changed according to their mass-to-charge ratio. Subsequently, at a predetermined timing, the exit gate electrode voltage generator 32 lowers the voltage applied to the exit gate electrode 132 to a level that is lower than the voltage at the exit end of the ion guide 14 and yet higher than the voltage applied to the first plate electrode of the ion transport optical system 16. The broken line U3 in FIG. 2B schematically represents the potential distribution between the exit end of the ion guide 14 and the first plate electrode of the ion transport optical system 16 in this situation.

[0078] As shown in FIG. 2B, the potential barrier no longer exists and a potential gradient sloping from the exit end of the ion guide 14 down to the ion transport optical system 16 is formed, so that the ions trapped within the inner space of the ion guide 14 are simultaneously released toward the ion transport optical system 16. The starting point (initial position) from which the ions begin to move within the inner space of the ion guide 14 toward the ion transport optical system 16 varies depending on the mass-to-charge ratios of the ions; roughly speaking, the starting point for an ion having a lower mass-to-charge ratio is located at a farther position from the exit end of the ion guide 14. The released ions travel through the ion transport optical system 16 to the orthogonal accelerator 17, where an ion having a lower mass-to-charge ratio needs to travel a longer distance to reach the orthogonal accelerator 17.

[0079] In order to transport the ions through the ion transport optical system 16 while converging them into an area near the ion beam axis C, a different level of voltage is applied from the ion transport optical system voltage generator 33 to each plate electrode included in the ion transport optical system 16. Therefore, the potentials at the positions of where the plate electrodes are located are not exactly the same. However, the potential on average can be considered as constant. Accordingly, in FIG. 2B, the potential distribution is indicated by the dotted line.

[0080] The ions moving toward the orthogonal accelerator 17 gain most of their kinetic energy from the accelerating electric field formed within the space between the exit end of the ion guide 14 and the first plate electrode of the ion transport optical system 16. Provided that the amount of this energy is always the same, the moving speed of each ion depends on its mass-to-charge ratio; i.e. the lower the mass-to-charge ratio is, the higher the speed becomes. On the other hand, an ion having a lower mass-to-charge ratio has a longer travel distance. Therefore, an ion traveling faster than an ion having a higher mass-to-charge ratio will eventually have only a small difference in the terms of the time required to reach the orthogonal accelerator 17. This fact is hereinafter described using a simulation result.

[0081] FIG. 4 is a model configuration diagram assumed in a simulation calculation of the motion of the ion in the Q-TOFMS of the first embodiment. FIG. 5 is a chart showing the result of the simulation of the relationship between the releasing DC voltage (the voltage applied to the exit gate electrode 132 to release ions) and the travel time, with the initial position of the ion changed according to its mass-to-charge ratio. In the present example, the starting position of the ion is expressed in relation to the position of the exit gate electrode 132 as the reference point (zero), with the moving direction of the ions at the releasing point defined as positive and the opposite direction as negative. For example, the starting position of an ion with m/z 400 is located at 0.5 mm frontward from the exit gate electrode 132, while that of an ion having a lower mass-to-charge ratio, m/z 100, is located at 5.5 mm frontward from the exit gate electrode 132. Namely, the latter ion has a 5-mm longer travel distance than the former one.

[0082] For comparison, the travel time was also calculated for ions with m/z 100, m/z 200, m/z 300 and m/z 400 in the case where the ions were simply trapped within the inner space of the ion guide 14 before being released, i.e. under the condition that the ions were assumed to be located at almost the same position regardless of their mass-to-charge ratios when they were released. The result was 8.19037 usec, 11.5829 usec, 14.1861 usec and 16.3807 usec, respectively. On the other hand, as can be seen in FIG. 5, for example, when the releasing voltage is −1.5 V, the travel time of the ion with m/z 100 is approximately 14 usec, and the travel time of the ion with m/z 400 is approximately 16.1 usec. As compared to the result obtained under the condition that the ions were initially located at almost the same position, the range of the travel time was dramatically narrowed. This fact demonstrates that the travel time can be almost equalized by regulating the starting position of the ions according to their mass-to-charge ratios.

[0083] However, the change in the starting position of the ions also causes a change in the amount of energy given to the ions during their passage through the inner space of the ion guide 14. Therefore, it is difficult to accurately equalize the periods of time required for the travel of the ions having different mass-to-charge ratios by merely regulating the starting position of the ions. Therefore, it is preferable to additionally change the releasing DC voltage according to the mass-to-charge ratio of the measurement target ion. The result shown in FIG. 5 demonstrates that the travel time can be approximately equalized to 16 usec by setting the releasing DC voltage at approximately −1.8 V for the ion with m/z 400 and at approximately −0.4 V for the ion with m/z 100. Based on the relationship between the releasing DC voltage and the travel time previously determined by such a simulation or preliminary experiment, it is possible to appropriately set the releasing DC voltage according to the mass-to-charge ratio of the measurement target ion so as to practically eliminate the mass-to-charge-ratio dependency of the period of time required for the ions to reach the orthogonal accelerator 17.

[0084] At the point in time where the predetermined delay time has passed since the point of release of the ions from the ion guide 14 (i.e. collision cell 13), the orthogonal accelerator voltage generator 34 applies acceleration voltages to the pushing electrode 172 and extracting electrode 173, respectively. The delay time is a constant, which is previously determined according to the required travel time. When the accelerating voltages are applied in the orthogonal accelerator 17, the measurement target ion has already been introduced into the orthogonal accelerator 17 and is present within the space between the pushing electrode 172 and the extracting electrode 173, regardless of the mass-to-charge ratio of the measurement target ion. Therefore, in the Q-TOFMS of the present embodiment, the measurement target ion can be assuredly ejected into the flight space 20 and subjected to the mass spectrometry.

[0085] Next, a Q-TOFMS as the second embodiment of the present invention is described with reference to the attached drawings. The overall configuration of the Q-TOFMS of the second embodiment is the same as that of the first embodiment; the difference from the first embodiment exists in the control performed by the controller 30 in some operations, such as the application of the voltage from the exit gate electrode voltage generator 32 to the exit gate electrode 132. The characteristic control operation in the Q-TOFMS of the second embodiment is described with reference to FIGS. 6 and 7. FIG. 6 is a schematic diagram of the potential distribution on the axis C, while FIG. 7 is a timing chart of the voltage applied to the exit gate electrode and the voltage applied for orthogonal acceleration.

[0086] In the Q-TOFMS of the second embodiment, when ions are trapped within the inner space of the ion guide 14, the ion guide voltage generator 31 applies, to each of the four rod electrodes constituting the ion guide 14, a voltage generated by adding a radio-frequency voltage and a DC voltage, while the exit gate electrode voltage generator 32 applies, to the exit gate electrode 132, a predetermined level of DC voltage that is higher than the voltage at the exit end of the ion guide 14. These operations are the same as in the first embodiment except that the voltage applied to the exit gate electrode 132 in this stage is fixed. The single-dotted chain line U.sub.2 in FIG. 6 represents the potential distribution formed in this stage between the exit end (located at point P.sub.1 in FIG. 2B) of the ion guide 14 and the first plate electrode (located at point P.sub.4 in FIG. 2B) of the ion transport optical system 16. The potential barrier has a fixed height.

[0087] Subsequently, at a point in time which is earlier than the point of release of the ions from the inner space of the ion guide 14 by a predetermined length of time, the exit gate electrode voltage generator 32 increases the voltage applied to the exit gate electrode 132. The broken line U.sub.5 in FIG. 6 represents the potential distribution formed by this operation. When the potential barrier is increased, the ions which are trapped within the inner space of the ion guide 14 and moving toward the exit end of the ion guide 14 are greatly pushed back, where an ion having a lower mass-to-charge ratio is pushed back to a closer position to the entrance end of the ion guide 14. The increased potential barrier is maintained for only a short period of time. Subsequently, the voltage applied to the exit gate electrode 132 is decreased to a lower level than the voltage at the exit end of the ion guide 14. The ions trapped within the inner space of the ion guide 14 are thereby released, where the ions start from different positions depending on their respective mass-to-charge ratios; ions having lower mass-to-charge ratios start from closer positions to the entrance end of the ion guide 14. In other words, the travel distance of the ions varies depending on their mass-to-charge ratios, as already explained. By appropriately setting the value of the voltage applied to push back the ions immediately before the release of the ions in the previously described manner (push-back voltage), it is possible to equalize, to some extent, the periods of time required for the travel of the ions with different mass-to-charge ratios so that the ions almost simultaneously reach the orthogonal accelerator 17. This fact is hereinafter described using a simulation result.

[0088] FIG. 8 is a model configuration diagram assumed in a simulation calculation of the motion of the ion in the Q-TOFMS of the second embodiment. FIG. 9 is a chart showing the result of the simulation of the relationship between the push-back voltage and the travel time for ions with different mass-to-charge ratios. The period of time to apply the push-back voltage (indicated by tin FIG. 7) was set at 1.4 usec.

[0089] As described earlier, in the case where the ions are simply trapped within the inner space of the ion guide 14 before being released, the periods of time required for the travel of the ions are 8.19037 usec, 11.5829 usec, 14.1861 usec and 16.3807 usec for ions with m/z 100, m/z 200, m/z 300 and m/z 400, respectively. By comparison, when a push-back voltage of 4.2 V is applied, the periods of time required for the travel of the ions with m/z 100, m/z 200, m/z 300 and m/z 400 are 22.6295 usec, 20.0834 usec, 20.7912 usec and 22.2793 usec, respectively. Normally, the length of the area in which the ions are accelerated in the orthogonal accelerator 17 is approximately within a range from 30 mm to 40 mm. A few usec of difference in the travel time is permissible. This fact demonstrates that an appropriate setting of the push-back voltage makes it possible for a wide range of mass-to-charge ratios of the ions to be almost simultaneously introduced into the orthogonal accelerator 17 and accelerated within this orthogonal accelerator 17.

[0090] In this manner, in the Q-TOFMS of the second embodiment, not only ions having a specific mass-to-charge ratio but also ions included within a wide range of mass-to-charge ratios can be accelerated in the orthogonal accelerator 17 into the flight space 20 and subjected to a mass spectrometry. Therefore, a high-sensitivity mass spectrum covering a wide range of mass-to-charge ratios can be obtained with a single measurement.

[0091] The first and second embodiments were concerned with the case where the present invention was applied in a Q-TOFMS using an orthogonal acceleration TOFMS. The present invention can also be applied in a linear TOFMS or reflectron TOFMS using a three-dimensional quadrupole ion trap as the ion ejection source. In this case, the orthogonal accelerator 17 in the configuration of the first and second embodiments can be simply replaced by a three-dimensional quadrupole ion trap. That is to say, the system can be configured so that the ions which are released from the ion guide 14 (or collision cell 13) and pass through the ion transport optical system 16 are introduced through the ion injection opening of the three-dimensional quadrupole ion trap into the inside of the same ion trap. In this case, it is necessary to limit, to some extent, the time range in which the ions are introduced through the ion injection opening into the three-dimensional quadrupole ion trap. However, by using the configuration of the first embodiment, ions having a specific mass-to-charge ratio can be introduced into the ion trap with a high level of efficiency. Furthermore, by using the configuration of the second embodiment, ions included within a wider range of mass-to-charge ratios can be introduced into the ion trap.

[0092] It should be noted that any of the previous embodiments is an example of the present invention, and any change, modification, addition or the like appropriately made within the spirit of the present invention will evidently fall within the scope of claims of the present application.

REFERENCE SIGNS LIST

[0093] 1 . . . Chamber [0094] 2 . . . Ionization Chamber [0095] 3, 4, 5 . . . Intermediate Chamber [0096] 6 . . . High-Vacuum Chamber [0097] 7 . . . ESI Spray Device [0098] 8 . . . Heated Capillary [0099] 9 . . . Ion Guide [0100] 10 . . . Skimmer [0101] 11 . . . Ion Guide [0102] 12 . . . Quadrupole Mass Filter [0103] 13 . . . Collision Cell [0104] 132 . . . Exit Gate Electrode [0105] 14 . . . Ion Guide [0106] 15 . . . Ion Passage Opening [0107] 16 . . . Ion Transport Optical System [0108] 17 . . . Orthogonal Accelerator [0109] 171 . . . Entrance Electrode [0110] 172 . . . Pushing Electrode [0111] 173 . . . Extracting Electrode [0112] 20 . . . Flight Space [0113] 21 . . . Reflector [0114] 22 . . . Back Plate [0115] 23 . . . Ion Detector [0116] 30 . . . Controller [0117] 31 . . . Ion Guide Voltage Generator [0118] 32 . . . Exit Gate Electrode Voltage Generator [0119] 33 . . . Ion Transport Optical System Voltage Generator [0120] 34 . . . Orthogonal Accelerator Voltage Generator [0121] C . . . Ion Beam Axis