US3387132A - Particle beam apparatus with a cryogenically cooled specimen cartridge that is below the specimen holder temperature - Google Patents

Particle beam apparatus with a cryogenically cooled specimen cartridge that is below the specimen holder temperature Download PDF

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Publication number
US3387132A
US3387132A US392088A US39208864A US3387132A US 3387132 A US3387132 A US 3387132A US 392088 A US392088 A US 392088A US 39208864 A US39208864 A US 39208864A US 3387132 A US3387132 A US 3387132A
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specimen
cartridge portion
cartridge
diaphragm
specimen holder
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US392088A
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English (en)
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Herrmann Karl-Heinz
Loebe Wolfram
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Siemens AG
Siemens Corp
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Siemens Corp
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41CPROCESSES FOR THE MANUFACTURE OR REPRODUCTION OF PRINTING SURFACES
    • B41C3/00Reproduction or duplicating of printing formes
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41CPROCESSES FOR THE MANUFACTURE OR REPRODUCTION OF PRINTING SURFACES
    • B41C3/00Reproduction or duplicating of printing formes
    • B41C3/06Reproduction or duplicating of printing formes to produce printing blocks from plastics
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41MPRINTING, DUPLICATING, MARKING, OR COPYING PROCESSES; COLOUR PRINTING
    • B41M1/00Inking and printing with a printer's forme
    • B41M1/02Letterpress printing, e.g. book printing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41MPRINTING, DUPLICATING, MARKING, OR COPYING PROCESSES; COLOUR PRINTING
    • B41M9/00Processes wherein make-ready devices are used
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41NPRINTING PLATES OR FOILS; MATERIALS FOR SURFACES USED IN PRINTING MACHINES FOR PRINTING, INKING, DAMPING, OR THE LIKE; PREPARING SUCH SURFACES FOR USE AND CONSERVING THEM
    • B41N1/00Printing plates or foils; Materials therefor
    • B41N1/12Printing plates or foils; Materials therefor non-metallic other than stone, e.g. printing plates or foils comprising inorganic materials in an organic matrix
    • GPHYSICS
    • G21NUCLEAR PHYSICS; NUCLEAR ENGINEERING
    • G21KTECHNIQUES FOR HANDLING PARTICLES OR IONISING RADIATION NOT OTHERWISE PROVIDED FOR; IRRADIATION DEVICES; GAMMA RAY OR X-RAY MICROSCOPES
    • G21K5/00Irradiation devices
    • G21K5/08Holders for targets or for other objects to be irradiated
    • 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
    • H01J37/20Means for supporting or positioning the object or the material; Means for adjusting diaphragms or lenses associated with the support

Definitions

  • a particle beam apparatus having wall structure forming a chamber, the wall structure being at the temperature of the surrounding atmosphere when the apparatus is in operation and having a vacuum space in the chamber; a cartridge assembly mounted in the chamber and having two coaxial and axially apertured cartridge portions, a first one of the cartridge portions being in thermally conductive connection with the chamber so as to be substantially at the temperature of the wall structure; cryogenic means connected with a second one of the cartridge portions for cooling it during the operation to a temperature below the temperature of the wall structure; a specimen holder and diaphragm means mounted on the first cartridge portion in coaxial relation thereto, the diaphragm means being axially spaced from the specimen holder on one side of the holder and being in thermally conductive connection with the first cartridge portion so as to be approximately at the temperature of the wall structure; and means for directing a particle beam through the first apertured cartridge portion onto a specimen held in the specimen holder, the second cartridge portion extending around the first cartridge portion in the
  • Our invention relates to particle beam apparatus, also known as corpuscular-ray apparatus, particularly electron microscopes, which during operation are continuously connected to a vacuum pump and have a specimen holder accommodating cartridge connected with a cryogenic cooling device.
  • particle beam apparatus also known as corpuscular-ray apparatus, particularly electron microscopes, which during operation are continuously connected to a vacuum pump and have a specimen holder accommodating cartridge connected with a cryogenic cooling device.
  • connection of the specimen cartridge with the cryogenic device serves to reduce soiling of the object or, more accurately, to minimize the rate of soiling substantially down to zero.
  • soiling is caused by the specimen being coated with deposits stemming from residual hydrocarbon gases contained in the vacuum space of the corpuscular-ray apparatus and growing on the specimen under the effect of the corpuscular ray.
  • the coatings become troublesome, for example in electron microscopes, because they reduce the contrast of the microscopic image, tend to blur the contours of the electron-optical image, and to darken the image, thus aggravating the work to be done with the apparatus and often also prevent utilizing the degree of resolution otherwise attainable.
  • the specimen holder is accommodated within a cartridge which is "ice located in a cooling chamber formed of good heat-conducting walls heat-conductively connected with a lowtemperature cooling device.
  • a cooling chamber formed of good heat-conducting walls heat-conductively connected with a lowtemperature cooling device.
  • the vicinity of the specimen as well as the specimen itself are cooled down to temperatures near C.
  • This known device thus operates to cool the specimen as well as its environment.
  • Such a device indeed aifords a reduction in the rate of soiling down to the zero value.
  • difiiculties are often encountered because an excessive cooling is accompanied in most cases by greatly undesirable deterioration of the specimen, manifested essentially by removal of material therefrom.
  • Measurements have shown that there is a given temperature, dependent upon the particular specimen and the particular investigating conditions obtaining in the corpuscular-ray apparatus, at which the rate of soiling as well as the deterioration of the specimen will vanish.
  • This temperature can be adjusted only with great difficulty, not only on account of its dependency upon the particular specimen, but also because the rate of soiling and the specimen deterioration are not uniformly distributed over the specimen surface but are dependent upon the particular locality of the specimen surface under observation. Furthermore, undesired movements of the specimen due to thermal contraction of the cooled parts may occur.
  • a second known device for reducing the rate of soiling affords the advantage that no, or at least no appreciable, reduction of material from the specimen takes place and that no difficult temperature conditions are to be maintained.
  • the second device operates by cooling only the environment of the specimen down to a temperature beneath the approximate value of l30 C., whereas the specimen remains, at least approximately, at normal room temperature.
  • the favorable performance of this device can be explained by considering that the rate of soiling depends upon the atoms and molecules of hydrocarbons still contained in the residual gases within the vacuum space of the corpuscular-ray apparatus, whereas the reduction of the specimen is caused by molecules of water vapor. With a relatively warm specimen, the dwell time of the water molecules on the specimen is considerably shorter than on the surrounding surface areas, so that the latter have a pumping effect and greatly eliminate the danger of water molecules acting upon the specimen.
  • This second known device affords considerable advantages in practical operation because, below a temperature of the specimen environment of approximately l30 C., the reduction of the specimen is negligibly slight within a wide range of temperature. Consequently, cooling of the specimen environment to a temperature within a certain range affords keeping any soiling as well as any deterioration of the specimen in negligible limits.
  • the specimen holder accommodating cartridge consists of two mutually heatinsulated portions of which one contains the specimen holder and is in good heat-conducting connection therewith and also with parts of the corpuscular-ray apparatus that are at least approxmately at normal room temperature.
  • the second cartridge portion is heat-insulated from the specimen holder, surrounds the holder, and is in good heat-conducting connection with the cryogenic cooling device.
  • the specimen holder is located between at least two diaphragms which are in good heat-conducting connection through the second cartridge portion with the cryogenic device. This requires that the second cartridge portion be given a particular construction. It consists of a cup-shaped piece and a cover piece.
  • the cupshaped piece is connected with the cryogenic device, surrounds the specimen holder and also carries the assembly of diaphragms.
  • the cover piece matches the not cryogenically cooled first cartridge portion and is in interruptible heat-conducting contact with the cup-shaped piece. The possibility of interrupting or eliminating the heat-conducting contact between the cup-shaped piece and the cover piece is necessary because, when the specimen is to be exchanged and hence to be sluiced out of the vacuum chamber, the first cartridge portion and the correlated cover piece of the second, cooled cartridge portion must both be taken out of the corpuscular-ray apparatus.
  • the reason for this particular design of the second car tridge portion is the fact that the diaphragms mounted on opposite sides respectively of the specimen holder must also be cooled in order to realize the chamber principle, i.e., for providing a chamber having cryogenically cooled walls surrounding on all sides the specimen whose temperatures is substantially equal to normal room temperature.
  • This is achieved in the known device by having on the one hand the diaphragms mounted on the cup-shaped piece in heat-conducting connection therewith, and, on the other hand, by providing the cover piece with a heatconducting extension which reaches into the region of the specimen holder and holds the diaphragms on the other side of the specimen holder so as to connect them heatconductively with the cryogenic cooling device.
  • the application of the chamber principle in the known device thus makes it necessary to provide for a mutual geometric penetration of the first cartridge portion, being substantially at room temperature, relative to the second cartridge portion which is in heat-conducting connection with the cryogenic device. This is a difficult structural design requiring assembling and adjusting work of extremely high precision.
  • the described known device involves the danger that the cooled diaphragm arrangement which constitutes a covering of the cartridge space may be subjected to icing, which due to the proximity of the diaphragm arrangement to the lens field may result in disturbing astigmatism.
  • Our invention more particularly relates to a corpuscular-ray apparatus of the type last described, having a specimen cartridge formed of two mutually heat-insulated portions of which one contains the specimen holder and is in good heat-conducting connection therewith and with parts of the corpuscular-ray apparatus which are approximately at normal room temperature, whereas the second cartridge portion surrounding the specimen holder is heatinsulated therefrom and in gOOd heat-conducting connection with a low-temperature cooling device, and the speci men holder being located between at least two diaphragms.
  • Another object of the invention is to devise a specimen cartridge generally of the above-mentioned kind that facilitates exchanging a specimen by permitting the specimen-holder accommodating cartridge portion to be removed as a unit from the corpuscular-ray apparatus without affecting the mounting of the second cartridge portion in the apparatus.
  • Still another object of the invention is to provide for structural separation between the cryogenically cooled cartridge portion and the other cartridge portion so as to prevent occurrence of undesired displacements of the specimen.
  • a first cartridge portion aside from accommodating the specimen holder, also receives heat-conductively the diaphragm means located at one side of the specimen holder so that these diaphragm means are also at a temperature approximately corresponding to normal room temperature. Furthermore, the
  • first cartridge portion possesses lateral openings between these diaphragm means and the specimen holder, the openings being located in a region where the second cartridge portion surrounds the first cartridge portion.
  • the second, cooled cartridge portion can be effective to exhaust any atoms or molecules of gases or vapors as may be present between the diaphragm means and the specimen holder.
  • the chamber principle heretofore considered indispensable for effective reduction of specimen soiling, is done away with, and the cryogenic cooling of the diaphragm means located on one side of the specimen holder is likewise eliminated.
  • a diaphragm kept at room temperature does not retain atoms or molecules moving in the region of the diaphragm opening, the danger of specimen soiling is nevertheless avoided by virture of the fact that the first cartridge portion in its region between the diaphragms and the specimen holder within the cooled second cartridge portion possesses the above-mentioned openings.
  • the surface of the specimen holder facing the room-temperature diaphragm is opposite the cooled inner surfaces of the second cartridge portion, so that the latter exhaust any atoms and molecules as may have penetrated into the inter-space between the above-mentioned diaphragm means and the specimen holder.
  • the second cartridge portion is fastened to the objective lens of the corpuscular-ray apparatus such as an electron microscope, and the first cartridge portion is inserted into a specimen holder table and protrudes into the second cartridge portion within the region where the specimen holder and the above-mentioned openings are located.
  • the second cartridge portion, connected with the cryogenic device, may remain in the apparatus without eliminating this connection, even during exchange of a specimen.
  • the distance between the two cartridge portions are preferably made only as large as needed to permit the first cartridge portion to pass by the second cartridge portion during table displacing movement. In this manner, the penetration of atoms and molecules into the region of the specimen, as may result in soiling or deterioration of the specimen, is minimized or substantially prevented.
  • the second cartridge portion may be formed by the cooled parts of the lens, due to the fact that the second cartridge portion is permanently and fixedly arranged in the corpuscular-ray apparatus.
  • These lens parts may be constituted, for example, by one or both of the cooled pole shoes of a magnetic lens.
  • the lateral openings in the first cartridge portion between the diaphragms and the specimen holder may be provided, for example, by fastening the specimen holder to the first cartridge portion with the aid of a wire mesh having a suitable mesh width.
  • a simpler, more effective and often more stable way of providing for the openings is to fasten the specimen holder by means of heatconducting legs or struts to the first cartridge portion so that the specimen holder is virtually freely suspended within the second cartridge portion.
  • the openings are then constituted by the free spaces between the individual struts.
  • the struts may consist of wire or may be directly machined out of the material from which the first cartridge portion is formed.
  • the invention offers various possibilities. For example, the
  • diaphragms on the other side of the specimen holder may be heat-conductively mounted in the second cartridge portion so that they are in good heat-conducting connection through the second cartridge portion with the low-temperature cooling device, as in one of the above-described known arrangements.
  • the diaphragm temperature With this choice of the diaphragm temperature, however, there exists the above-mentioned danger of ice formation at the diaphragms. It is preferable, therefore, not to subject these diaphragms to cryogenic cooling and to heat-insulate them from the second cartridge portion, for example by heat-insulating inserts.
  • the diaphragm on the other side of the specimen holder is constituted by the lens-aperture diaphragm which is approximately at room temperature and axially spaced from the specimen holder, and if the second cartridge portion extends at least to the vicinity of this aperture diaphragm.
  • the second cartridge portion is extended beyond the aperture diaphragm to an area of slight postenlargement of the image in the apparatus, the second cartridge portion being provided with a lateral opening for the heatinsulated passage of the carrier for the aperture diaphragm.
  • the first cartridge portion can be taken out of the apparatus through a vacuum lock or similar device of conventional design for the purpose of exchanging a specimen.
  • This also applies to the low-temperature cooling device which is in good heat-conducting connection with the second cartridge portion.
  • a cryogenic device comprising in known manner a coolant vessel filled with liquid air or the like and having a cooling rod pressed against the second cartridge portion to maintain a good heat-conducting connection between the cryogenic medium and the second cartridge portion.
  • the cooling rod may be pressed elastically by spring means against the second cartridge portion.
  • a fixed or screwthread connection is also applicable because in the preferred embodiment of the invention the second cartridge portion remains fixedly mounted within the corpuscularray apparatus.
  • thermocouple may be mounted in known manner on the second cartridge portion to provide a voltage which is passed to the outside by means of leads extending along the cooling rod, thus affording an indication of the temperature of the second cartridge portion.
  • FIG. 1 shows an axial section of part of an electron microscope comprising an objective lens assemblywith a specimen cartridge.
  • FIG. 2 is a view from below onto a carrier for the specimen holder in a lens assembly according to FIG. 1.
  • FIG. 3 is a section along the line IIIIII in FIG. 2.
  • FIGS. 4 to 6 are axial sectional views of three other objective lens assemblies embodying the invention.
  • FIG. 7 shows partly in section a cryogenic device which forms part of any one of the electron microscope devices illustrated in FIG. 1 or in FIGS. 4 to 6.
  • the illustnated assembly of components is located in a vacuum vessel of an electron microscope having a vacuum pump in continuous operation to maintain the necessary vacuum during use of the microscope.
  • the assembly comprises circular pole shoes 1 and 2 of an objective lens systems 3 of the magnetic type.
  • the specimen cartridge 4 according to the invention is mounted above the lens 3 and comprises two cartridge portions 5 and 6.
  • the first cartridge portions 5 is approximately at normal room temperature, i.e., about 20 0, being inserted in a supporting table structure 7 of metal and in good heat-conducting contact therewith.
  • the table structure 7 is joined with the metallic wall of the vacuum vessel (not shown) thus maintaining the cartridge portion 5 approximately at ambient room temperature.
  • the second cartridge portion 6 is in good heat-conducting connection with a cooling rod 8 which extends laterally away from the illustrated assembly and has a portion 8' (FIG. 7) immersed in cryogenic medium, such as liquid air, contained in a coolant vessel as will be more fully described hereinafter.
  • cryogenic medium such as liquid air
  • the cooled cartridge portion 6 is fastened to the lens system 3 with the aid of heat-insulating inserts 9 (FIG. 1) consisting of sleeves of synthetic plastic, for example.
  • the first cartridge portion 5 comprises a conical top part 10 and two parts 12 and 13 which are coaxially fastened to the top part 10, being in threaded engagement therewith in the exemplified embodiment.
  • the part 12 constitutes the carrier proper for the specimen holder 14.
  • the part 13, inserted into the top part 10, serves as a holder for centrally apertured diaphragm 15.
  • the carrier 12 forms downwardly extending legs or struts 12a, 12b and 12c (FIGS. 1, 2, 3) whose lower ends have respective inwardly directed lugs for supporting the disc-shaped and centrally apertured specimen holder 14. While three struts are shown, a larger number of struts may be provided.
  • the diaphragm 15 located above the specimen holder 14 and being in good heat-conducting connection with the table structure 7 through the insert 13 and the conical part 10, is kept approximately at normal room temperature.
  • a second, centrally apertured diaphragm 16 on the opposite side of the specimen holder 14 is mounted on the second cartridge portion 6 and is approximately at the low temperature of the second cartridge portion which is in heat-conducting connection with the cooling rod 8.
  • the above-described embodiment further makes ap parent that, by virtue of the invention the structural unit of the first cartridge portion, containing the specimen holder, can be removed from the corpuscular-ray apparatus for exchanging the specimenan operation preferably performed by sluicing the first cartridge portion through a vacuum lock-without affecting the second cartridge portion which may remain undisturbed inside the apparatus.
  • the cooling of a diaphragm 16 entails some danger of ice formation due to precipitation of water vapor. Since this diaphragm is located in the gap between the two pole shoes 1 and 2 of the objective lens 3, such icing may be detrimental in causing or increasing astigmatism of the objective lens. For this reason, it is generally preferable that this diaphragm be no subjected to cryogenic cooling.
  • the diaphragm 16 is mounted on the second cartridge portion 6 with the aid of a thermally insulating insert plate 20.
  • the diaphragm 16 is virtually kept at room temperature and the specimen holder 14 is located between two diaphragms 15 and 16 which are both at least approximately at normal room temperature. In this case, however, some slight residual soiling of the specimen may have to be taken into account because a warm surface, constituted by the diaphragm 16, is located in proximity to the specimen.
  • the device according to FIG. 4 corresponds to the one described above with reference to FIGS. 1 to 3.
  • the aperture diaphragm 21 which normally forms part of the objective-lens system is used as a protective diaphragm on its side of the specimen holder 14 and the second cartridge portion 6 is downwardly extended into the region of the apertured diaphragm 21 so as to surround this diaphragm. Due to the fact that the slider 22 in which the apertured diaphragm 21 is in heatconducting connection with the wall structures of the corpuscular-ray apparatus, the diaphragm 21 is substantially at room temperature. Since it is spaced a larger distance from the object holder 14 than is the diaphragm 16 in FIG. 4, any remaining danger of the object becoming soiled is greatly reduced.
  • FIG. 6 fully eliminates the danger that the specimen and the lens-aperture diaphragm may become soiled and also virtually eliminates any detrimental effect of ice formation at the cooled diaphragm upon the image-forming quality of the lens.
  • the lens-aperture diaphragm 21 with its supporting slider 22 is at least approximately at room temperature, but the second cartridge portion 6 is downwardly extended a much greater distance than in the embodiment of FIG. 5, so that the aperture diaphragm 21 is surrounded by the cartridge portion 6 in substantially the same manner as the object holder 14. Consequently any soiling of the apertured diaphragm as well as any soiling of the specimen is prevented.
  • the passage 23 for the diaphragm slider 22 is designed and preferably provided with additional heat-insulating inserts for the purpose of preventing a heat-conducting connection between the second cartridge portion 6 and the aperture diaphragm 21.
  • Another heat-insulating insert 24 of annular shape surrounds the lower extension of the cartridge portion 6 also for the purpose of preventing a heat-conducting connection between the cartridge portion 6 and the surrounding wall structure 32 of the corpuscular-ray apparatus.
  • the extension of the cartridge portion 6 has such a length beyond the location of the aperture diaphragm 21 that the end 25 of the cartridge portion is located in a region of a slight post-enlargement of the image.
  • the end 25 may be located at the place where the first intermediate image in an electron microscope is formed. Any icing of the end 25 occurring in this region would no longer have a detrimental effect upon the quality of the image produced. This is predicated upon the requirement that the second cartridge portion 6 has a large cross section at its end 25 for the passage of the corpuscular ray. This, however, is in no way detrimental to the desired reduction in specimen soiling because the end 25 is too far remote from the specimen holder 14.
  • the cooling rod 8 establishes a connection of the cooled cartridge portion with a cryogenic vessel. This is exemplified by the cryogenic device shown in FIG. 7. The left end of the cooling rod 8 presses against the second cartridge portion 6 (not shown in FIG. 7). The right hand portion 8' of the cooling rod extends downwardly into a vessel 30 containing the cryogenic medium such as liquid air, liquid nitrogen or the like.
  • the vessel 30 is mounted in an insulating container 31 which is fastened to the wall 32 of the corpuscular-ray apparatus.
  • the cooling rod 8 passes through the wall 32 with the aid of suitable sealing and heat-insulating means such as shown at 33.
  • the invention is not limited to the particular embodiments illustrated. It is applicable with corpuscular-ray or particle beam apparatus other than electron microscopes and is not predicated upon providing the particular cryogenic device shown in FIG. 7. Instead of a specimen holder in form of a diaphragm as shown on the drawing, a mesh Work or other support for the specimen may be used. In some cases it is desirable or necessary to provide for good heat conductance between the table structure and/ or the diaphragm slider, on the one hand, and such other parts of the corpuscular-ray apparatus as are substantially at room temperature, on the other hand, by using additional heat-conducting means which do not interfere with the necessary displacing motion of the table structure or diaphragm slider. Suitable for this purpose, for example, are braided metal connectors. If necessary, such heatconducting connector means may also be in connection with additional heating devices.
  • a particle beam apparatus having wall structure forming a chamber, said wall structure being at the temperature of the surrounding atmosphere when the apparatus is in operation and having a vacuum space in said chamber; a cartridge assembly mounted in said chamber and having two coaxial and axially apertured cartridge portions, a first one of said cartridge portions being in thermally conductive connection with said chamber so as to be substantially at the temperature of said wall structure; cryogenic means connected with a second one of said cartridge portions for cooling it during said operation to a temperature below the temperature of said wall structure; a specimen holder and diaphragm means mounted on said first cartridge portion in coaxial relation thereto, said diaphragm means being axially spaced from said specimen holder on one side of said holder and being in thermally conductive connection with said first cartridge portion so as to be approximately at the temperature of said wall structure; and means for directing a particle beam through said first apertured cartridge portion onto a specimen held in said specimen holder; said second cartridge portion extending around said first cartridge portion in the region where said specimen holder is axially spaced
  • apparatus in apparatus according to claim 1, said first and second cartridge portions forming respective structural units, said unit of said first cartridge portion being removable from the apparatus for specimen exchange independently of said other unit.
  • Apparatus according to claim 1 comprising a magnetic lens mounted in coaxial relation to said cartridge assembly and connected with said cryogenic means to be cooled thereby, said lens forming part of said second cartridge portion.
  • said first cartridge portion having a main body and having mutually spaced heat-conducting struts extending from said main body, said specimen holder being suspended by said struts from said main body, and said openings being constituted by the interspaces between said struts.
  • Apparatus according to claim 1 comprising further diaphragm means coaxially located on the other side of said specimen holder from said diaphragm means on said first cartridge portion in axially spaced relation thereto and heat-conductively mounted on said second cartridge portion to be cooled by said cryogenic means.
  • Apparatus according to claim 1 comprising further diaphragm means coaxially located on the other side of said specimen holder from said diaphragm means on said first cartridge portion in axially spaced relation thereto, said further diaphragm means being thermally insulated from said second cartridge portion.
  • Apparatus according to claim 1 comprising further diaphragm means coaxially located on the other side of said specimen holder from said diaphragm means on said first cartridge portion in coaxially spaced relation thereto and mounted on said second cartridge portion, and heatinsulating means inserted between said further diaphragm means and said second cartridge portion.
  • Apparatus according to claim 1 comprising a lens having two annular pole shoes coaxialy spaced from each other, said first and second cartridge portions extending coaxially in one of said pole shoes, and said specimen holder and diaphragm means being located in the bore of said one annular pole shoe.
  • said lens having a lens-aperture diaphragm approximately at the temperature of said wall structure, said aperture diaphragm being located between said pole shoes in axially spaced relation to said specimen holder and separated therefrom by space free of structure, and said second cartridge portion having an extension surrounding said lens-aperture diaphragm.
  • said extension of said second cartridge portion having a lateral opening, said aperture diaphragm having a heat-conducting part passing through said opening in heat-insulated relation from said second cartridge portion, and said extension of said second cartridge portion extending beyond said aperture diaphragm to an area of slight post-enlargement of said lens.
  • said cryogenic means comprising a vessel for liquefied gaseous medium at cryogenic temperature, and a heat conducting rod structure having one end portion in said vessel to be immersed in said medium and having the other end in heat conducting engagement with said second cartridge portion.
  • a particle beam apparatus comprising a table structure having the temperature of the surrounding atmosphere when the apparatus is in operation; a cartridge assembly having two coaxial and axially apertured cartridge portions, a first one of said cartridge portions being inserted in said table structure and in thermally conductive contact therewith so as to be substantially at the temperature of said table structure; a specimen holder and diaphragm means mounted on said first cartridge portion, in coaxial relation thereto, said diaphragm means being axially spaced from said specimen holder on one side of said holder and being in thermally conductive connection with said first cartridge portion so as to be approximately at the temperature of said table structure; means for directing a particle beam through said first apertured cartridge portion onto a specimen held in said specimen holder; an objective lens fixedly mounted in the apparatus in coaxial relation to said cartridge assembly, said second cartridge portion being fastened to said objective lens; cryogenic means connected with said second cartridge portion for cooling it during said operation to a temperature below the temperature of said table struc ture, said second cartridge portion extending around said first
  • said specimen holder and diaphragm means being removably mounted in said first cartridge portion, and said first cartridge portion being removable for specimen exchange from said table stucture independently of said second cartridge portion.
  • said lens having pole shoes thremally connected with said cryogenic means to be cooled thereby, at least one of said pole shoes being integral with said second cartridge portion.

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US392088A 1963-09-09 1964-08-26 Particle beam apparatus with a cryogenically cooled specimen cartridge that is below the specimen holder temperature Expired - Lifetime US3387132A (en)

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DES87171A DE1202915B (de) 1963-09-09 1963-09-09 An der Pumpe arbeitender Korpuskularstrahl-apparat, insbesondere Elektronenmikroskop, mit einer den Objekttraeger aufnehmenden und mit einer Tiefkuehlvorrichtung in Verbindung stehenden Objektpatrone

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3526766A (en) * 1967-02-24 1970-09-01 Max Planck Gesellschaft Adjustable pole-shoe lens assembly for corpuscular ray devices and method for adjusting the same
US3558878A (en) * 1968-07-17 1971-01-26 Applied Res Lab Method of reducing specimen contamination in an electron probe by cooling the objective lens
US3973125A (en) * 1965-09-16 1976-08-03 Siemens Aktiengesellschaft Corpuscular-ray apparatus with a cryogenically cooled specimen space
US4179605A (en) * 1977-07-11 1979-12-18 Nihon Denshi Kabushiki Kaisha Cold trap for electron microscope
CN116859683A (zh) * 2023-08-31 2023-10-10 光科芯图(北京)科技有限公司 显微镜物镜热稳定性的控制装置及方法

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US2858444A (en) * 1954-07-14 1958-10-28 Siemens Ag Object-holding device for electron microscopes
US3124680A (en) * 1958-09-13 1964-03-10 Agent

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2858444A (en) * 1954-07-14 1958-10-28 Siemens Ag Object-holding device for electron microscopes
US3124680A (en) * 1958-09-13 1964-03-10 Agent

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US3973125A (en) * 1965-09-16 1976-08-03 Siemens Aktiengesellschaft Corpuscular-ray apparatus with a cryogenically cooled specimen space
US3526766A (en) * 1967-02-24 1970-09-01 Max Planck Gesellschaft Adjustable pole-shoe lens assembly for corpuscular ray devices and method for adjusting the same
US3558878A (en) * 1968-07-17 1971-01-26 Applied Res Lab Method of reducing specimen contamination in an electron probe by cooling the objective lens
US4179605A (en) * 1977-07-11 1979-12-18 Nihon Denshi Kabushiki Kaisha Cold trap for electron microscope
CN116859683A (zh) * 2023-08-31 2023-10-10 光科芯图(北京)科技有限公司 显微镜物镜热稳定性的控制装置及方法
CN116859683B (zh) * 2023-08-31 2023-11-28 光科芯图(北京)科技有限公司 显微镜物镜热稳定性的控制装置及方法

Also Published As

Publication number Publication date
NL6407801A (enrdf_load_stackoverflow) 1965-03-10
NL133028C (enrdf_load_stackoverflow) 1971-12-15
DE1202915B (de) 1965-10-14
GB1053169A (enrdf_load_stackoverflow) 1966-12-30

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