US2266717A - Electron microscope - Google Patents

Electron microscope Download PDF

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US2266717A
US2266717A US303180A US30318039A US2266717A US 2266717 A US2266717 A US 2266717A US 303180 A US303180 A US 303180A US 30318039 A US30318039 A US 30318039A US 2266717 A US2266717 A US 2266717A
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vessel
radiating
relative
adjusting
electron microscope
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US303180A
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Borries Bodo Von
Schuchmann Hans
Ruska Ernst
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Fides Gesellschaft fuer die Verwaltung und Verwertung von Gewerblichen Schutzrechten mbH
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Fides Gesellschaft fuer die Verwaltung und Verwertung von Gewerblichen Schutzrechten mbH
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/04Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement or ion-optical arrangement
    • H01J37/147Arrangements for directing or deflecting the discharge along a desired path
    • H01J37/1471Arrangements for directing or deflecting the discharge along a desired path for centering, aligning or positioning of ray or beam
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/04Arrangements of electrodes and associated parts for generating or controlling the discharge, e.g. electron-optical arrangement or ion-optical arrangement
    • H01J37/147Arrangements for directing or deflecting the discharge along a desired path
    • H01J37/15External mechanical adjustment of electron or ion optical components
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01JELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
    • H01J37/00Discharge tubes with provision for introducing objects or material to be exposed to the discharge, e.g. for the purpose of examination or processing thereof
    • H01J37/02Details
    • H01J37/24Circuit arrangements not adapted to a particular application of the tube and not otherwise provided for

Definitions

  • the present invention relates. to electron microscopes and to new improvements therein.
  • the electron microscopes of the known type consist of a radiating apparatus including an incandescent cathode, a Wehnelt cylinder and an anode diaphragm for producing an electron beam which is directed through a field coil acting as a condensing lens, an object support and one or more magnifying field coils so as to form a highly enlarged image of the object to be studied. It is also known to tilt or shift the coil forming the condensing lens in order to direct the electron beam onto the object. This leads to adjustments in which the electron beam does not coincide with the optical axis of the enlarging system.
  • the image formed on the fluorescent screen is subjected to shifting movements if fluctuations occur in the current of the condensing lens or the voltage of the radiating apparatus. Such fluctuations however, can not be entirely avoided, and-ashifting of the image constitutes a very disturbing factor particularly if the image is to be reproduced photographically.
  • the invention provides means for adjusting the position and the direction of the electron beam and for adjusting one or more parts of the radiating apparatus relativeto the I system of field coils serving as magnifying lenses.
  • These means are designed so that they permit adjusting one or more parts of the radiating apparatus relative to the lens system by shifting and tilting the parts, or by either of these methods.
  • By the use of such adjusting means it is possible to direct the electron beam produced by the radiating apparatus so as to coincide precisely with the optical axis of the magnifying lens system.
  • fluctuations in the current of the condenser coil or the voltage of the radiating apparatus modify only the crosssectional area of the beam without causing changes in the direction thereof. Consequently, a shifting of the image through such fluctuations is entirely prevented.
  • the adjusting means according to the invention may be designed for adjusting the incandescent cathode relative to the Wehnelt cylinder.
  • the advantage hereby obtained is that one freedom of movement, that is, a mere shifting move ment, will be sumcient for performing the adjustment;
  • Another possibility accordingto the invention consists in providing means for adjusting'the incandescent cathode and the Wehnelt cylinder together relative to the anode diaphragm.
  • Still another way of' designing a microscope according to the invention consists 'in' the .pro- Vision of means for tilting andshifting: the :en-v tire radiating apparatus, that 1. is, the' incandescent cathode, the Wehnelt cylindr'andthe anode diaphragm, relativeto theTcondenSer-Iens and the other stationary parts-of the electron microscope.
  • the advantage of theflastzmen tioned device consists in that the adjusting means may easily be formed so' as to be electrically on ground potential.
  • This object maybe attained by providing means for tilting and shifting the condensing lens relative to the otherstationary lenses which are mounted on the supporting frame structure.
  • the condenser'lens' is preferably made adjustable inde pendent of'the means for adjusting the elements of the radiating apparatus.
  • an other object of'thepresent invention to provide means for adjusting or selecting the desired portion of the object'to be studiedby shifting the object support in a'plan'e transverse to the electron beam. If a new portion 'Ofthei object is to be studied, only the supportof theobject need be adjusted in transverse direction relative to the electron beam, whereas the latter, once it has been finally adjusted, requires no further adjustment.
  • This method of operating has the particular advantage that, regardless of which portion of the object is to be examined, always the optically most favorable part of the portraying system is used for forming the image,
  • the radiating apparatus I of the electron microscope includes an incandescent cathode 2, a Wehnelt cylinder 3 and an anode diaphragm 4. These parts are firmly mounted in a rigid structure consisting of a supporting body 30, an insulator 31 secured to the body 30 and enclosing the apparatus I, and an insulating sleeve 32 surrounding the terminals 33 of the apparatus I.
  • the electron beam produced by the radiating apparatus passes through a condensing coil 5, a sluicing device 5 for inserting and supporting the object to be studied, an objective coil 1 and a projecting coil 8.
  • the objective coil and the projecting coil form the magnifying lens system of the microscope.
  • a partition 36 and a tubular extension 3! are firmly secured to each other and connected with the other parts of the stationary vessel structure by means of a connecting structure 34.
  • the interior of the composite microscope vessel is hermetically sealed and evacuated.
  • the entire radiating apparatus carried by support 30 may be adjusted relative to the stationary portion of the electron microscope.
  • the stationary tubular part 3'! is provided with an extension 38 carrying adjusting screws II and countersprings l3 (one of each being illustrated) which bear against an intermediate rigid member 39.
  • This member also has adjusting screws l2 and counteracting springs l4 (one of each being illustrated) which bear against the supporting body 30 of the radiating unit.
  • Ball bearings as indicated at 40 and 4!, may be provided between elements 38 and 39 and between elements 39 and 30, respectively.
  • an adjustment of screws ll effects a displacement of the intermediate member 39 and the entire radiating unit in a direction transverse to the optical axis
  • the adjustment of screws l2 causes the supporting body 30 of the radiating unit to tilt relative to the optical axis of the stationary lenses 7 and 8.
  • the adjusting screws II and [2 in one or the other direction, the electron beam may be easily adjusted so as to coincide precisely with the optical axis of the magnifying lens system.
  • a rubber sleeve l9 serves for tightly connecting the movable part of the microscope with the stationary part 9.
  • this lens may also be adjusted relative to the vacuum vessel of the electron microscope.
  • adjusting screws [5 co-operating with resilient holding means H are provided in the stationary vessel portion 34 so as to bear against an intermediate ring 42 which in turn carries adjusting screws l6 and counteracting springs l8 bearing against the lens structure 5.
  • the screws l5 and I6 permit shifting and tiltin the condensing lens 5.
  • ] may be provided for shifting the sluicing device 6 relative to the vessel portion l0 within a plane transverse to the direction of the electron beam.
  • and 22 on the sluicing device 6 are used for connecting the movable sluice tightly to the stationary parts so as to preserve the vacuum in the interior of the microscope.
  • the upper sleeve 2! is of smaller size than the upper surface of the sluicing device 6 and the lower sleeve 22, so that the external pressure may exert a considerable force upon the sluicing device and press the latter against the objective coil 1, thus holding the device 6 in a fixed position.
  • and the upper surface of the sluicing device 6 is preferably dimensioned so that the latter can be shifted relatively easily and with great accuracy without losing the vacuum in the interior of the microscope.
  • all of the aforementioned adjusting screws are arranged so as to be accessible from the outside and serviceable during the operation of the microscope.
  • the present invention is not limited to the particular embodiment shown in the drawing and is susceptible of various modifications.
  • the sleeves l9 and 2! may consist of a single corrugated tube of tombac or the like which connects the radiating apparatus I with the sluicing device 6.
  • the adjusting means H, [3, l5, I6, I! and I8 may be mounted on a rigid upward extension of the vessel portion In of the electron microscope.
  • An electron microscope having means for holding the object to be studied, a magnifying lens system for producing an image of the object, a radiating unit for producing an electron beam, a condensing lens between said radiating unit and said object-holding means, said radiating unit being tiltable and shiftable in a transversal plane relative to said condensing lens, adjusting means for varying the angular position of said radiating unit relative to said condensing lens, and means for adjusting the transversal position of said radiating unit in any direction along said plane, said difierent adjusting means being operable independently from one another.
  • An electron microscope having a stationary rigid Vessel structure, means associated with said structure for holding the object to be studied, magnifying lens means mounted on said structure, a condensing lens also associated with said structure, a radiating unit for producing an electron beam, joint means for vacuum-tightly connecting said unit with said vessel structure so as to permit said unit a tilting and transverse shifting movement relative to said structure, an intermediate rigid member slidably arranged on said structure and engaging said radiating unit so as to permit an angular displacement of said unit relative to said member, adjusting means for varying and fixing the position of said intermediate member relative to said structure, and further adjusting means in transversal directions for varying and fixing the angular position of said unit relative to said member.
  • An electron microscope comprising a stationary rigid vessel structure having a tubular vessel portion, means for holding the object to be studied, a magnifying lens system, a condensing lens consisting of a magnet coil and arranged on and around said tubular vessel portion, a radiating unit for producing an electron beam, said radiating means being substantially in alignment with said tubular vessel portion so as to form an extension of said vessel structure, a sleeve of yielding material hermetically joining said unit with said tubular vessel portion to allow said unit tilting and shifting movements relative to said vessel portion, an intermediate annular member concentrically surrounding said sleeve and engaging said radiating unit so as to permit said unit angular displacements relative to said member, means for guiding said member relative to said vessel portion so as to permit said member shifting movements in transversal directions With respect to said vessel portion, adjusting means for varying and fixing the transversal position of said intermediate member relative to said structure, and further adjusting means for varying and fixing the angular position of said unit relative to said member,
  • An electron microscope comprising a composite vessel structure, a magnifying lens system, a condensing lens, and radiating means for producing an electron beam, said vessel structure having a first vessel portion provided with said magnifying lens system, a second vessel portion provided with said condensing lens and carrying said radiating unit, said second vessel portion being spaced from said first vessel portion and rigidly connected therewith so as to have said condensing lens and said unit substantially coaxial with said magnifying lens system, and an intermediate vessel portion shiftable transversely relative to said first and second vessel portions and vacuum-tightly joined therewith, said intermediate vessel portion forming a sluicing device for accommodating the object to be studied, and adjusting means for varying and fixing the position of said intermediate vessel portion relative to said other vessel portions, said adjusting means being arranged exteriorly so as to be serviceable during the operation of the electron microscope.
  • An electron microscope comprising a composite vacuum vessel having two fixed vessel portions spaced from each other in the direction of the optical axis and rigidly connected with each other, and an intermediate vessel portion arranged between and vacuum-tightly connected with said other vessel portions, said intermediate vessel portion forming a device for holding the object to be studied and being transversely displaceable relative to said other vessel portions, a radiating unit for producing an electron beam, said unit being arranged at the end of one of said fixed vessel portions so as to be displaceable transversely and angularly relative thereto, adjusting means for varying and fixing the position of said unit relative to said latter vessel portion in order to adapt said position to that of the object in said intermediate vessel portion, and a magnifying lens system arranged on the other of said fixed vessel portions.
  • An electron microscope comprising a composite vacuum vessel having two fixed vessel portions spaced from each other in the direction of the optical axis and rigidly connected with each other, and an intermediate vessel portion arranged between and vacuum-tightly connected with said other vessel portions, said intermediate vessel portion forming a device for holding the object to be studied and being transversely displaceable relative to said other vessel portions, a radiating unit for producing an electron beam and a lens for condensing said beam, said unit and said condensing lens being arranged on one of said fixed vessel portions and independently movable transversely and angularly relative to said vessel portions, independently operable adjusting means for varying and fixing the positions of said unit and said condensing lens respectively with respect to said latter vessel portion, and a magnifying lens system arranged on the other of said fixed vessel portions.
  • An electron microscope having a radiating device for producing an electron beam, a lens for condensing said beam, means for holding the object to be studied, a magnifying lens system for causing said condensed beam to produce an image of the object, said object holding means being displaceable relatively to and independently of said radiating device, condensing lens and magnifying lens system in the directions of a plane transversal to said beam, said radiating device being displaceable angularly and transversely with respect to said lens and lens system, and adjusting devices serviceable during the operation of the microscope for independently varying and fixing the positions respectively of said holding means and said radiating device.
  • An electron microscope having a radiating device for producing an electron beam, a lens for condensing said beam, means for holding the object to be studied, a magnifying lens system for causing said condensed beam to produce an image of the object, said object-holding means being displaceable relatively to and independently of said radiating device, condensing lens and magnifying lens system in directions of a plane transversal to said beam, said radiating device and said condensing lens being each separately displaceable angularly and transversely with respect to said lens system and independently of said radiating device, and adjusting devices for independently varying and fixing the position of each of said holding means, radiating device and condensing lens respectively.

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  • Chemical & Material Sciences (AREA)
  • Analytical Chemistry (AREA)
  • Electron Sources, Ion Sources (AREA)

Description

Dec-Q 64 1941- B. VON- BORRIES ETAL- 2,266,717
ELECTRON MICROSCOPE Filed Nov-. 7, 1939 Patented Dec. 16, 1941 1 ELECTRON MICROSCOPE Bodo Von Berries, Hans Schuchmann, and Ernst Ruska, Beriin-Spandau, Germany, assignors to Fides G-eseilschaft' fiir die Verwaltung und Verwertung Von gcwerblichen Schutzrechten mit besclir'einkter Haftung, Berlin, Germany, a-
corporation of Germany Application November 7, 1939, Serial No. 303,180 In Germany September 16, 1938 8 .Claims. (Q1. Zak-95) The present invention relates. to electron microscopes and to new improvements therein.
The electron microscopes of the known type consist of a radiating apparatus including an incandescent cathode, a Wehnelt cylinder and an anode diaphragm for producing an electron beam which is directed through a field coil acting as a condensing lens, an object support and one or more magnifying field coils so as to form a highly enlarged image of the object to be studied. It is also known to tilt or shift the coil forming the condensing lens in order to direct the electron beam onto the object. This leads to adjustments in which the electron beam does not coincide with the optical axis of the enlarging system. As a result the image formed on the fluorescent screen is subjected to shifting movements if fluctuations occur in the current of the condensing lens or the voltage of the radiating apparatus. Such fluctuations however, can not be entirely avoided, and-ashifting of the image constitutes a very disturbing factor particularly if the image is to be reproduced photographically.
It is the principal objectof the present invention to prevent such undesired shifting of an image formed in an electron microscope and, in particular, to render the electron microscope insensitive to fluctuations of the current and voltage, as mentioned above.
To this end, the invention provides means for adjusting the position and the direction of the electron beam and for adjusting one or more parts of the radiating apparatus relativeto the I system of field coils serving as magnifying lenses. These means are designed so that they permit adjusting one or more parts of the radiating apparatus relative to the lens system by shifting and tilting the parts, or by either of these methods. By the use of such adjusting means, it is possible to direct the electron beam produced by the radiating apparatus so as to coincide precisely with the optical axis of the magnifying lens system. As a result, fluctuations in the current of the condenser coil or the voltage of the radiating apparatus modify only the crosssectional area of the beam without causing changes in the direction thereof. Consequently, a shifting of the image through such fluctuations is entirely prevented.
The adjusting means according to the invention may be designed for adjusting the incandescent cathode relative to the Wehnelt cylinder. The advantage hereby obtained is that one freedom of movement, that is, a mere shifting move ment, will be sumcient for performing the adjustment;
Another possibility accordingto the invention consists in providing means for adjusting'the incandescent cathode and the Wehnelt cylinder together relative to the anode diaphragm.
Still another way of' designing a microscope according to the invention consists 'in' the .pro- Vision of means for tilting andshifting: the :en-v tire radiating apparatus, that 1. is, the' incandescent cathode, the Wehnelt cylindr'andthe anode diaphragm, relativeto theTcondenSer-Iens and the other stationary parts-of the electron microscope. The advantage of theflastzmen tioned device consists in that the adjusting means may easily be formed so' as to be electrically on ground potential.
Another object of the invention is:to;over= come the eifect'of deviations'of the'optical-axis of the condensing lens irom'the geometrical axis, which in the manufacture maysometimessnot be avoided. This object maybe attained by providing means for tilting and shifting the condensing lens relative to the otherstationary lenses which are mounted on the supporting frame structure. For this purpose, the condenser'lens'is preferably made adjustable inde pendent of'the means for adjusting the elements of the radiating apparatus. The advantageis hereby obtained that once the condenser'lens has been correctly adjusted, no further adjustment need be made, even if certain parts ofthe radiating apparatus as such must be exchanged, for example, if the incandescent cathode-is burnt out. The newly inserted-parts 'of theradia-ting apparatus are then again placed-in thecorrect position relative'to the 'lens system which has been once fixedly adjusted.v It is, however; advisable that the adjusting mechanism ofthe condenser'coil be so constructed-that; after:be ing once adjusted; furtheradjustments cannot be easily made during the operation of the microscope.
After finally adjusting theelectron beamso as to point in the desired direction, it'is advisable to maintain such adjustment even if in the operationof the microscope a new portion of the object'is to be studied. Itis, therefore, an other object of'thepresent invention -toprovide means for adjusting or selecting the desired portion of the object'to be studiedby shifting the object support in a'plan'e transverse to the electron beam. If a new portion 'Ofthei object is to be studied, only the supportof theobject need be adjusted in transverse direction relative to the electron beam, whereas the latter, once it has been finally adjusted, requires no further adjustment. This method of operating has the particular advantage that, regardless of which portion of the object is to be examined, always the optically most favorable part of the portraying system is used for forming the image,
These and other objects, features and advantages of the present invention will be understood from the following description of the mechanism diagrammatically illustrated in the accompanying drawing which shows an axial cross section through the main elements of an electron microscope according to the present invention.
The radiating apparatus I of the electron microscope, as shown in the drawing, includes an incandescent cathode 2, a Wehnelt cylinder 3 and an anode diaphragm 4. These parts are firmly mounted in a rigid structure consisting of a supporting body 30, an insulator 31 secured to the body 30 and enclosing the apparatus I, and an insulating sleeve 32 surrounding the terminals 33 of the apparatus I. The electron beam produced by the radiating apparatus passes through a condensing coil 5, a sluicing device 5 for inserting and supporting the object to be studied, an objective coil 1 and a projecting coil 8. The objective coil and the projecting coil form the magnifying lens system of the microscope. They are both stationary and firmly connected with the wall portion 9 of the microscope vessel in whose lower portion 35 the magnified image is produced on a fluorescent screen or a photographic layer (both not illustrated). A partition 36 and a tubular extension 3! are firmly secured to each other and connected with the other parts of the stationary vessel structure by means of a connecting structure 34. The interior of the composite microscope vessel is hermetically sealed and evacuated. For precisely adjusting the position and direction of the electron beam, the entire radiating apparatus carried by support 30 may be adjusted relative to the stationary portion of the electron microscope. For this purpose, the stationary tubular part 3'! is provided with an extension 38 carrying adjusting screws II and countersprings l3 (one of each being illustrated) which bear against an intermediate rigid member 39. This member also has adjusting screws l2 and counteracting springs l4 (one of each being illustrated) which bear against the supporting body 30 of the radiating unit. Ball bearings, as indicated at 40 and 4!, may be provided between elements 38 and 39 and between elements 39 and 30, respectively. As apparent from the drawing, an adjustment of screws ll effects a displacement of the intermediate member 39 and the entire radiating unit in a direction transverse to the optical axis, while the adjustment of screws l2 causes the supporting body 30 of the radiating unit to tilt relative to the optical axis of the stationary lenses 7 and 8. Hence, by turning the adjusting screws II and [2 in one or the other direction, the electron beam may be easily adjusted so as to coincide precisely with the optical axis of the magnifying lens system. A rubber sleeve l9 serves for tightly connecting the movable part of the microscope with the stationary part 9.
In order to compensate for variations resulting in the manufacture of the condensing lens 5, this lens may also be adjusted relative to the vacuum vessel of the electron microscope. For this purpose, adjusting screws [5 co-operating with resilient holding means H are provided in the stationary vessel portion 34 so as to bear against an intermediate ring 42 which in turn carries adjusting screws l6 and counteracting springs l8 bearing against the lens structure 5. The screws l5 and I6 permit shifting and tiltin the condensing lens 5.
For shifting the sluicing device 6 relative to the vessel portion l0 within a plane transverse to the direction of the electron beam, adjusting screws 2|] may be provided. Rubber sleeves 2| and 22 on the sluicing device 6 are used for connecting the movable sluice tightly to the stationary parts so as to preserve the vacuum in the interior of the microscope. As shown in the drawing, the upper sleeve 2! is of smaller size than the upper surface of the sluicing device 6 and the lower sleeve 22, so that the external pressure may exert a considerable force upon the sluicing device and press the latter against the objective coil 1, thus holding the device 6 in a fixed position. However, the difference in dimension between the sleeve 2| and the upper surface of the sluicing device 6 is preferably dimensioned so that the latter can be shifted relatively easily and with great accuracy without losing the vacuum in the interior of the microscope. As apparent from the drawing, all of the aforementioned adjusting screws are arranged so as to be accessible from the outside and serviceable during the operation of the microscope.
The present invention is not limited to the particular embodiment shown in the drawing and is susceptible of various modifications. For example, the sleeves l9 and 2! may consist of a single corrugated tube of tombac or the like which connects the radiating apparatus I with the sluicing device 6. In this case, the adjusting means H, [3, l5, I6, I! and I8 may be mounted on a rigid upward extension of the vessel portion In of the electron microscope.
We claim:
1. An electron microscope having means for holding the object to be studied, a magnifying lens system for producing an image of the object, a radiating unit for producing an electron beam, a condensing lens between said radiating unit and said object-holding means, said radiating unit being tiltable and shiftable in a transversal plane relative to said condensing lens, adjusting means for varying the angular position of said radiating unit relative to said condensing lens, and means for adjusting the transversal position of said radiating unit in any direction along said plane, said difierent adjusting means being operable independently from one another.
2. An electron microscope having a stationary rigid Vessel structure, means associated with said structure for holding the object to be studied, magnifying lens means mounted on said structure, a condensing lens also associated with said structure, a radiating unit for producing an electron beam, joint means for vacuum-tightly connecting said unit with said vessel structure so as to permit said unit a tilting and transverse shifting movement relative to said structure, an intermediate rigid member slidably arranged on said structure and engaging said radiating unit so as to permit an angular displacement of said unit relative to said member, adjusting means for varying and fixing the position of said intermediate member relative to said structure, and further adjusting means in transversal directions for varying and fixing the angular position of said unit relative to said member.
3. An electron microscope comprising a stationary rigid vessel structure having a tubular vessel portion, means for holding the object to be studied, a magnifying lens system, a condensing lens consisting of a magnet coil and arranged on and around said tubular vessel portion, a radiating unit for producing an electron beam, said radiating means being substantially in alignment with said tubular vessel portion so as to form an extension of said vessel structure, a sleeve of yielding material hermetically joining said unit with said tubular vessel portion to allow said unit tilting and shifting movements relative to said vessel portion, an intermediate annular member concentrically surrounding said sleeve and engaging said radiating unit so as to permit said unit angular displacements relative to said member, means for guiding said member relative to said vessel portion so as to permit said member shifting movements in transversal directions With respect to said vessel portion, adjusting means for varying and fixing the transversal position of said intermediate member relative to said structure, and further adjusting means for varying and fixing the angular position of said unit relative to said member,
4. An electron microscope comprising a composite vessel structure, a magnifying lens system, a condensing lens, and radiating means for producing an electron beam, said vessel structure having a first vessel portion provided with said magnifying lens system, a second vessel portion provided with said condensing lens and carrying said radiating unit, said second vessel portion being spaced from said first vessel portion and rigidly connected therewith so as to have said condensing lens and said unit substantially coaxial with said magnifying lens system, and an intermediate vessel portion shiftable transversely relative to said first and second vessel portions and vacuum-tightly joined therewith, said intermediate vessel portion forming a sluicing device for accommodating the object to be studied, and adjusting means for varying and fixing the position of said intermediate vessel portion relative to said other vessel portions, said adjusting means being arranged exteriorly so as to be serviceable during the operation of the electron microscope.
5. An electron microscope comprising a composite vacuum vessel having two fixed vessel portions spaced from each other in the direction of the optical axis and rigidly connected with each other, and an intermediate vessel portion arranged between and vacuum-tightly connected with said other vessel portions, said intermediate vessel portion forming a device for holding the object to be studied and being transversely displaceable relative to said other vessel portions, a radiating unit for producing an electron beam, said unit being arranged at the end of one of said fixed vessel portions so as to be displaceable transversely and angularly relative thereto, adjusting means for varying and fixing the position of said unit relative to said latter vessel portion in order to adapt said position to that of the object in said intermediate vessel portion, and a magnifying lens system arranged on the other of said fixed vessel portions.
6. An electron microscope comprising a composite vacuum vessel having two fixed vessel portions spaced from each other in the direction of the optical axis and rigidly connected with each other, and an intermediate vessel portion arranged between and vacuum-tightly connected with said other vessel portions, said intermediate vessel portion forming a device for holding the object to be studied and being transversely displaceable relative to said other vessel portions, a radiating unit for producing an electron beam and a lens for condensing said beam, said unit and said condensing lens being arranged on one of said fixed vessel portions and independently movable transversely and angularly relative to said vessel portions, independently operable adjusting means for varying and fixing the positions of said unit and said condensing lens respectively with respect to said latter vessel portion, and a magnifying lens system arranged on the other of said fixed vessel portions.
'7. An electron microscope having a radiating device for producing an electron beam, a lens for condensing said beam, means for holding the object to be studied, a magnifying lens system for causing said condensed beam to produce an image of the object, said object holding means being displaceable relatively to and independently of said radiating device, condensing lens and magnifying lens system in the directions of a plane transversal to said beam, said radiating device being displaceable angularly and transversely with respect to said lens and lens system, and adjusting devices serviceable during the operation of the microscope for independently varying and fixing the positions respectively of said holding means and said radiating device.
8. An electron microscope having a radiating device for producing an electron beam, a lens for condensing said beam, means for holding the object to be studied, a magnifying lens system for causing said condensed beam to produce an image of the object, said object-holding means being displaceable relatively to and independently of said radiating device, condensing lens and magnifying lens system in directions of a plane transversal to said beam, said radiating device and said condensing lens being each separately displaceable angularly and transversely with respect to said lens system and independently of said radiating device, and adjusting devices for independently varying and fixing the position of each of said holding means, radiating device and condensing lens respectively.
BODO VON BORRIES. ERNST RUSKA. HANS SCHUCHMANN.
US303180A 1938-09-16 1939-11-07 Electron microscope Expired - Lifetime US2266717A (en)

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Cited By (9)

* Cited by examiner, † Cited by third party
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US2418317A (en) * 1944-04-27 1947-04-01 Rca Corp Electronic gun adjustment
US2420207A (en) * 1944-12-30 1947-05-06 Rca Corp Electron gun mounting
US2421722A (en) * 1944-12-30 1947-06-03 Rca Corp Specimen holder assembly
US2423158A (en) * 1944-04-19 1947-07-01 Rca Corp Specimen chamber for electron microscopes
US2424790A (en) * 1942-12-01 1947-07-29 Gen Electric Electron microscope
US2444368A (en) * 1946-03-12 1948-06-29 Rca Corp Method of making electron diffraction patterns of fusible specimens
US2663815A (en) * 1950-09-26 1953-12-22 Clarostat Mfg Co Inc Ion trap
US2754349A (en) * 1951-03-28 1956-07-10 Leo C Werner Insulating spacers
US3149258A (en) * 1954-09-09 1964-09-15 Sheldon Edward Emanuel Electron microscope with an X-ray target

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
NL67115C (en) * 1946-01-12

Cited By (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2424790A (en) * 1942-12-01 1947-07-29 Gen Electric Electron microscope
US2423158A (en) * 1944-04-19 1947-07-01 Rca Corp Specimen chamber for electron microscopes
US2418317A (en) * 1944-04-27 1947-04-01 Rca Corp Electronic gun adjustment
US2420207A (en) * 1944-12-30 1947-05-06 Rca Corp Electron gun mounting
US2421722A (en) * 1944-12-30 1947-06-03 Rca Corp Specimen holder assembly
US2444368A (en) * 1946-03-12 1948-06-29 Rca Corp Method of making electron diffraction patterns of fusible specimens
US2663815A (en) * 1950-09-26 1953-12-22 Clarostat Mfg Co Inc Ion trap
US2754349A (en) * 1951-03-28 1956-07-10 Leo C Werner Insulating spacers
US3149258A (en) * 1954-09-09 1964-09-15 Sheldon Edward Emanuel Electron microscope with an X-ray target

Also Published As

Publication number Publication date
FR864910A (en) 1941-05-08
US2301987A (en) 1942-11-17

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