JP2756581B2 - Ion source for liquid chromatography mass spectrometer - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an ion source for a liquid chromatography mass spectrometer.

(Prior Art) A conventional ion source of this kind is shown in FIG. 3 (see Japanese Patent Publication No. Sho 62-57068). According to the figure, the liquid sample flowing out of the liquid chromatograph 1 passes through a through hole inside the hollow needle electrode 2 and is introduced into the discharge chamber 5 from the tip of the hollow needle electrode 2. On the other hand, the carrier gas 3 is provided on the outer periphery of the hollow needle electrode 2, has a narrow tip, and is jetted from a gap between the guide tube 4 having a gap between the hollow needle electrode 2 and the hollow needle electrode 2. It is discharged into the discharge chamber 5 as a flow. A high voltage is applied between the hollow needle electrode 2 and the counter electrode 6 having the ion passage port 6a by a high voltage power supply 7, and a corona discharge is generated by the high voltage. In the figure, 8 is an acceleration electrode, 9 is a ground electrode, and 10 is a gas outlet.

Therefore, in the ion source for liquid chromatography mass spectrometer, the liquid sample ejected from the tip of the hollow needle electrode 2 is first miniaturized by corona discharge. Is further refined by the jet flow of the carrier gas 3 flowing through the gap, and is vaporized by the heat of the corona discharge to promote ionization.

(Problems to be Solved by the Invention) In a conventional ion source for a liquid chromatography mass spectrometer, a liquid sample miniaturized by corona discharge is further miniaturized by a jet flow of a carrier gas 3.
The droplets of the micronized liquid sample collide with the counter electrode 6 by the jet flow of the carrier gas, and are vaporized and crystallized on the counter electrode 6, so that at the passage 6a of the counter electrode 6,
There was a problem of clogging. In addition, carrier gas 3
When the carrier gas 3 is discharged into the discharge chamber 5 when the pressure in the guide tube 4 becomes higher than that in the discharge chamber 5 due to
There is a problem that adiabatic expansion occurs, cluster ions are generated, and the performance of the ion source is reduced. Further, ions passing through the ion passage opening 6a of the counter electrode 6 are extracted by the accelerating electrode 8, but since there is no means for suppressing the diffusion of the extracted ions, there is a problem that the ion collection efficiency is deteriorated. Was.

SUMMARY OF THE INVENTION An object of the present invention is to solve the conventional problems described above, prevent clogging in an ion passage port, improve ion collection efficiency, and improve performance.

(Means for Solving the Problems) In order to achieve the above object, an ion source for a liquid chromatography mass spectrometer according to the present invention is attached to a cylindrical body and an opening at the top of the cylindrical body via an insulator. Top plate with through holes,
And an atmospheric pressure ionization chamber formed so as to be surrounded by an orifice plate with a small diameter hole attached to the opening at the bottom of the cylindrical body via an insulator, and penetrates through the through hole of the top plate with a gap kept therebetween. A hollow needle electrode through which the liquid sample flows, which is disposed coaxially with the small diameter hole of the orifice plate and whose tip faces the small diameter hole of the orifice plate in the atmospheric pressure ionization chamber at a distance, and the small diameter of the orifice plate. At least two or more gas supply pipes for ejecting hot dry gas from an ejection port directed between the hole and the tip of the hollow needle electrode; and the orifice at a side of the orifice plate opposite to the atmospheric pressure ionization chamber. A mesh-like cylindrical electrode arranged coaxially with the small diameter hole of the plate,
A skimmer having a hole disposed coaxially with a small diameter hole of the orifice plate in the vicinity of the cylindrical electrode on the side opposite to the orifice plate.

A heater is provided on the outer periphery of the cylindrical body, and the temperature in the atmospheric pressure ionization chamber is maintained at about 150 ° C.

(Operation) In the present invention, the distance between the tip of the hollow needle electrode and the small diameter hole of the orifice plate is 1 cm, the voltage applied to the hollow needle electrode is 3 to 7 Kv, and the voltage applied to the orifice plate is 60 to 65.
V, when the top plate is set to 100 V, the liquid sample ejected from the tip of the hollow needle electrode becomes positively charged fine droplets by corona discharge and flows in the direction of the small diameter hole of the orifice plate.
The high-temperature dry gas spouted from the spout of the gas supply pipe flows into the space between the small-diameter hole of the orifice plate and the tip of the hollow needle electrode, and after drying the microdroplets to generate ions,
The flow direction is changed, flows along the hollow needle electrode from the tip of the hollow needle electrode in the direction of the through hole of the top plate, and flows out of the atmospheric pressure ionization chamber through the through hole of the top plate. As a result, the solvent molecules vaporized from the microdroplets are efficiently released outside the atmospheric pressure ionization chamber. On the other hand, ions generated in the atmospheric pressure ionization chamber pass through the small-diameter hole of the orifice plate, and then pass through the mesh-like cylindrical electrode to which a voltage of 65 V is applied.
The diffusion of the particles of the ionized liquid sample is suppressed by the reticulated tubular electrode, and the particles pass through the central portion in the reticulated tubular electrode. Thereafter, the ions that have passed through the central portion of the mesh-like cylindrical electrode pass through the holes of the skimmer.

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 shows a schematic configuration of a liquid chromatography mass spectrometer using an embodiment of the present invention. In FIG. 1, 11 is a cylindrical body, 12 is a top plate, 12a is a through hole of the top plate 12, 13
Is an orifice plate, 13a is a small-diameter hole of the orifice plate 13, 14 is an atmospheric pressure ionization chamber, 15 is a hollow needle electrode, 16 is a gas supply pipe for ejecting a high-temperature dry gas, 16a is an ejection port of the gas supply pipe 16, 17 Is a mesh-shaped cylindrical electrode, 18 is a skimmer which is a cone-shaped member as shown, 18a is a hole of the skimmer 18, 19 is a heater, 20 is a first chamber, 21 is a skimmer mounting cylinder, and 22 is a skimmer. A lens system disposed in the mounting cylinder 21, 23 is a second chamber, and 24 is a mass spectrometer. Second
The figure shows an atmospheric pressure ionization ion source which is a main part of FIG. 1. In FIG. 1, a cylindrical body 11 and a through-hole attached to an opening at the top of the cylindrical body 11 through an insulator 24a are shown. An atmospheric pressure ionization chamber 14 is formed by being surrounded by a top plate 12 having a hole 12a and an orifice plate 13 having a small diameter hole 13a attached to an opening at the bottom of the cylindrical body 11 via an insulator 24b. The hollow needle electrode 15 through which the liquid sample flows is disposed coaxially with the small-diameter hole 13a of the orifice plate 13 while penetrating through the through-hole 12a of the top plate 12, and the tip thereof is located within the orifice plate 14 in the atmospheric pressure ionization chamber 14. It faces 13 small diameter holes 13a with a distance. Further, two gas supply pipes 16 for ejecting high-temperature dry gas are provided in the through holes 12 of the top plate 12.
Each penetrates the top plate 12 at the target position across the a and extends into the atmospheric pressure ionization chamber 14, bends at the tip thereof toward the axis of the hollow needle electrode 15, and the ejection port 16 a is a small-diameter hole 13 a of the orifice plate 13. And the tip of the hollow needle electrode 15. Further, the reticulated cylindrical electrode 17 is disposed on the opposite side of the orifice plate 13 from the atmospheric pressure ionization chamber 14 and coaxially with the small-diameter hole 13a of the orifice plate 13 via an insulator 24c. In the vicinity of the cylindrical electrode 17 on the side opposite to the orifice plate 13, a skimmer 18 is provided.
The hole 18a is disposed coaxially with the small-diameter hole 13a of the orifice plate 13. The heater 19 is arranged on the outer periphery of the cylindrical body 11 and heats the inside of the atmospheric pressure ionization chamber 14.

Therefore, the distance between the tip of the hollow needle electrode 15 and the small diameter hole 13a of the orifice plate 13 is set to 1 cm, the voltage applied to the hollow needle electrode 15 is 3 to 7 Kv, and the voltage applied to the orifice plate 13 is 60 to 6
When the top plate is set to 100 V and the top plate is set to 100 V, the liquid sample ejected from the tip of the hollow needle electrode 15 forms minute droplets positively charged by corona discharge and flows in the direction of the small-diameter hole 13 a of the orifice plate 13. However, the high-temperature dry gas spouted from the spout 16a of the gas supply pipe 16 flows into the space between the small-diameter hole 13a of the orifice plate 13 and the tip of the hollow needle electrode 15, and dries the microdroplets to form ions. After the generation, the flow direction is changed and the hollow needle electrode 15 is moved from the tip of the hollow needle electrode 15 in the direction of the through hole 12a of the top plate 12.
And flows out of the atmospheric pressure ionization chamber 14 through the through hole 12a of the top plate 12. As a result, the concentration of the solvent gas in the space between the tip of the hollow needle electrode 15 and the small-diameter hole 13a of the orifice plate 13 is reduced, and desolvation of cluster ions generated by corona discharge is promoted. Also, the top plate of dry gas
Along with the flow of the 12 in the direction of the through hole 12a, the solvent molecules generated by drying the microdroplets are also discharged out of the atmospheric pressure ionization chamber 14. On the other hand, ions generated in the atmospheric pressure ionization chamber 14 pass through the small-diameter hole 13a of the orifice plate 13, and
Although it passes through the reticulated tubular electrode 17 to which a voltage of 5 V is applied, diffusion of ions is suppressed by the reticulated tubular electrode 17, and passes through the central portion in the reticulated tubular electrode 17. . After that, the ions that have passed through the central portion of the reticulated cylindrical electrode 17 are
After passing through the hole 18a of the skimmer 18, it passes through the lens system 22 and enters the mass spectrometer 24. Further, when the cylindrical body 11 is heated by the heater 19 and the inside of the atmospheric pressure ionization chamber 14 is maintained at about 150 ° C., droplets of the liquid sample ejected from the tip of the hollow needle electrode 15 are promoted, and ionization is improved. become.

In the above embodiment, two gas supply pipes 16 are used, but the number may be two or more. The shape of the cylindrical body 11 is not limited to a circle, but may be a polygon such as a square.

(Effects of the Invention) According to the present invention, the following effects can be obtained.

(1) A high-temperature dry gas spouted from the spout of the gas supply pipe dries positively charged microdroplets of the liquid sample, generates ions, changes the flow direction, and changes the flow direction from the tip of the hollow needle electrode. The liquid flows along the hollow needle electrode in the direction of the through hole of the plate and flows out of the atmospheric pressure ionization chamber through the through hole of the top plate, so that the liquid sample droplet does not vaporize on the orifice plate, and the orifice The small diameter hole of the plate is not clogged. In addition, the flow of the dry gas in the atmospheric pressure ionization chamber makes it possible to completely vaporize a liquid sample of several hundred μl / min in the space between the hollow needle electrode and the orifice plate. No, it can withstand continuous use for a long time. Furthermore, the solvent molecules generated by drying the microdroplets are efficiently released outside the atmospheric pressure ionization chamber along the flow of the drying gas, thereby promoting the desolvation of the cluster ions generated by drying the microdroplets. And improve the analytical sensitivity.

(2) After the ions generated in the atmospheric pressure ionization chamber pass through the small diameter hole of the orifice plate, the diffusion of the particles of the liquid sample ionized by the reticulated cylindrical electrode is suppressed, and the center of the reticulated cylindrical electrode is reduced. Since the ions pass through the portion, the ion collection efficiency is improved, and the performance as an ion source is improved.

[Brief description of the drawings]

FIG. 1 is a schematic cross-sectional view of a liquid chromatography mass spectrometer using an embodiment of the present invention, and FIG. 2 is a cross-sectional view of an ion source for a liquid chromatography mass spectrometer according to an embodiment of the present invention. FIG. 3 is a configuration diagram of a conventional ion source for a liquid chromatography mass spectrometer. In the figure, 11: cylindrical body 12: top plate 12a: through hole of top plate 13: orifice plate 13: small diameter hole of a orifice plate 14: atmospheric pressure ionization chamber 15: hollow needle electrode 16 ... gas supply pipe 16a ... gas supply pipe spout 17 ... net-like cylindrical electrode 18 ... skimmer 18a ... skimmer hole 19 ... heater 24a ... insulator 24b ... insulator 24c ... Insulator

Claims (2)

(57) [Claims] 1. A cylindrical body, a top plate having a through hole attached to an opening at a top portion of the cylindrical body via an insulator, and a top plate with a through hole attached to an opening at a bottom portion of the tubular body via an insulator. An atmospheric pressure ionization chamber formed so as to be surrounded by an orifice plate with a small-diameter hole, and a through-hole of the top plate are arranged coaxially with the small-diameter hole of the orifice plate while penetrating the top plate with a gap therebetween. A hollow needle electrode through which a liquid sample flows at a distance from the small-diameter hole of the orifice plate in the atmospheric pressure ionization chamber, and a jet port directed between the small-diameter hole of the orifice plate and the tip of the hollow needle electrode. At least two or more gas supply pipes for injecting a high-temperature dry gas, and a mesh-like cylindrical electrode disposed coaxially with the small-diameter hole of the orifice plate on the side of the orifice plate opposite to the atmospheric pressure ionization chamber. And near the opposite side of the cylindrical electrode from the orifice plate. In liquid ion source for chromatography mass spectrometer, characterized in that a skimmer with a small-diameter hole and the hole disposed coaxially of the orifice plate. 2. The ion source for a liquid chromatography mass spectrometer according to claim 1, wherein a heater is provided on the outer periphery of the cylindrical body.