阅读说明：本技术 带电粒子线装置 (Charged particle beam device ) 是由 中野朝则 山泽雄 鹿岛秀夫 于 2019-04-19 设计创作，主要内容包括：提供具有能修正色像差的绕组像差修正器的带电粒子线装置。多极透镜具有：磁性体芯(150)；多个电流线(101)～(112)；丝状的多个电极(301)～(312)；用于将多个电极固定于真空容器内的结构物的绝缘性的电极固定部(331)～(342)；和设于电极固定部与磁性体芯的中心轴之间且设为基准电位的导电性的屏蔽件(320)、(321),多个电流线的主线部沿着磁性体芯的内壁相对于磁性体芯的中心轴而轴对称地配置,多个电极中的与磁性体芯的中心轴平行的部分相对于磁性体芯的中心轴而轴对称地配置。(Provided is a charged particle beam device having a winding aberration corrector capable of correcting chromatic aberration. The multipole lens has: a magnetic core (150); a plurality of current lines (101) - (112); a plurality of filamentous electrodes (301) to (312); insulating electrode fixing portions (331) to (342) for fixing the plurality of electrodes to a structure in the vacuum container; and conductive shields (320, 321) provided between the electrode fixing section and the center axis of the magnetic core and having a reference potential, wherein main line sections of the plurality of current lines are arranged along the inner wall of the magnetic core so as to be axisymmetric with respect to the center axis of the magnetic core, and portions of the plurality of electrodes parallel to the center axis of the magnetic core are arranged so as to be axisymmetric with respect to the center axis of the magnetic core.)

1. A charged particle beam device is characterized by comprising:

an electron gun for emitting the electron beam 1 time;

an aberration corrector having a multi-stage multipole lens to which the 1 st-order electron beam is incident;

an objective lens of the 1 st order electron beam incident through the aberration corrector; and

a vacuum container for accommodating the electron gun, the aberration corrector, and the objective lens,

the multipole lens has: a magnetic body core; a plurality of current lines; a plurality of electrodes in the form of filaments; an insulating electrode fixing portion for fixing the plurality of electrodes to a structure in the vacuum chamber; and a conductive shield provided between the electrode fixing portion and the central axis of the magnetic core and having a reference potential,

the main line portions of the plurality of current lines are arranged along the inner wall of the magnetic core so as to be axisymmetrical with respect to the central axis of the magnetic core,

the plurality of electrodes are arranged so that portions extending along the center axis of the magnetic core are axisymmetrically arranged with respect to the center axis of the magnetic core.

2. Charged particle beam apparatus according to claim 1,

the number of the plurality of current lines is equal to the number of the plurality of electrodes.

3. Charged particle beam apparatus according to claim 1,

the magnetic core has a plurality of slots formed in an inner wall thereof, centers of the plurality of slots are arranged in an axisymmetric manner with respect to a central axis of the magnetic core, and main line portions of the plurality of current lines are arranged in any one of the plurality of slots of the magnetic core.

4. Charged particle beam apparatus according to claim 3,

the plurality of electrodes includes a 1 st electrode and a 2 nd electrode,

on a plane formed by the centers of the grooves facing each other with the center axis of the magnetic core interposed therebetween, a portion of the 1 st electrode parallel to the center axis of the magnetic core and a portion of the 2 nd electrode parallel to the center axis of the magnetic core are arranged symmetrically with respect to the center axis of the magnetic core.

5. Charged particle beam apparatus according to claim 1,

the shield is a cylindrical member disposed so that a central axis of the shield coincides with a central axis of the magnetic core,

the shield is disposed so that an end of the shield coincides with an end of the magnetic body core, or so that an end of the shield is opposed to an inner wall of the magnetic body core.

6. Charged particle beam apparatus according to claim 3,

the current line has a connection portion for introducing the main line portion from the outside of the magnetic core into the slot or for leading the main line portion from the slot to the outside of the magnetic core,

a nonmagnetic spacer is disposed between the connection portion of the current line and the magnetic core.

7. Charged particle beam apparatus according to claim 3,

the current line has a connection portion for introducing the main line portion from the outside of the magnetic core into the slot or for leading the main line portion from the slot to the outside of the magnetic core,

a magnetic body cover facing the longitudinal direction of the groove of the magnetic body core,

the connection portion of the current line is disposed in a through hole provided between the magnetic body core and the magnetic body cover.

8. Charged particle beam apparatus according to claim 1,

the aberration corrector has the multipole lens of 4 stages,

either a magnetic field or an electric field is excited in the multipole lenses of the 1 st and 4 th stages, and a magnetic field and an electric field are excited in the multipole lenses of the 2 nd and 3 rd stages.

Technical Field

The present invention relates to a charged particle beam application technique, and more particularly to a charged particle beam device such as a scanning electron microscope and a transmission electron microscope equipped with an aberration corrector.

Background

In charged particle beam devices represented by Scanning Electron Microscopes (SEM) and Scanning Transmission Electron Microscopes (STEM), an aberration corrector is introduced to improve resolution. As one of the types of aberration corrector, there is the following aberration corrector: the multipole lens is configured by multipole lenses arranged in multiple stages, and is configured to generate an electric field or a magnetic field to combine a plurality of multipole fields, thereby removing aberrations included in charged particle beams passing through the multipole lenses. Patent document 1 discloses a winding-type aberration corrector that generates a multipole field using magnetic fields from a plurality of current lines.

Documents of the prior art

Patent document

Patent document 1: JP 2009-54581 publication

Disclosure of Invention

Problems to be solved by the invention

In patent document 1, a relatively inexpensive aberration corrector of a multipole correction system can be realized by forming a multipole field using a current line, but high mechanical positional accuracy is required, and in this case, high positional accuracy is required for the arrangement of the current line.

The requirement for high positional accuracy is alleviated by providing the multipole lens with a magnetic core, providing a plurality of grooves for arranging main line portions of current lines on an inner wall of the magnetic core, and forming the plurality of grooves such that centers of the plurality of grooves are arranged axisymmetrically with respect to a central axis of the magnetic core. According to this configuration, by accurately forming the center position of the slot of the magnetic core in the circumferential direction and the radial direction, the influence of the displacement of the current line in the slot on the magnetic field intensity generated by the multipole lens can be substantially eliminated.

Aberration is one of aberrations of electron lenses used in an electron microscope, but in order to correct chromatic aberration for higher resolution of an electron microscope, it is necessary to excite an electric field in addition to a magnetic field. Therefore, in an aberration corrector using a multipole lens using a current line (referred to as a "winding aberration corrector"), an excitation electric field is required, and an electrode for exciting the electric field needs to be arranged in the multipole lens.

Means for solving the problems

A charged particle beam device according to one embodiment includes: an electron gun for emitting the electron beam 1 time; an aberration corrector having a multi-stage multipole lens to which the 1 st-order electron beam is incident; an objective lens of 1-time electron beam incident through the aberration corrector; and a vacuum container for accommodating the electron gun, the aberration corrector and the objective lens, wherein the multipole lens comprises: a magnetic body core; a plurality of current lines; a plurality of electrodes in the form of filaments; an insulating electrode fixing portion for fixing the plurality of electrodes to a structure in the vacuum container; and a conductive shield provided between the electrode fixing portion and a central axis of the magnetic core and having a reference potential, wherein main line portions of the plurality of current lines are arranged along an inner wall of the magnetic core so as to be axisymmetric with respect to the central axis of the magnetic core, and portions of the plurality of electrodes parallel to the central axis of the magnetic core are arranged so as to be axisymmetric with respect to the central axis of the magnetic core.

ADVANTAGEOUS EFFECTS OF INVENTION

Provided is a charged particle beam device having a winding aberration corrector capable of correcting chromatic aberration.

Other objects and novel features will become apparent from the technology of this specification and the accompanying drawings.

Drawings

Fig. 1A is an overview cross-sectional view (schematic) of a multipole lens.

Fig. 1B is a top view (schematic) of a multipole lens.

Fig. 1C is an overview (schematic view) of the center position of the groove provided in the magnetic core.

Fig. 2 is an overview (schematic) of the current lines.

Fig. 3 is a diagram showing a structure of a multipole lens capable of superimposing electric fields.

Fig. 4 is a diagram showing a structure of a multipole lens capable of superimposing electric fields.

Fig. 5 shows an example of a multipole lens in which a nonmagnetic spacer is provided on a magnetic core.

Fig. 6 is an overview sectional view of the magnetic body core.

Fig. 7 shows an example of the structure of the electronic device.

Fig. 8A is an electron optical diagram showing a trajectory of an electron beam passing through the winding aberration corrector.

Fig. 8B is an electron optical diagram showing the trajectory of the electron beam passing through the winding aberration corrector.

Detailed Description

The winding aberration corrector is configured to have a multi-stage multi-pole lens. The multipole lens according to the present embodiment has a structure in which a current line for generating a magnetic field is disposed in a groove provided in the inner wall of a magnetic core. The arrangement of the magnetic cores and the current lines for generating a magnetic field in the multipole lens according to the present embodiment will be described with reference to fig. 1A to 1C. Fig. 1A is an overview cross-sectional view (schematic view) of a multipole lens corresponding to stage 1 of the winding aberration corrector, fig. 1B is a top view (schematic view) of a multipole lens corresponding to stage 1 of the winding aberration corrector, and fig. 1C is an overview (schematic view) of a center position of a groove provided in a magnetic core. The magnetic core 150 is made of a magnetic material such as pure iron or permalloy, has a cylindrical shape, and has grooves 151 to 162 extending in the Z direction on its inner wall. As shown in fig. 1C, the center positions 151a to 162a of the respective grooves are provided axisymmetrically with respect to the central axis 150a of the magnetic core 150. That is, the center position 151a of the groove 151 and the center position 157a of the groove 157 are arranged so as to be axisymmetric on the same plane with respect to the central axis 150 a. The same applies to the groove center position 152a and the groove center position 158a, the groove center position 153a and the groove center position 159a, the groove center position 154a and the groove center position 160a, the groove center position 155a and the groove center position 161a, the groove center position 156a, and the groove center position 162a, respectively. In addition, in this example, 12 slots are provided, but the number of slots is not limited. When the number of the grooves is k, the angle between the adjacent grooves is an angle (360 °/k) divided by the number of the grooves k, with the central axis 150a of the magnetic core 150 as a rotation axis.

The main line portions of the current lines 101 to 112 are disposed in grooves 151 to 162 provided in the magnetic core 150, respectively. FIG. 2 shows only the current lines 101 to 112 as an overview (schematic view). 12 current lines including the current line 101 to the current line 112 are arranged around the optical axis 100 of the charged particle beam. The optical axis 100 of the charged particle beam coincides with the central axis 150a of the magnetic core 150.

The structure of the current line will be described by taking the current line 101 shown in fig. 1A as an example. The current line 101 has a rectangular circuit shape, and is supplied with current from a power supply not shown. The arrows marked on the current lines indicate the direction of the current flowing through the current lines. Hereinafter, as shown in fig. 1A, the current line is divided into 4 sections corresponding to the sides of the quadrangle, and these sections are referred to as a main line section 121, a connection section 122, a connection section 123, and a return line section 124. The main line portion 121 is a portion of the current line disposed in the groove of the magnetic core, the connection portions 122 and 123 are portions for introducing the main line portion 121 into the groove from the outside of the magnetic core or for leading the main line portion 121 out of the groove to the outside of the magnetic core, and the return line portion 124 is a portion of the current line disposed outside the magnetic core.

The multipole field is formed by a magnetic field from the main line portion. In the winding lens (multipole lens) shown in fig. 2, the power supply is omitted, but a current needs to be passed with a specific distribution in the excitation of the multipole field. For example, as one combination for exciting a 2N pole field (N is an integer of 1 or more), I represents a current applied to each of the current lines 101 to 112₁～I₁₂Then obtain the reference current A_NThe combination of the current values obtained by (equation 1).

[ mathematical formula 1]

I_i＝A_NCos (N (i-1) pi/6. cndot. (equation 1)

(equation 1) represents the current distribution for exciting a single multipole field. In this case, the current lines 101 to 112 are connected to different power supplies, respectively.

In a conventional winding lens without a magnetic core, the main wire portion and the return wire portion have opposite current flows, and therefore the multipole field generated by the return wire portion has a function of reducing the multipole field generated by the main wire portion. In contrast, in the winding lens of the present embodiment, the magnetic core 150 is disposed between the main line portion 121 and the return line portion 124, and thus the magnetic core functions as a magnetic shield, and the return line portion does not affect the multipole field generated by the main line portion.

In the case of the multipole lens according to the present embodiment, the intensity of the magnetic field to be excited is hardly affected by the positional accuracy of the main line portion of the current line arranged in the groove of the magnetic core. In a conventional winding aberration corrector not using a magnetic core, high accuracy is required for the arrangement position of a current line in order to generate a desired magnetic field. In contrast, in the winding aberration corrector of the present embodiment, if the center position of the slot of the magnetic core is accurately formed in the circumferential direction and the radial direction, the deviation of the arrangement position of the current line in the slot hardly affects the magnetic field intensity generated by the multipole lens, which is a very advantageous feature when actually forming the multipole lens to construct the aberration corrector.

A multipole lens in which electrodes are arranged to excite an electric field so as to overlap a magnetic field excited by a current line will be described with reference to fig. 3 and 4. Fig. 3 is a sectional view of a multipole lens. The sectional view of fig. 3 is a sectional view in a plane including the optical axis 100 (central axis 150 a). Fig. 4 shows cross-sectional views 391, 392, 393 taken along lines a-a, B-B, and C-C shown in fig. 3. That is, the sectional view of fig. 4 is a sectional view in a plane perpendicular to the optical axis 100 (central axis 150 a).

The electrodes 301 to 312 excited by an electric field have filament (wire) shapes, and a desired electric field is generated by applying a predetermined voltage to each of the electrodes 301 to 312. Here, the structure of the vacuum vessel 350 in which the winding aberration corrector is disposed is held at the reference potential (GND). Therefore, the electrodes 301 to 312 are insulated from the surrounding structure by the electrode fixing portions 331 to 342, respectively, and are fixed in position. For example, the electrode fixing portion is an insulating member having a groove formed on a surface thereof for fixing the electrode. In this example, the electrode fixing portions 331 to 342 are provided on a vacuum barrier 351 for keeping a region through which the optical axis 100 passes in vacuum and for setting a region where the magnetic core 150 is disposed to, for example, atmospheric pressure. For example, the electrode 301 is fixed by a 1 st electrode fixing portion 331a provided on the upper side (on the electron source side) and a 2 nd electrode fixing portion 331b provided on the lower side (on the sample side). In this example, the electrode fixing portions 331 to 342 are provided for each electrode, but for example, a single insulating member may be provided on each of the vacuum partition walls 351 located above and below the magnetic core 150, and a groove for disposing an electrode may be provided in the insulating member to fix the position of the electrode. The vacuum partition wall 351 provided with the electrode fixing portion is an example, and may be a structure in another vacuum container.

For aberration correction, high positional accuracy is required for the electrodes 301 to 312. Specifically, it is necessary that the distance ∈ from the optical axis 100 (central axis 150a) of the electrode (portion parallel to the optical axis 100) and the angle θ formed by adjacent electrodes viewed from the optical axis 100 (central axis 150a) be equal to each other. In this example, 12 electrodes are provided, and the number of slots of the magnetic core 150 is equal to the number of the slots, but may not be equal to the number of the slots (or the number of current lines). When the number of electrodes is j, the angle between adjacent electrodes is an angle (360 °/j) divided by the number of electrodes j, with the optical axis 100 (the central axis 150a of the magnetic core 150) as the rotation axis.

In this example, the number of electrodes and the number of slots of the magnetic core are made equal, and the electrodes are arranged so as to correspond to the slots of the magnetic core. That is, on a plane formed by the centers of the grooves facing each other with the center axis 150a of the magnetic core interposed therebetween, a portion parallel to the center axis of the magnetic core in one of the electrodes and a portion parallel to the center axis of the magnetic core in the other electrode are arranged symmetrically with respect to the center axis of the magnetic core. Specifically, on a plane formed by the center position 151a of the groove 151 and the center position 157a of the groove 157, the electrodes 301 and 307 are disposed so as to be symmetrical with respect to the optical axis 100 (the center axis 150a), on a plane formed by the center position 152a of the groove 152 and the center position 158a of the groove 158, the electrodes 302 and 308 are disposed so as to be symmetrical with respect to the optical axis 100 (the center axis 150a), on a plane formed by the center position 153a of the groove 153 and the center position 159a of the groove 159, the electrodes 303 and 309 are disposed so as to be symmetrical with respect to the optical axis 100 (the center axis 150a), on a plane formed by the center position 154a of the groove 154 and the center position 160a of the groove 160, the electrodes 304 and 310 are disposed so as to be symmetrical with respect to the optical axis 100 (the center axis 150a), on a plane formed by the center position 155a of the groove 155 and the center position 161a of the groove 161, the electrodes 305 and 311 are disposed symmetrically with respect to the optical axis 100 (the central axis 150a), and the electrodes 306 and 312 are disposed symmetrically with respect to the optical axis 100 (the central axis 150a) on a plane formed by the central position 156a of the groove 156 and the central position 162a of the groove 162.

Since the electric field excited by the electrodes 301 to 312 depends on the magnetic field excited by the multipole lens, the magnitude of the voltage applied to the electrodes 301 to 312 depends on the magnitude of the current flowing through the current lines 101 to 112 constituting the multipole lens. Therefore, by making the number of electrodes equal to the number of slots of the magnetic core and arranging the electrodes corresponding to the slots of the magnetic core as in the present embodiment, the control of the winding aberration corrector can be facilitated. However, even when the number and arrangement are different, the winding aberration corrector can be controlled by controlling the voltage applied to the electrodes or the current flowing through the current lines so as to interpolate the positional deviation between the position where the magnetic field is generated and the position where the electric field is generated.

In addition, in the present embodiment, the 1 st shield 320 is provided above the magnetic body core, and the 2 nd shield 321 is provided below. The shields 320 and 321 are conductive cylindrical members provided so as to surround the optical axis 100 (the central axis 150a), and are arranged so that the central axis of the shield coincides with the optical axis 100 (the central axis 150 a). The potential of the shields 320, 321 is set to the reference potential. For example, the shields 320 and 321 can be positioned and the reference potential can be applied by fixing the shields 320 and 321 to the structure of the vacuum chamber 350 at the reference potential.

One of the roles of the shields 320, 321 is that since insulating members (electrode fixing portions 331 to 342) are disposed in the vicinity of the optical axis 100, these insulating members are hidden from the electron beam. By disposing the shields 320, 321 set at the reference potential between the optical axis 100 and the insulating member, the electron beam is not adversely affected even when the insulating member is charged.

Another function of the shields 320, 321 is to align the region acted upon by the magnetic field based on the current lines and the electric field based on the electrodes. Therefore, the lower surface of the 1 st shield 320 is desirably located at the same height as the upper surface of the magnetic body core 150 or at a position lower than the upper surface, and similarly, the upper surface of the 2 nd shield 321 is desirably located at the same height as the lower surface of the magnetic body core 150 or at a position higher than the lower surface. That is, the shield is desirably disposed so that its end coincides with the end of the magnetic core or is opposed to the inner wall of the magnetic core. In this case, the regions on which the electric field and the magnetic field act become equal, and the control of the winding aberration corrector can be facilitated. In contrast, when the lower surface of the 1 st shield 320 is located higher than the upper surface of the magnetic core 150 and/or the upper surface of the 2 nd shield 321 is located lower than the lower surface of the magnetic core 150, the regions on which the electric field and the magnetic field act are different, and control for offsetting the differences in the regions of action is required.

The magnetic core used in the multipole lens according to the present embodiment is not limited to the above-described shape, and various modifications are possible. For example, the shape of the groove provided in the magnetic core can be determined in consideration of ease of winding. As shown in fig. 5, a nonmagnetic spacer 400 may be provided in the Z direction with respect to the magnetic core 150. By providing the connecting portion of the current line in the nonmagnetic spacer 400, the 6-pole field strength excited by the connecting portion is reduced, and the accuracy of the position in the Z direction can be relaxed. In addition, although fig. 5 shows an example in which a nonmagnetic spacer is provided on the upper surface of the magnetic core 150, a nonmagnetic spacer may be provided on both the upper and lower surfaces.

Further, as shown in fig. 6, a slit may be provided instead of the groove reaching the upper and lower surfaces of the magnetic core. The slit 501 is thinner than the other portions of the magnetic core 550, and through holes 502 and 503 penetrating the inner wall and the outer wall of the magnetic core 550 are provided at the upper end and the lower end of the slit 501. A current line is arranged in the slit 501 through the through holes 502 and 503. In this configuration, the influence of the positional deviation of the connection portion of the current line is eliminated, and an ideal multipole field by the winding lens can be excited. In addition, similar effects can be obtained even if the magnetic core shown in fig. 1A is a magnetic core with upper and lower covers in which cylindrical magnetic covers having the same inner and outer diameters are disposed above and below the magnetic core.

Fig. 7 shows an example of the configuration of an electronic apparatus incorporating the winding aberration corrector described above. An electron beam (not shown) emitted from the electron gun 701 is shaped into a parallel beam by a condenser lens 702, passes through a winding aberration corrector 703, is condensed by a condenser lens 704, and is condensed on a sample 707 by an objective lens 706. The focused spot is deflected halfway through the scanning coil 705, and is scanned on the sample 707. The vacuum vessel 740 is evacuated, and the electron beam advances while being maintained in a vacuum state until reaching the sample 707 from the electron gun 701. In the winding aberration corrector 703, the chromatic aberration on the axis and the spherical aberration are corrected. The winding aberration corrector 703 is connected to a power supply 711, and a multi-pole field of an electric field or a magnetic field is excited in the winding aberration corrector 703 by a voltage and a current output from the power supply 711. The power supply 711 is further connected to a computer 720 that controls the entire system. The output value from the power supply 711 to the winding aberration corrector 703 is changed in response to a command from the computer 720.

Fig. 8A to B are electron-optical diagrams showing the trajectory of the electron beam 750 passing through the winding aberration corrector. The electron beam 750 passing through the winding aberration corrector 703 varies in trajectory according to the direction. Fig. 8A shows a trajectory (x trajectory) viewed from the y direction (direction perpendicular to the paper surface in fig. 7), and fig. 8B shows a trajectory (y trajectory) viewed from the x direction (left-right direction of the paper surface in fig. 7). Winding aberration corrector 703 is constituted by multipole lenses 771 to 774 of 4 stages, and excites a 4-pole field in multipole lenses 771 to 774, respectively, so that the trajectory of electron beam 750 is separated into an x trajectory and a y trajectory by the 4-pole field excited in multipole lens 771, and then converged in the x direction at position x of multipole lens 772 and converged in the y direction at position y of multipole lens 773, and after passing through multipole lens 774, the x trajectory and the y trajectory become symmetrical trajectories (parallel trajectories) again. In order to form such a trajectory, it is necessary to excite either a magnetic field or an electric field in the multipole lens 771 or the multipole lens 774. Both the magnetic field and the electric field are excited in the multipole lens 772 and the multipole lens 773. By using the winding aberration corrector of the present embodiment, chromatic aberration and spherical aberration can be corrected.

The present invention is not limited to the above-described embodiments, and includes various modifications. For example, the above-described embodiments have been described to explain the present invention for easy understanding, but the present invention is not necessarily limited to the embodiments having all the configurations described. In addition, a part of the structure of one embodiment may be replaced with the structure of another embodiment, and the structure of one embodiment may be added to the structure of another embodiment. Further, addition, deletion, and replacement of another configuration may be performed on a part of the configurations of the embodiments. For example, in the embodiment, the description has been given of the mode in which the current lines for generating the magnetic field in the multipole lens are arranged in the grooves provided in the inner wall of the magnetic core, but a plurality of current lines may be arranged axially symmetrically with respect to the central axis of the magnetic core along the inner wall of the magnetic core without providing the grooves.

Description of reference numerals

100.. an optical axis, 101 to 112.. an electric current line, 121.. a main line portion, 122, 123.. a connecting portion, 124.. a return line portion, 150, 550.. a magnetic core, 151 to 162.. a slot, 301 to 312.. an electrode, 320.. a 1 st shield, 321.. a 2 nd shield, 331 to 342.. an electrode fixing portion, 350.. a vacuum container, 351.. a vacuum partition wall, 391, 392, 393.. section, 400.. non-magnetic spacer, 501.. slit, 502, 503.. through hole, 701.. electron gun, 702, 704.. convergent lens, 703.. winding aberration corrector, 705.. scan coil, 706.. objective lens, 707.. sample, 711.. power supply, 720.. computer, 740.. vacuum vessel, 750.. electron beam, 771 ~ 774.. multipole lens.