Abstract:
The objective of the present application is to suppress the occurrence of flares and to reduce the amount of secondary electrons arising at an aperture provided to the lead-out electrode of an electron gun. By coating a thin film having a low rate of secondary electron emission such as carbon onto the aperture of a lead-out electrode closest to an electron source in an electron gun, it is possible to reduce the amount of secondary electrons arising. Secondary electrons arising at the lead-out electrode, are reduced, and so as a result, flare is reduced. By incorporating two apertures to the lead-out electrode, and applying to the two apertures a potential that is equipotential to the lead-out electrode, it is possible to eliminate an electric field from seeping from under to over the lead-out electrode. Secondary electrons arising when an electron beam impacts the lead-out electrode cease to incur force in the direction of passage from the lead-out electrode, and consequently there is a reduction in flares.

Description:
TECHNICAL FIELD 
       [0001]    The present invention relates to an electron gun including a Schottky electron source or a field emission electron source and a charged particle beam device equipped with these electron guns. 
       BACKGROUND ART 
       [0002]    Since the Schottky electron gun and the field emission electron gun can stably emit an electric current of high brightness in a narrow energy spread, these electron guns are used for the electron gun of a charged particle beam device such as a scanning electron microscope (SEM) and a transmission electron microscope (TEM). Particularly, these electron guns are used for the electron gun of an electron microscope for analysis because of the characteristics of a narrow energy spread and a high brightness, for example. 
         [0003]      FIG. 3  schematically illustrates the configuration of a previously existing electron gun as a Schottky electron gun is taken as an example. The electron gun is configured of at least components below, including an electron source  1  formed of a tungsten single crystal material with a sharpened tip end, a filament  2  welded to the electron source  1  for heating the electron source  1 , zirconium dioxide  3  coated over the electron source  1 , a suppressor electrode  4  that suppresses thermoelectrons generated from the filament  2 , an extracting electrode  5  that provides a strong electric field at the tip end of the electron source  1  for extracting electrons, and one or a plurality of accelerating electrodes  6  that accelerate the extracted electrons to a predetermined energy. The electron gun in  FIG. 3  is the case of including one stage of the accelerating electrode. Moreover, the extracting electrode  5  includes an aperture  7  that restricts electrons (an electron beam) passed therethrough. 
         [0004]    A negative potential V0 is applied to the electron source  1  with respect to the ground potential. When an electric current is passed through the filament  2 , the filament  2  is heated at a temperature of about 1,800 K, and the zirconium dioxide  3  coated over the electron source  1  is diffused toward the tip end of the electron source  1 . At this time, the work function on the tip end face of the electron source  1 , that is, the work function on the crystal plane (100) of a single crystal is reduced to about 2.8 eV. Here, when a positive voltage V1 is applied to the extracting electrode  5  with respect to the electron source  1 , the electric field near the tip end of the electron source  1  is increased, and electrons (an electron beam) are emitted from the crystal plane of the electron source  1 , on which the work function is reduced, toward the extracting electrode  5  by Schottky effect (technically, electrons are emitted from crystal planes of tetragonal symmetry orthogonal to the crystal plane (100) such as the crystal plane (101) and the crystal plane (001) on the side faces near the tip end of the electron source in addition to the crystal plane (100) of the tip end of the electron source). 
         [0005]    In the electrons emitted from the electron source  1 , the electrons passed through the extracting electrode  5  are accelerated at a predetermined accelerating voltage by the accelerating electrode  6 , and emitted from the electron gun. The electrons emitted from the electron gun are reduced to a specific magnification by a condenser lens and an objective lens, for example, not illustrated, and applied to a sample. 
         [0006]    The electron microscope detects secondary electrons, transmission electrons, and reflection electrons generated by an interaction between electrons and a sample when the electrons collide against the sample, and observes and analyzes the microstructure of the sample. 
         [0007]    Here, when an electron beam spot is observed through a fluorescent screen, for example, brightness called a flare is sometimes confirmed around a main beam. 
         [0008]      FIG. 4  is a main beam  30  and a flare  31  of an electron beam spot actually observed.  FIG. 4(   a ) is a photograph diagram and  FIG. 4(   b ) is a schematic diagram. The flare  31  causes a reduction in signal-to-noise and a reduction in resolution of the observed image of the electron microscope and causes a system peak when analyzed. 
         [0009]    As illustrated in  FIG. 5 , in Related Patent Document 1, it is considered that the flare is caused by electrons (an electron beam R) that an electron beam B 2  emitted from crystal planes  1   b  (the crystal plane (010) and the crystal plane (001), for example) on the side faces near the tip end of an electron source (a tungsten single crystal)  1  is reflected in an extracting electrode  5 . In this connection, a main beam B 1  is emitted from a tip end face  1   a  of the electron source  1  (i.e. the crystal plane (100)). In Related Patent Document 1 (Japanese Patent Application Laid-Open Publication No. 2008-117662), for the measures against the flare, a plurality of apertures  7  and  8  (two apertures, for example) were provided on an electron beam passage to geometrically restrict an angle at which the electrons are passed, as illustrated in  FIG. 6 . As a result, the reflection electron beam R from the extracting electrode caused by the electron beam emitted from the tip end side faces of the electron source  1  is geometrically restricted. Here, in the case where the apertures  7  and  8  are mounted on the extracting electrode  5 , the apertures  7  and  8  restrict an angle of the electrons passed to an angle of 6°. 
       CITATION LIST 
     Patent Literature 
       [0000]    
       
         PATENT DOCUMENT 1: Japanese Patent Application Laid-Open Publication No. 2008-117662 
       
     
       SUMMARY OF THE INVENTION 
     Technical Problem 
       [0011]    In the electron gun, a flare also occurs from causes other than the reflection electrons R from the side faces of the extracting electrode. This is because it is confirmed by experiment that a flare includes a component having energy a few kV lower than the energy of the main beam and this component occurs from a cause other than the reflection electron. In the electrons emitted from the electron source  1 , the electrons passed through the extracting electrode  5  are 1/100 or less, and most of the electrons collide against the extracting electrode  5  and the aperture  7 . For example, the entire electric current emitted from the electron source ranges from a few to a few hundreds microamperes, whereas the electric current passed through the aperture  7  mounted on the extracting electrode  5  ranges from a few tens to a few hundreds nanoamperes. 
         [0012]      FIG. 7  is the detail of a previously existing aperture  7  mounted on an extracting electrode  5 .  7 ′ denotes a beam transmission hole of the aperture  7 . A plate  70  forming the aperture  7  is made of molybdenum in a thickness of 10 to 50 μm, and the surface of the molybdenum plate  70  is coated with platinum palladium  71  in a thickness of 10 to 50 nm in order to prevent electrification caused by an oxidize film. When electrons collide against the aperture  7  provided on the extracting electrode  5 , the interaction between the electrons and the platinum palladium generates a secondary electron e 2  (see  FIG. 8 ). In addition to this, as illustrated in  FIG. 8 , an electric field generated by the extracting electrode  5  and an accelerating electrode  6  goes beyond the aperture  7  mounted on the extracting electrode  5  (see  FIG. 3 ). This electric field applies force to the secondary electron e 2  generated at the aperture  7  in the direction in which the secondary electron e 2  is passed through the aperture  7  (the hole  7 ′). The secondary electron e 2  passed through the aperture  7  is further accelerated, and emitted from the electron gun. The electron beam of the secondary electron e 2  generated at the aperture  7  is observed as a spatially spread flare of low energy on the electron microscope as compared with the main beam of primary electrons directly emitted from the electron source  1 . The flare causes a reduction in resolution, a reduction in signal-to-noise, and a system peak when analyzed. 
         [0013]    Related Patent Document 1 discloses neither the recognition of the problems of the secondary electrons generated at the aperture  7  nor a means for solving the problems. 
         [0014]    The present invention is made in the circumstances of the problems. It is an object of the present invention to reduce an amount of secondary electrons generated at an aperture provided on an extracting electrode and to suppress the occurrence of a flare. 
       Solution to Problem 
       [0015]    In order to solve the problems, the present invention is basically configured as follows. 
         [0016]    (1) Namely, an electron gun includes: an electron source; an extracting electrode configured to apply an electric field to the electron source for extracting electrons from the electron source, the extracting electrode including an aperture configured to pass a part of electrons from the electron source; and an accelerating electrode configured to accelerate electrons extracted using the extracting electrode at a predetermined accelerating voltage. In the electron gun, one or more of the apertures are provided, and a surface of a base material of at least an aperture closest to the electron source is coated with a material having a secondary electron emission rate of 0.6 or less when irradiation energy of primary electrons colliding against the aperture ranges from 2 to 3 kV, as a material having a small secondary electron emission rate. 
         [0017]    Preferably, the coating material applied to the surface of the base material of the aperture is carbon or boron, for example. 
         [0018]    Preferably, the electron gun is applied to a Schottky electron gun or a field emission electron gun as an application object, but not limited thereto. The electron gun is applicable to other electron guns including similar problems. 
         [0019]    (2) Moreover, in addition to the configuration described above, the invention of the present application also proposes an electron gun in which the extracting electrode is provided with two upper and lower apertures; and a potential of these apertures is made equal to a potential of the extracting electrode. 
         [0020]    As illustrated in the configuration in (1), the material on the surface of the base material of the aperture  7  provided on the extracting electrode  5  is changed to a material of a low secondary electron emission rate, so that it is possible to reduce an amount of secondary electrons generated from the surface of the base material of the aperture because a primary electron beam (an electron beam emitted from the electron source) collides against the aperture  7 . 
         [0021]    Furthermore, the potential of the two upper and lower apertures provided on the extracting electrode as in (2) is controlled to be equal to the potential of the extracting electrode, so that it is possible to eliminate an electric field going from below to above the extracting electrode. Accordingly, even though secondary electrons are generated (emitted) from the surface of the base material of the aperture valve, it is possible to prevent the secondary electrons being passed through the aperture. 
       Advantageous Effects of the Invention 
       [0022]    According to the present invention, it is possible to reduce an amount of secondary electrons generated at an aperture provided on an extracting electrode. Accordingly, the occurrence of a flare is suppressed, so that it is possible to observe an image of a high resolution and a high signal-to-noise when observing a sample using an electron microscope, for example. Moreover, a system peak when analyzed is eliminated as well. 
         [0023]    Furthermore, in addition to the foregoing configurations, the technique that controls the potential of the two upper and lower apertures to be equal to the potential of the extracting electrode is selectively adopted, so that even though secondary electrons are generated as described above, the secondary electrons are prevented from being passed through the aperture, and it is possible to more effectively prevent the occurrence of a flare caused by the secondary electrons. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0024]      FIG. 1  is a schematic diagram of a first embodiment of a Schottky electron gun to which the present invention is applied; 
           [0025]      FIG. 2  is a perspective view of an aperture mounted on an extracting electrode according to the embodiment, which is cut in a half; 
           [0026]      FIG. 3  is a schematic diagram of an exemplary previously existing Schottky electron gun; 
           [0027]      FIG. 4  is an exemplary flare image observed on an electron microscope, (a) is a photograph diagram of the flare image, and (b) is a schematic diagram; 
           [0028]      FIG. 5  is a schematic diagram of a cause in which a flare occurs in a previously existing technique; 
           [0029]      FIG. 6  is a schematic diagram of the previously existing technique in which the reflection electrons of electrons emitted from the side faces of an electron source are restricted using an extracting electrode; 
           [0030]      FIG. 7  is a perspective view of a previously existing aperture mounted on the extracting electrode, which is cut in a half; 
           [0031]      FIG. 8  is a conceptual diagram of a manner in which a secondary electron generated at the aperture mounted on the extracting electrode is passed through the aperture in the previously existing technique; 
           [0032]      FIG. 9  is a conceptual diagram of the potential distribution near apertures on an extracting electrode when two apertures are provided; 
           [0033]      FIG. 10  is a schematic diagram of an electron microscope system mounted with an electron gun according to the present invention; 
           [0034]      FIG. 11  is a schematic diagram of a control screen for an electron gun displayed on a control PC; and 
           [0035]      FIG. 12  is a schematic diagram of a second embodiment of the present invention. 
       
    
    
     DESCRIPTION OF EMBODIMENTS 
       [0036]    Embodiments of the present invention will be described with reference to embodiments in  FIGS. 1 ,  2 , and  9  to  13 . 
       First Embodiment 
       [0037]    An embodiment in  FIG. 1  (a first embodiment) is a Schottky electron gun as an example to which the present invention is applied. 
         [0038]    In the drawing, an electron source (an emitter)  1 , a filament  2 , zirconium dioxide  3 , a suppressor electrode  4 , an extracting electrode  5 , and an accelerating electrode  6  are similar to the previously existing components illustrated in  FIG. 3 . 
         [0039]    Namely, in driving the electron gun, the electron source  1  made of a tungsten single crystal material is heated at a temperature of about 1,800 K by the filament  2 . At this time, the zirconium dioxide  3  coated over the electron source is diffused, and the work function of the crystal plane (100) of the tip end face of the electron source  1  is reduced to about 2.8 eV. Here, when a positive potential of the work function or more is applied to the extracting electrode  5  with respect to the electron source  1 , an electric field near the tip end of the electron source  1  is increased, and electrons are emitted from the electron source  1 . In the electrons emitted from the electron source  1 , the electrons passed through apertures  7 A and  8 A provided on the extracting electrode  5  are accelerated at a predetermined accelerating voltage at the accelerating electrode  6 , and emitted as the electron beam of the electron gun. On the other hand, the electrons that are not enabled to be passed thorough the extracting electrode  5  are mostly absorbed into the extracting electrode  5  when colliding against the extracting electrode  5 . According to the previously existing technique, as already described above, a part of the electrons generate secondary electrons and reflection electrons due to the interaction between the aperture members, the extracting electrode, and primary electrons. 
         [0040]    In the embodiment, first, the following configuration is provided in order to suppress the generation of these secondary electrons. 
         [0041]    First, a plurality of apertures, two upper and lower apertures  7 A and  8 A, for example, are provided on the extracting electrode  5 . A material  72  of a small secondary electron emission rate is coated over the surface of a base material (molybdenum, for example)  70  of at least the upper aperture  7 A as illustrated in  FIG. 2 . Carbon and boron are named for a preferable coating  72 . 
         [0042]    In the case where electrons from the electron source are caused to collide against a target at an electron irradiation energy of 2 to 3 kV, the secondary electron emission rate of carbon ranges from 0.2 to 0.6, and the secondary electron emission rate of platinum ranges from 1.0 to 1.5. The secondary electron emission rates are disclosed in “A DATA BASE ON ELECTRON-SOLID INTERACTIONS, David Joy (URL:rsh.nst.pku.edu.cn/software/database0101.doc)”, for example. Therefore, in the case where the carbon film  72  is coated over the surface of the base material  70  of the aperture  7 A, secondary electrons emitted from the aperture  7 A (namely, secondary electrons generated when primary electrons from the electron source  1  are caused to collide against the aperture  7 A) can be reduced to ⅕ to ⅖ as compared with the previously existing aperture  7 . The carbon film  72  illustrated in  FIG. 2  is applied to at least the top face of the base material  70  of the aperture  7 A, that is, applied to the surface to which a primary electron beam from the electron source is applied. The thickness of the carbon film  72  has to be thick in order to prevent the primary electrons emitted from the electron source from being passed through the carbon film  72 . However, when the thickness is too thick, the coating is prone to peel off. Desirably, the film thickness of the carbon film  72  is 500 nm or less. A typically preferable film thickness of the coating ranges from 50 to 200 nm. 
         [0043]    The carbon film is used as the coating material for the aperture as described above, so that it is possible to reduce an amount of secondary electrons generated at the aperture provided on the extracting electrode. According to the embodiment, when observing a sample through an electron microscope, it was possible to observe an image of a high resolution and a high signal-to-noise by suppressing the occurrence of a flare. 
         [0044]    It is noted that for the coating material  72 , boron can also achieve a low secondary electron emission rate similar to carbon. The secondary electron emission rate for boron is 0.4 or less in the case where electrons from the electron source are caused to collide against boron at an electron irradiation energy of 2 to 3 kV. 
         [0045]    The technical concept of the invention of the present application is basically in that the surface of the base material of the aperture provided on the extracting electrode of the electron gun is coated with a material as a material of a small secondary electron emission rate, which has a secondary electron emission rate of 0.6 or less in the case where the irradiation energy of primary electrons colliding against the aperture ranges from 2 to 3 kV. When the secondary electron emission rate is satisfied, a material other than carbon and boron may be used for the base material applied to the surface of the base material of the aperture. 
         [0046]    Moreover, the potential of the two upper and lower apertures, the aperture  7 A and the aperture  8 A, is the same as the potential of the extracting electrode  5 . 
         [0047]      FIG. 9  is a schematic diagram of the potential distribution near the apertures  7 A and  8 A in this case. In  FIG. 9 , since the potential in the space between the aperture  7 A and the aperture  8 A is equal to the potential of the extracting electrode  5 , the electric field is zero in the space. Therefore, the electric field generated between the accelerating electrode  6  and the extracting electrode  5  is relaxed in this space, and does not go beyond the aperture  7 A. In the embodiment, as already described, the aperture  7 A is applied with the coating  72  using a material of a small secondary electron emission rate. Even though an electron beam collides against near the aperture  7 A to generate secondary electrons, the electric field generated between the accelerating electrode  6  and the extracting electrode  5  is relaxed in this space, and does not go beyond the aperture  7 A. Thus, the secondary electrons are absorbed into the extracting electrode  5  while scattering in the extracting electrode  5 , not passed through the aperture  7 A. 
         [0048]    On the other hand, since the electric field goes beyond the aperture  8 A, secondary electrons are generated in the case where the main electron beam (primary electrons) passed through the aperture  7 A collides against the aperture  8 A. These secondary electrons are passed through the aperture  8 A mounted on the extracting electrode  5 . In this case, when the aperture  8 A is also coated with a material of a small secondary electron generation rate (carbon and boron, for example), the generation of secondary electrons can be effectively suppressed. However, instead of the material, the following structural consideration can also effectively suppress the generation of secondary electrons from the aperture  8 A. 
         [0049]    Namely, the hole diameter of the aperture  8 A is geometrically increased more than that of the aperture  7 A in order that the main electrons do not collide against the base material  70  of the aperture  7 A. Moreover, desirably, the distance between the two apertures is one time the inner diameter of the aperture  8 A or more in order that the electric field does not go beyond the aperture  7 A. For example, in the case where the inner diameter of the aperture  7 A is 0.5 mm and the distance between the tip end of the electron source  1  and the aperture  7 A is 1.5 mm, the inner diameter of the aperture  8 A is set to 0.6 mm and the distance between the two apertures  7 A and  8 A is set to 0.6 mm or more. On the other hand, when the distance between the two apertures  7 A and  8 A becomes long, the extracting electrode  5  becomes thick, which sometimes causes a problem in that the optical properties of the electron gun are degraded. Therefore, desirably, the distance between the two apertures  7 A and  7 B is one time to three times the inner diameter of the aperture  8 A. 
         [0050]    It is noted that in the embodiment, the two apertures  7 A and  8 A are provided, so that the effect similar to the effect of Related Patent Document 1 (Japanese Patent Application Laid-Open Publication No. 2008-117662) already described, that is, the effect can also be exerted to prevent the transit of the electron beam R reflected in the extracting electrode as illustrated in  FIG. 6  in the present specification. 
         [0051]    According to the embodiment, the electrons passed through the extracting electrode  5  are accelerated at a predetermined energy at the accelerating electrode  6 , and emitted from the electron gun. Since all the emitted electrons are electrons emitted from the electron source  1 , no flare occurs in the case where a sample is observed through the electron microscope, and an image of a high resolution and a high signal-to-noise can be obtained. Moreover, it is also possible to eliminate a system peak when analyzed. 
         [0052]      FIG. 10  is a schematic diagram of a transmission electron microscope (TEM/STEM) system as an exemplary charged particle beam device mounted with the electron gun according to the present invention. The electron microscope is configured of a main body  10  including an electron gun  13  according to the foregoing embodiment, a power supply  11  that supplies a voltage and an electric current to drive the main body, and a controller  12  that controls the main body  10  by controlling the output of the power supply. 
         [0053]    In the configuration, the main body  10  is configured of the electron gun  13  that generates and emits electrons accelerated at given energy, an illumination system  14  that controls the emitted electrons toward a sample, a sample stage  16  that holds a sample  15  and moves the sample  15  in a given direction, a secondary electron detector  17   a  that detects signals when the electrons collide against the sample, a scattering electron detector  17   b , detection systems including a transmission electron detection system  17   c  and other detection systems, an image forming system  18  that controls the magnification and angle of electrons to be passed through the sample, and an exhaust system  19  that vacuum-exhausts the entire system, for example. The power supply  11  includes a voltage supply that supplies a potential to the electrodes of the electron gun  10  and electric current supplies that pass electric currents through the lenses of the illumination system  14  and the image forming system  18 , and also includes a power supply that drives the units of the main body  10  and a power supply that drives the controller  12 , for example. 
         [0054]    The controller  12  serves as controlling the main body  10  by controlling the output of the power supply  11 . As for the electron gun, the controller  12  controls the accelerating voltage, the extracting voltage, and the filament current, for example, and controls the electron gun to emit electrons having a given accelerating energy in a given amount. The electron gun  13  includes the aperture  7 A and the aperture  8 A described in the foregoing embodiment, in which at least the aperture  7 A is coated with a material of a small secondary electron emission rate and a potential the same as that of the extracting electrode is applied to the space between the apertures  7 A and  8 A. It is noted that  FIG. 10  is a schematic diagram of the transmission electron microscope (TEM/ATEM). A similar effect can be expected in the electron gun  13  described in the foregoing embodiment even in the case where the electron gun  13  is mounted on a scanning electron microscope (SEM). 
         [0055]      FIG. 11  is an exemplary electron gun control screen displayed on the monitor of the controller.  FIG. 11  is a control screen for the Schottky electron gun. Set values are displayed on the left side of the screen, and HV-ON buttons and read values are displayed on the right side. The accelerating voltage (V0), the extracting voltage (V1), and the filament current (If) are preset on the left side of the screen. When the HV-ON button is pressed, a negative accelerating potential (−V0) is applied to the electron source  1 . Moreover, an electric current is passed through the filament  2  to heat the electron source  1 . When a positive extracting voltage (V1) is applied to the extracting electrode  5  with respect to the electron source after sufficiently heating the electron source  1 , electrons are emitted from the electron source  1 . Here, an emission current (Ie) detects electrons emitted from the electron source  1  or an electric current caused by electrons absorbed in the extracting electrode  5 . The potential of the two apertures  7 A and  8 A applied to the embodiment is controlled to be equal to the potential of the extracting electrode as already described. In  FIG. 11 , the accelerating voltage, the extracting voltage, the filament current, and the emission current are displayed as the read values. However, it may be fine that all values are displayed, or necessary values are selected and displayed. 
       Second Embodiment 
       [0056]      FIG. 12  is another embodiment (a second embodiment) including accelerating electrodes in a plurality of stages. Differences between the embodiment and the first embodiment are in that the Schottky electron gun including the accelerating electrode  6  in a single stage is shown in the first embodiment and a Schottky electron gun including accelerating electrodes in three stages is shown in the second embodiment. The configurations of apertures  7 A and  8 A are similar as in the first embodiment. The basic operations and working effect of the embodiment are similar as in  FIG. 1 , and the description is omitted. 
         [0057]    In the embodiment, a control voltage V2 having a positive potential with respect to an electron source  1  is applied to an accelerating electrode  6   a . An accelerating electrode  6   c  is grounded, and a voltage across the accelerating electrodes  6   a  and  6   b  and a voltage across the accelerating electrodes  6   b  and  6   c  are divided by a split resister  9  at an equal voltage ((V0−V2)/2). Here, the control voltage V2 is used for controlling the trajectory of electrons when passed through the accelerating electrode  6 . 
         [0058]    Also in the embodiment, all of electrons emitted from the electron gun are electrons emitted from the electron source  1 . Therefore, in the case where a sample is observed through an electron microscope, no flare occurs, and it is possible to obtain an image of a high resolution and a high signal-to-noise. Moreover, it is also possible to eliminate a system peak when analyzed. 
         [0059]    The embodiments illustrated in  FIGS. 1 and 12  show the embodiments of the Schottky electron gun. However, the similar effect can be obtained also in the case of a field emission electron gun. Also in the case of the field emission electron gun, a tungsten single crystal is used for an electron source, and an extracting electrode and an accelerating electrode are similarly disposed as in the Schottky electron gun. The extracting electrode is provided with the apertures  7 A and  8 B similarly in the first and second embodiments already described. As publicly known, the field emission electron gun is different from the Schottky electron gun in that the field emission electron gun is an electron gun using the field emission phenomenon, which is operated at ambient temperature and needs ultrahigh vacuum. The configurations of the apertures  7 A and  8 A are similar as in the Schottky electron gun, and the drawings are omitted in the embodiment. 
         [0060]    In the foregoing embodiments, the example is shown that the two apertures  7 A and  8 A are provided on the extracting electrode. However, one aperture or three apertures or more may be provided, in which at least the aperture  7 A closest to the electron source is coated with a member of a small secondary electron emission rate. 
         [0061]    Moreover, the present invention is applicable not only to the electron microscope (TE/STEM/SEM) but also to other charged particle devices. 
       REFERENCE SIGNS LIST 
       [0000]    
       
           1  Single crystal tungsten electron source 
           2  Filament 
           3  Zirconium dioxide 
           4  Suppressor electrode 
           5  Extracting electrode 
           6 ,  6   a ,  6   b ,  6   c  Accelerating electrode 
           7 ,  8  Aperture 
           7 A,  8 A Aperture 
           70  Base material for the aperture 
           71  Antistatic coating 
           72  Coating for reducing an amount of secondary electrons generated 
           9  Split resister 
           10  Main body 
           11  Power supply 
           12  Controller 
           13  Electron gun 
           14  Illumination system 
           15  Sample 
           16  Sample stage 
           17   a  Secondary electron detector 
           17   b  Scattering electron detector 
           17   c  Transmission electron detector 
           18  Image forming system 
           19  Exhaust system