The present application claims priority from Japanese patent application JP 2011-141388 filed on Jun. 27, 2011, the content of which is hereby incorporated by reference into this application.
The present invention relates to a mass spectrometer and a method of operating the same.
In a mass spectrometer, there are a number of methods of transporting liquid and solid samples to an ionization source. Above all, an explanation will be given as follows of sample introduction using a probe of introducing a sample directly to an ionization source or a vicinity thereof.
US 2010/0243884 A1 describes a method of introducing a probe holding a sample to a sample vaporizing chamber at a vicinity of an ionization source under a reduced pressure. According to the method, a sample is vaporized by heating the probe, and a sample gas is introduced to the ionization source by making a gas flow from the sample vaporizing chamber in a direction to the ionization source. The sample gas is ionized at the ionization source by an ion-attachment ionization or the like, and generated ions are introduced into a mass analyzer by an electric field.
Japanese Unexamined Patent Application Publication No. Hei10 (1998)-69876 describes a small heating sample probe for directly introducing a sample to an ionization source for electron ionization (EI). The probe has a metal wire at a tip end thereof, sampling is carried out by adsorbing the sample to the wire, and the sample is heated to vaporize by applying a voltage on the wire. After introducing the probe into a vacuumed chamber (10−3 through 10−4 Pa), a sample gas can be ionized by EI.
Analytical Chemistry, 2005, 77, 7826-7831 describes an atmospheric pressure solids analysis probe for introducing a sample directly to an ionization source for an atmospheric pressure chemical ionization (APCI). A sample is coated onto a tip end of a melting point capillary made of borosilicate and is inserted into a space where APCI is performed. The sample is gasified by blowing a high temperature gas to a sample coating portion, and a sample gas is ionized by a plasma generated by corona discharge. Generated ions pass through an orifice and are conveyed to a mass analyzer.
According to a configuration described in US 2010/0243884 A1, a preparatory exhaust chamber is needed between the sample vaporizing chamber and the atmosphere for introducing the probe from a side of the atmosphere to the sample vaporizing chamber, a structure thereof becomes complicated, and therefore, the configuration is disadvantageous for downsizing. Moreover, an ion loss in a transfer line is brought about when the sample gas moves from the sample vaporizing chamber the ionization source, which gives rise to a deterioration in a sensitivity.
In the EI ionization source described in Japanese Unexamined Patent Application Publication No. Hei10 (1998)-69876, the sample is ionized by impacting high energy electrons to the sample under high vacuum (about 10−4 Pa). Therefore, fragmentation of the sample by the impact is conspicuous. The fragmentation complicates a mass spectrum obtained and makes an analysis difficult. In a case of a highly volatile sample, the sample is vaporized at a time point of introducing the probe into vacuum, and the measurement cannot be performed.
The probe described in Analytical Chemistry, 2005, 77, 7826-7831 is a probe used in APCI. Generated ions are conveyed from under the atmospheric pressure to the mass analyzer which is a high vacuum area by passing through a small orifice or a capillary having a small conductance. Therefore, ions are lost in passing through the orifice or the capillary to bring about a deterioration in a sensitivity. Moreover, the sample is vaporized by blowing the heated gas to the probe, and therefore, the sample gas is diffused. There is a possibility that only a portion of the sample gas is ionized. A gas flow does not flow to the mass analyzer. Therefore, there is a possibility that only a portion of generated ions are taken into the mass analyzer. Therefore, it seems that an amount of ions subjected to mass analysis is small as opposed to an amount of the sample.
As described above, the deterioration in the sensitivity is brought about by diffusion of the gas in a procedure of vaporizing and ionizing the sample, or an ion loss by hitting ions on the surface of a transfer line in a procedure of introducing the ions to the mass analyzer. There poses a problem that mass spectra become complicated by the fragmentation of the sample. There also poses a problem by a deterioration in a throughput owing to a complication in interchanging the sample.
According to an example of a mass spectrometer for resolving the problem described above, there is provided a mass spectrometer including a sample attaching member of attaching a sample, an ionizing chamber including an introductory port of the sample attaching member and an ionization source of generating a sample ion of the sample, a vacuumed chamber including a mass analyzer of analyzing the sample ion, and an opening/closing mechanism provided between the ionizing chamber and the vacuumed chamber, in which the opening/closing mechanism is controlled from a closed state to an open state after introducing the sample attaching member into the ionizing chamber.
As an example of a mass analyzing method, there is provided a mass analyzing method which is a mass analyzing method using an ionizing chamber including an introductory port of a sample attaching member of attaching a sample and an ionization source, a vacuumed chamber including an introductory port of an ion of the sample and a mass analyzer, and an opening/closing mechanism provided between the ionizing chamber and the vacuumed chamber, the mass analyzing method including a step of reducing a pressure of the vacuumed chamber to be equal to or lower than 0.1 Pa in a state of closing the opening/closing mechanism, a step of introducing the sample attaching member arranged with the sample to the ionizing chamber, a step of making a pressure of the ionizing chamber equal to or higher than 100 Pa and equal to or lower than 5000 Pa by bringing the opening/closing mechanism to an open state after introducing the sample attaching member, a step of generating the sample ion of the sample arranged at the sample attaching member by driving the ionization source, and a step of analyzing a mass of the sample ion introduced from the ionizing chamber to the vacuumed chamber by the mass analyzer.
According to the present invention, ionization with inconsiderable fragmentation can be carried out at a high sensitivity with a high throughput.
A sample introduction probe 6, having a resistance heating filament 100 at a tip end thereof, and to which the current can be made to flow from outside, is inserted into the ionization source 1. Here is exemplified a mode of inserting the sample introduction probe 6 having a handle to the cylindrical ionization source 1. The tip end of the sample introduction probe 6 is attached with the resistance heating filament 100. There is a cap for closing the ionization source 1 in a state of inserting the sample introduction probe 6 to the ionization source 1. Molybdenum, tungsten, tantalum, etc. can be used for the resistance heating filament 100. The resistance heating filament 100 is attached with a sample 7. Before inserting the sample introduction probe 6 to the ionization source 1, the resistance heating filament 100 is directly coated with a sample. Or, the resistance heating filament 100 is adhered with an adsorbent (filter paper, PDMS, other porous material etc.) that is adsorbed with the sample. The sample 7 is heated by heating the resistance heating filament 100 by supplying an electric power of about 1 through 20 W from a heating power source 50, and the sample 7 is gasified at inside of the ionization source 1. As the sample, a sample of a solid of a powder or the like, a liquid, or a gas can be adsorbed. The larger the power applied on the resistance heating filament 100, the higher the temperature of the resistance heating filament 1, and the more easily the sample 7 is gasified. On the other hand, when a necessary power is small, the mass spectrometer can be driven by a battery and the mass spectrometer can be carried.
A first discharge electrode 8 and a second discharge electrode 9 are arranged at a pipe that is provided by being connected to the ionization source 1 to be, for example, orthogonal to the sample introduction probe 6. Dielectric barrier discharge is generated by applying a voltage therebetween, and a discharge produced plasma 10 is generated. Charged particles are generated by a discharge produced plasma 10, water cluster ions are generated on the basis of the charged particles, and the sample 7 is ionized by ion-molecule interaction of the water cluster ions and the sample gas. The method is soft ionization using the discharge produced plasma, and an amount of fragmentation of sample ions is small in comparison with an EI ion source having a large amount of fragmentation as shown in Japanese Unexamined Patent Application Publication No. Hei10 (1998)-69876. In a case of intending to bring about fragmentation, a power applied on the discharge electrode may be increased as described below. The sample ions generated by the discharge produced plasma 10 are introduced to the vacuumed chamber 3 by passing through an orifice 13 by opening the valve 4. A mass analyzer 11 and a detector 12 are installed in the vacuumed chamber 3. The introduced ions are isolated for respective m/z by the mass analyzer 11 of a quadrupole mass filter, an ion trap, a time-of-flight mass spectrometer, etc., and detected by the detector 12 of an electron multiplier, etc.
There is no restriction in the shape of the resistance heating filament 100 at the tip end of the sample probe, and various shaped are conceivable as shown in
The sample introduction probe 6 may be inserted to any place in the ionization source that generates the discharge produced plasma 10. However, a conductance in the ionization source is large to a degree by which a pressure in the ionization source at any space substantially stays the same. Substantially the same mentioned here signifies that a difference in the pressure in the ionization source is to a degree of doubling the pressure. For example, in
When the sample introduction probe 6 is inserted to the ionization source 1 and the sample 7 is ionized, the valve 4 is brought into an open state. The vacuumed chamber 3 is maintained at a pressure equal to or lower than 0.1 Pa. The pressure of the ionization source 1 is determined by an exhaust rate of the pump 2, a conductance of the orifice 13, and a conductance of a gas introducing slender pipe 14 provided to be connected to the ionization source on a side opposed to the vacuumed chamber 3 relative to the sample 7. The nearer the pressure of the ionization source 1 to the pressure of the vacuumed chamber 3, the more the loss in introducing ions from the ionization source 1 to the vacuumed chamber 3 is reduced. Therefore, a sensitivity of the mass spectrometer is increased when the ionization is performed under a reduced pressure more than when the ionization is performed under the atmospheric pressure. On the other hand, there is present a pressure range of generating the discharge produced plasma 10 stably, and a typical value thereof falls in a range of 100 through 5000 Pa. Also, a pressure range in which the ionization can be performed efficiently falls in a range of 500 through 3000 Pa. When the pressure is below 500 Pa, fragmentation of ions is intensified. Also, the plasma is not generated at the pressure equal to or lower than 1 Pa. An ionization source of an EI ionization source as shown in Japanese Unexamined Patent Application Publication No. Hei10 (1998)-69876 is maintained at a pressure of about 10−4 Pa. Therefore, when the sample is introduced into the ionization source, the sample is volatilized. According to the present method, the ionization source 1 is maintained at the pressure equal to or higher than 100 Pa in order to stably generate the discharge produced plasma 10, and the sample is difficult to be evaporated.
A pressure at outside of the ionization source 1 is higher than that of the ionization source 1 or is the atmospheric pressure. A gas flow is produced from the gas introducing slender pipe 14 to the vacuumed chamber 3 by a difference between the pressure at inside of the ionization source 1 and the vacuumed chamber 3 and the pressure at outside of the ionization source 1. The sample ions are efficiently transported into the vacuumed chamber 3 by the gas flow. Adsorption of the sample to an inner wall of the ionization source 1 is reduced owing to the presence of the gas flow. Not only a deterioration in a sensitivity by loss of the sample but also carry-over of the sample to successive measurement can be prevented by reducing the adsorption.
As the valve 4, for example, a pinch valve, a slider valve, a ball valve etc. is used. The gas introducing slender pipe 14 may be an orifice when the orifice is operated as a necessary conductance. When outside of the ionization source 1 is the atmosphere, air is made to flow in from the gas introducing slender pipe 14 into the ionization source. On the other hand, a specific gas of a rare gas etc. of He or the like may be introduced from the gas introducing slender pipe 14. In Analytical Chemistry, 2005, 77, 7826-7831, only the high temperature gas is blown to the probe holding the sample, and diffusion of the generated sample gas is not controlled. On the other hand, according to the present method, there is generated the gas flow directed to the mass analyzer in the ionization source. The sample gas is not considerably diffused but is introduced efficiently into the vacuumed chamber 3 after having been ionized by the discharge produced plasma 10. Also ions are borne on the flow of the gas under a pressure region equal to or higher than 100 Pa. In US 2010/0243884 A1, generated ions are conveyed to the mass analyzer by an electric field. The direction of the electric field is a direction orthogonal to the gas flow by which the sample gas is transported. There also exist ions which progress not along the electric field but a gas flow and the sensitivity is lowered. According to the structure proposed by the present invention, in comparison with the structure of Analytical Chemistry, 2005, 77, 7826-7831, the gas flow transports ions to the vacuumed chamber 3 where the mass analyzer is present, and therefore, generated ions can be introduced wastelessly.
As a positional relationship among the sample introduction probe 6, the discharge produced plasma 10, and the gas introducing slender pipe 14, various patterns are conceivable so far as the positional relationship is a relationship by which the gas introduced from outside can transport the gas sample efficiently to the vacuumed chamber 3. Examples thereof are shown in
A distance between the first discharge electrode 8 and the second discharge electrode 9 is typically about 5 mm. The longer the distance between the discharge electrodes, the higher the power necessary for discharge. For example, an alternating current voltage is applied on one of the discharge electrodes from a power source 51, and a DC voltage is applied to the other discharge electrode. The applied alternating current voltage may be of a rectangular wave or a sine wave. As a typical example, the applied voltage falls in a range of 0.5 through 10 kV and its frequency falls in a range of about 1 through 100 kHz. A density of the discharge produced plasma 10 is increased by using the rectangular wave when a voltage amplitude stays the same. On the other hand, in the sine wave, in a case of a high frequency, the voltage can be stepped up by a coil. Therefore, the sine wave achieves an advantage that the power source 51 is more inexpensive than in a case of using the rectangular wave. The higher the voltage and the frequency, the higher the inputted power, and therefore, the higher the density of the discharge produced plasma 10. However, when the inputted power is excessively high, a temperature of the plasma becomes high and fragmentation is liable to be brought about. The frequency or the voltage of the alternating current voltage may be changed for each sample or ion that is an object of measurement. For example, the inputted power is increased in a case of measuring a molecule which is difficult to be subjected to fragmentation as in an inorganic ion or in a case of intending to subject an object ion to fragmentation and measuring a fragment ion, and the inputted power is reduced in a case of measuring a molecule which is easy to be subjected to fragmentation. Power consumption of the power source 51 can be reduced when switching is carried out so as to apply the voltage on the discharge electrode only when needed.
The arrangement of the discharge electrodes can variously be changed so far as discharge is performed via a dielectric substance.
Simultaneously therewith, the discharge produced plasma 10 is generated and the sample gas is ionized. Generated ions are efficiently introduced into the vacuumed chamber 3 by a gas flowing in from the gas introducing slender pipe 14, and are isolated for respective m/z. After the measurement has been finished, the valve 4 is closed and the sample introduction probe 6 is detached from the ionization source 1. The resistance heating filament 100 is interchanged to a new one in order to prevent carry-over to measurement of a successive sample. Thereby, a successive one of the sample 7 is installed at the resistance heating filament 100 and new measurement is started. The sample introduction probe 6 attached with the next sample 7 may be prepared.
In US 2010/0243884 A1, it is necessary to take out a total of the sample introduction probe from the sample vaporizing chamber in order to interchange the samples. A preparatory exhausting chamber having two valves is needed between the sample vaporizing chamber and the atmosphere in order to maintain pressures of the mass analyzer, the ionization source, and the sample vaporizing chamber. Therefore, a structure thereof is complicated and large-sized. On the other hand, according to the structure of the present invention, the valve 4 is present between the ionization source 1 and the vacuumed chamber 3. The pressure in the ionization source 1 is increased by closing the valve 4, and the sample introduction probe 6 can simply be taken out. Therefore, the structure of the present invention is simpler than that of US 2010/0243884 A1 and is suitable also for downsizing. In a case where not only the preparatory exhausting chamber but the valve 4 is not present, the pressure in the vacuumed chamber needs to increase for interchanging the sample. It is necessary await for reducing the pressure in the vacuumed chamber after inserting the sample probe to the ionization source in order to measure the successive sample, and the throughput is deteriorated. Therefore, the valve 4 is a configuration which is significant in carrying out the measurement with high throughput.
As shown by the result, a time period taken from evaporation to ionization of one sample is several seconds, and it is known that the measurement can be performed with high throughput.
When the sample gas passes through the plasma area, the sample gas is ionized more efficiently than in a case where the sample gas does not pass through the plasma area. On the other hand, the sample gas is easy to be subjected to fragmentation. The fragmentation is alleviated when a flow rate of the gas passing through the plasma area is increased. The structure of the ionization source 1 becomes simple and easy to be downsized by making the plasma area coaxial with the sample introduction probe 6. The measurement flow is similar to that of
Charged droplets are generated by injecting a solution from the probe 60 for electrospray ionization connected with a pump 70 for feeding the solution. Ions generated from the charged droplets are impacted to the sample 7 installed at the tip end of the sample introduction probe 6, and sample ions are generated. The sample ions are introduced to the vacuumed chamber 3 by a gas flow. Or, the sample is vaporized by the resistance heating filament 100 or the high temperature gas, and the charged droplets are injected to the vaporized sample. The vaporized sample is taken into the charged liquid drops, and ionized by the principle of electrospray. The sample ions are introduced to the vacuumed chamber 3 by the gas flow. The loss in introducing ions from the ionization source to the vacuumed chamber is reduced and the sensitivity is increased by ionizing the sample under a reduced pressure similar to the other embodiments. On the other hand, when the pressure is excessively low, thermal energy cannot be given from the surrounding gas to the charged droplets, and the charged droplets cannot be broken and evaporated to thereby reduce an ionization efficiency. Therefore, the pressure in the ionization source is made to be able to maintain both of the ionization efficiency and the efficiency of introducing ions to the vacuum chamber 3 at high levels. Specifically, the pressure preferably falls in a range of 100 through 5000 Pa.
Although in the discharge produced plasma, a sample is gasified and thereafter ionized, a high mass molecule is difficult to be volatilized and therefore, the molecule is difficult to be ionized. On the other hand, according to the electrospray ionization method shown in the present embodiment, the sample can be ionized directly from a solution state. Therefore, even the high mass molecule can easily be ionized. Therefore, the method is effective when the object of the measurement is protein, peptide, or polysaccharide. On the other hand, there is needed the pump 70 for feeding the solution for generating the charged droplets to the probe 60 for electrospray ionization, and a structure thereof becomes complicated. In order to stably generate the charged droplets, an inert gas of nitrogen or the like may be introduced as an auxiliary gas in a shape of a concentric circle of an injection port of the probe 60 for electrospray ionization. Although in
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