Patent Publication Number: US-2022232672-A1

Title: Electrode-embedded ceramic structure

Description:
TECHNICAL FIELD 
     The present specification discloses a technique relating to an electrode-embedded ceramic structure. 
     BACKGROUND ART 
     Japanese Patent Application Publication No. 2011-207222 (referred to as Patent Document 1, hereinafter) describes a ceramic structure with an electrode embedded therein (a pillar-shaped ceramic heater). In Patent Document 1, the electrode is firstly printed on a surface of a ceramic sheet. Then, the ceramic sheet is wrapped around a ceramic shaft while being pressed against the ceramic shaft to produce an intermediate in which the ceramic sheet is pressure bonded to the ceramic shaft. After this, the intermediate is fired to bond the ceramic sheet and the ceramic shaft, as a result of which the ceramic heater is produced. 
     SUMMARY OF INVENTION 
     As described, in Patent Document 1, the intermediate in which the ceramic sheet is pressure bonded to the ceramic shaft is fired. As a result, the ceramic sheet is bonded and integrated with the ceramic shaft, completing a structure in which the electrode is embedded in the ceramic. The ceramic heater of Patent Document 1 includes a structure in which a matrix (ceramic) has a different material (electrode) from the matrix embedded therein. Thus, the matrix may be degraded, such as the matrix being cracked, for example, due to a thermal expansion rate difference between the ceramic and the electrode. There is a need for improved durability (degradation control) of ceramic structures having an electrode embedded therein. The present specification aims to realize an electrode-embedded ceramic structure with improved durability. 
     Solution to Technical Problem 
     An electrode-embedded ceramic structure disclosed in the present specification may comprise a ceramic shaft, wherein an electrode is disposed on an outer circumference thereof; and a ceramic tube housing the ceramic shaft therein and coupled to the ceramic shaft. In this electrode-embedded ceramic structure, spaces may be provided locally between the ceramic shaft and the ceramic tube. 
    
    
     
       BRIEF DESCRIPTION OF DRAWINGS 
         FIG. 1  illustrates a schematic view (perspective view) of an electrode-embedded ceramic structure according to a first embodiment; 
         FIG. 2  illustrates a cross-sectional view along a line II-II in  FIG. 1 ; 
         FIG. 3  illustrates an enlarged view of an area enclosed by a broken line III in  FIG. 2 ; 
         FIG. 4  illustrates a cross-sectional view along a line IV-IV in  FIG. 2 ; 
         FIG. 5  illustrates a cross-sectional view along a line V-V in  FIG. 2 ; 
         FIG. 6  illustrates an enlarged view of an area enclosed by a broken line VI in  FIG. 5 ; 
         FIG. 7  illustrates a manufacturing process of the electrode-embedded ceramic structure; 
         FIG. 8  illustrates a variant of the electrode-embedded ceramic structure according to the first embodiment (in cross-sectional view); 
         FIG. 9  illustrates a cross-sectional view of an electrode-embedded ceramic structure according to a second embodiment; and 
         FIG. 10  illustrates a cross-sectional view along a line X-X in  FIG. 9 . 
     
    
    
     DESCRIPTION OF EMBODIMENTS 
     An electrode-embedded ceramic structure disclosed in the present specification may comprise a ceramic shaft, wherein an electrode is disposed on an outer circumference thereof; and a ceramic tube housing the ceramic shaft therein and coupled to the ceramic shaft. The electrode-embedded ceramic structure disclosed in the present specification is manufactured by preparing the ceramic shaft that has the electrode (wiring pattern) provided on the outer circumference and the ceramic tube separately, inserting the ceramic shaft into the ceramic tube, and firing this assembly. By firing the assembly with the ceramic shaft inserted in the ceramic tube, the ceramic shaft and the ceramic tube are bonded and thus integrated. That is, the electrode is embedded in the ceramic. In the ceramic shaft before insertion into the ceramic tube, the electrode may not be exposed at a surface (outer circumferential surface) of the ceramic shaft. For example, in the ceramic shaft before insertion into the ceramic tube, a surface of the electrode may be covered by a protection layer or the like. 
     In the electrode-embedded ceramic structure, spaces may be provided locally between the ceramic shaft and the ceramic tube. Here, “between the ceramic shaft and the ceramic tube” means an interface at which the outer surface of the ceramic shaft joins (contacts) an inner surface of the ceramic tube (inner wall of the tube) before they are bonded. The interface between the ceramic shaft and the ceramic tube can be identified, even after they have been bonded and integrated, based on a distance from the center axis or outer surface of the electrode-embedded ceramic structure, observation of a cross-sectional image of the electrode-embedded ceramic structure, the position of the electrode in a cross-sectional image, or the like. 
     A material of the ceramic shaft and the ceramic tube may be an alumina-containing material or a zirconia-containing material. Examples of the alumina-containing material include alumina (Al 2 O 3 ), mullite (Al 6 O 13 Si 2 ), spinel (MgAl 3 O 4 ), etc. Examples of the zirconia-containing material include zirconia (ZrO 2 ), zirconia-containing materials such as partially stabilized zirconia and stabilized zirconia to which yttria (Y 2 O 3 ), calcia (CaO), etc. are added as stabilizers, etc. A homogeneous material may be used (e.g., the ceramic shaft and the ceramic tube are constituted of alumina) or different materials may be used (e.g., the ceramic shaft is constituted of alumina and the ceramic tube is constituted of zirconia). It is preferable that the ceramic shaft and the ceramic tube are constituted of a homogeneous material to bond them favorably. 
     The ceramic shaft may have a solid cylinder shape or a hollow cylinder shape. That is, the ceramic shaft may be solid or hollow. In case of the ceramic shaft having a hollow cylinder shape, one end thereof may be closed (bottomed hollow cylinder), both ends thereof may be closed (hollow cylinder), or the both ends may be open. The ceramic shaft with its both ends open can be considered to include a through hole (first through hole) extending axially from one end to the other end. Providing the first through hole in the ceramic shaft allows matter (liquid such as water, a solid such as a metal wire) to be disposed within the ceramic shaft. 
     The electrode may be disposed on the outer circumference of the ceramic shaft. Providing the ceramic shaft with the electrode allows the electrode-embedded ceramic structure to be used as a heater (ceramic heater). In case of the ceramic shaft including the first through hole, matter can be disposed within the first through hole and be heated therein. For example, platinum (Pt), Au—Pt alloy containing gold (Au), etc. may be used as a material of the electrode. The electrode may be formed on the outer circumferential surface of the ceramic shaft by screen printing, vapor deposition, or the like. Further, a surface of the electrode may be covered by a protection layer after the electrode has been formed on the outer circumferential surface of the ceramic shaft. Although a material of the protection layer is not particularly limited, resin, ceramic, etc. can be used. 
     The ceramic tube may include a hole for housing the ceramic shaft (housing portion). Specifically, the ceramic tube may have a bottomed hollow cylinder shape including a bottom surface that contacts a longitudinal end surface of the ceramic shaft and an inner circumferential surface that contacts the outer circumferential surface of the ceramic shaft. Further, a through hole (second through hole) communicating with the outside of the ceramic tube may be defined in the bottom surface. In this case, the second through hole may communicate with the first through hole. That is, the ceramic tube may include the second through hole that extends from the housing portion in which the ceramic shaft is housed to the outside of the ceramic tube and communicates with the first through hole. In this case, the first through hole can be depressurized by suction of the first through hole via the second through hole. 
     Depressurizing the first through hole via the second through hole while matter is disposed within the first through hole allows for adsorption of another material (such as metal) to the matter disposed within the first through hole. That is, the first through hole and the second through hole allow the electrode-embedded ceramic structure to be used as a vacuum adsorption device. Further, as described, providing the ceramic shaft with the electrode allows the electrode-embedded ceramic structure to be used as a heater. Thus, by including the first through hole and the second through hole, the electrode-embedded ceramic structure can adsorb another substance to matter, while heating the matter. 
     In case of the electrode-embedded ceramic structure including the first through hole and the second through hole, the diameters of the first through hole and the second through hole may be the same or different. In case of the diameters of the first through hole and the second through hole being different, the diameter of the second through hole may be smaller than the diameter of the first through hole. As described, providing the ceramic shaft with the first through hole allows for placement of matter within the first through hole, heating thereof, and adsorption thereto. The diameter of the second through hole being smaller than the diameter of the first through hole reduces leakage of the matter disposed within the first through hole to the outside of the electrode-embedded ceramic structure. Further, in depressurizing (deaerating) the first through hole, a pressure decrease in the first through hole is further facilitated as the diameter of the second through hole is smaller. The outer shape of the ceramic tube may be any shape, and for example, may be a cylinder or polygonal prism. 
     In the state where the ceramic shaft is inserted in the ceramic tube, the entirety of the longitudinal end surface of the ceramic shaft may be in contact with the ceramic tube or a part thereof may not be in contact therewith. Similarly, in the state where the ceramic shaft is inserted in the ceramic tube, the entirety of the outer circumferential surface of the ceramic shaft may be in contact with the inner circumferential surface of the ceramic tube or a part thereof may not be in contact therewith. Here, “the state where the ceramic shaft is inserted in the ceramic tube” means a state prior to firing of the ceramic shaft and the ceramic tube to bond them. 
     For example, by providing the end surface of the ceramic shaft and/or the bottom surface of the ceramic tube with a recess, the end surface of the ceramic shaft can be partially non-contact with the bottom surface of the ceramic tube. Similarly, by providing the outer circumferential surface of the ceramic shaft and/or the inner circumferential surface of the ceramic tube with a recess, the outer circumferential surface of the ceramic shaft can be partially non-contact with the inner circumferential surface of the ceramic tube. By maintaining the ceramic shaft and the ceramic tube partially non-contact with each other in the state where the ceramic shaft is inserted in the ceramic tube, spaces are provided locally between the ceramic shaft and the ceramic tube. 
     Further, a pore-forming material may be added to the ceramic shaft and/or the inside of the ceramic tube, and the pore-forming material may be eliminated upon firing the electrode-embedded ceramic structure (the ceramic shaft and the ceramic tube). This method can also provide spaces locally between the ceramic shaft and the ceramic tube. Polymer particles, carbon particles, etc. can be used as the pore-forming material. A space volume (space ratio) of the entire electrode-embedded ceramic structure and a space volume (space ratio) between the ceramic shaft and the ceramic tube can be controlled by adjusting the kind of pore-forming material (material, particle size) and an amount of the pore-forming material to be added. 
     Further, spaces can also be provided between the ceramic shaft and the ceramic tube by controlling a firing condition for the electrode-embedded ceramic structure (firing temperature, firing time, etc.) as well. As described, the electrode-embedded ceramic structure disclosed in the present specification is manufactured by preparing the ceramic shaft and the ceramic tube separately, inserting the ceramic shaft into the ceramic tube, and then firing the assembly. Thus, before firing (in the state where the ceramic shaft is inserted in the ceramic tube), there is a distinct interface between the ceramic shaft and the ceramic tube. Then, during firing, bonding progresses at the interface between the ceramic shaft and the ceramic tube, and thus they are integrated. By controlling the firing condition, a degree of the bonding (progress of the bonding) between the ceramic shaft and the ceramic tube can be controlled and spaces can be provided at parts between the ceramic shaft and the ceramic tube. 
     As described, in the electrode-embedded ceramic structure disclosed in the present specification, spaces are provided locally between the ceramic shaft and the ceramic tube. Thus, for example, when the electrode generates heat or when the electrode-embedded ceramic structure is heated, a force applied from the electrode to the ceramic can be mitigated by the spaces between the ceramic shaft and the ceramic tube. Specifically, it is possible to suppress cracks in the ceramic (the ceramic shaft and the ceramic tube) caused by a thermal expansion rate difference between the matrix (the ceramic) and the electrode. Providing spaces between the ceramic shaft and the ceramic tube allows for improved durability of the electrode-embedded ceramic structure. 
     The space volume (space ratio) between (at the interface between) the ceramic shaft and the ceramic tube can be determined from an image of a cross section of the electrode-embedded ceramic structure (a cross section along a plane including the ceramic shaft or a cross section along a plane perpendicular to the ceramic shaft). Specifically, a SEM image of a cross section of the ceramic structure is firstly obtained to identify the interface between the ceramic shaft and the ceramic tube. Then, an area of the spaces per 1 μm of the interface length is measured. The area of the spaces can be calculated, for example, by image-processing the obtained SEM image by ITEM analysis software (manufactured by Seika Corporation). The area of the spaces per 1 μm of the interface length (space area/μm) may be 0.3 μm 2  or more. With the space area of 0.3 μm 2 , the force applied from the electrode to the ceramic is sufficiently mitigated, and thus the electrode-embedded ceramic structure can have improved durability. 
     The space area at the interface of the ceramic shaft and the ceramic tube may be 0.5 μm 2  or more, 1 μm 2  or more, 1.5 μm 2  or more, or 2 μm 2  or more. The force applied to the ceramic is further mitigated as the space area per 1 μm of the interface length is larger. Further, the space area at the interface between the ceramic shaft and the ceramic tube may be 5 μm 2  or less. With the space area of 5 μm 2  or less, the ceramic shaft and the ceramic tube are sufficiently joined (bonded) and thus separation of the ceramic shaft from the ceramic tube due to an impact can be prevented. The space area at the interface between the ceramic shaft and the ceramic tube may be 4.5 μm 2  or less, 4 μm 2  or less, 3.5 μm 2  or less, or 3 μm 2  or less. 
     It is preferable that the spaces are uniformly distributed over the interface between the ceramic shaft and the ceramic tube. For example, when the interface between the end surface of the ceramic shaft and the ceramic tube is equally divided into four sections in an image of a cross section along a plane including the axis of the ceramic shaft, it is preferable that the spaces are observed in two or more sections of the four sections. It is more preferable that the spaces are observed in all of the four sections. Further, where the interface between a side surface (outer circumferential surface) of the ceramic shaft and the ceramic tube is equally divided into four sections (except for a portion where the electrode is disposed) in the same cross-sectional image, it is preferable that the spaces are observed in two or more sections, and it is more preferable that the spaces are observed in all of the four sections. Similarly, where the interface is equally divided into four sections (except for the portion where the electrode is disposed) in a cross section along a plane perpendicular to the axis of the ceramic shaft, it is preferable that the spaces are observed in two or more sections, and it is more preferable that the spaces are observed in all of the four sections. 
     EMBODIMENTS 
     First Embodiment 
     Referring to the drawings, a ceramic structure  50  is described. The ceramic structure  50  is an example of the electrode-embedded ceramic structure. The ceramic structure  50  is used as a ceramic heater. As illustrated in  FIGS. 1 and 2 , the ceramic structure  50  comprises a ceramic shaft  20  that has a solid cylinder shape and has electrodes  22  disposed on an outer circumference (outer circumferential surface) thereof and a ceramic tube  10  that has a bottomed hollow cylinder shape. The outer shape of the ceramic tube  10  is substantially cylindrical, however, its end portion at an end has a substantially conical shape with its diameter decreasing toward the end. The ceramic shaft  20  is housed in the ceramic tube  10 . The ceramic shaft  20  and the ceramic tube  10  are constituted of alumina, and are bonded and integrated with each other. Thus, the electrodes  22  are embedded in the ceramic. 
       FIG. 3  is a part of a cross section including the axis of the ceramic shaft  20  (longitudinal cross section) and an enlarged view of a broken-line area III in  FIG. 2 . As illustrated in  FIG. 3 , spaces  40  are provided at intervals at an interface between the ceramic shaft  20  and the ceramic tube  10 . The spaces  40  are distributed almost uniformly over the interface between the ceramic shaft  20  and the ceramic tube  10 . At portions where no spaces  40  are provided, the ceramic shaft  20  and the ceramic tube  10  are bonded. In  FIG. 3 , the spaces  40  are depicted in relatively large size and in a schematic manner to assist in understanding features of the ceramic structure  50 . In actuality, the spaces do not have a specific shape and vary in size. 
       FIG. 4  illustrates a cross section perpendicular to the axis of the ceramic shaft  20  (radial cross section) and illustrates a cross section along a line IV-IV in  FIG. 2 . As apparent from  FIG. 4 , the ceramic shaft  20  has a solid structure. As illustrated in  FIG. 4 , in a circumferential direction of the ceramic shaft  20  as well, the spaces  40  are provided at intervals and almost uniformly over the interface between the ceramic shaft  20  and the ceramic tube  10 . In other words, bonded portions  42  where the ceramic shaft  20  and the ceramic tube  10  are bonded are provided at intervals and almost uniformly in the circumferential direction of the ceramic shaft  20 . This mitigates a circumferential local concentration of internal stress caused when the ceramic structure  50  was fired (shrink fitted). In  FIG. 4  as well, the spaces  40  are schematically depicted in relatively large size. 
       FIG. 5  illustrates a cross section perpendicular to the axis of the ceramic shaft  20  (radial cross section) for portions where the electrodes  22  are disposed and illustrates a cross section along a line V-V in  FIG. 2 . In  FIG. 5 , the spaces at the interface between the ceramic shaft  20  and the ceramic tube  10  are not illustrated to clearly show the state of the electrodes  22 . As illustrated in  FIG. 5 , front and rear surfaces of the electrodes  22  contact the ceramic (the ceramic shaft  20  and the ceramic tube  10 ). That is, the electrodes  22  are embedded in the ceramic configuring the ceramic structure  50 . In the ceramic structure  50 , the electrodes  22  do not fully circumferentially extend, and there are portions between the electrodes  22 ,  22  where the ceramic shaft  20  and the ceramic tube  10  are bonded. 
       FIG. 6  is an enlarged view of a border between a portion where an electrode  22  is disposed and a portion where no electrodes  22  are disposed (contact portion between the ceramic shaft  20  and the ceramic tube  10 ) and illustrates an area enclosed by a broken line VI in  FIG. 5 . As shown in  FIG. 6 , no spaces are observed at an interface between the electrode  22  and the ceramic shaft  20  and at an interface between the electrode  22  and the ceramic tube  10 . On the other hand, the spaces  40  are observed at intervals at the interface between the ceramic shaft  20  and the ceramic tube  10 . 
     As illustrated in  FIGS. 3 to 6 , in the ceramic structure  50 , the spaces  40  are provided at intervals and almost uniformly over the interface between the ceramic shaft  20  and the ceramic tube  10 . Thus, the spaces  40  can reduce a force applied to the ceramic due to a thermal expansion rate difference between the electrodes  22  and the ceramic. On the other hand, no spaces are provided between the electrodes  22  and the ceramic. This prevents heat transfer between the electrodes  22  and the ceramic upon heat generation by the electrodes  22  from being cut off, realizing a heater with high responsivity (the temperature of the ceramic changes responsively according to temperature change of the electrodes  22 ). 
     Referring to  FIG. 7 , a manufacturing method of the ceramic structure  50  is described. For the ceramic structure  50 , firstly the ceramic shaft  20  that is constituted of alumina and has the electrodes (Pt electrodes)  22  vapor deposited on its surface was prepared, the ceramic tube  10  constituted of alumina in which a hole (bottomed hole)  12  is provided at the center was prepared separately from the ceramic shaft  20 , and the ceramic shaft  20  was inserted into the hole  12 . That is, the hole  12  is a housing portion for housing the ceramic shaft  20 . The ceramic shaft  20  was inserted until its end surface contacts the bottom of the hole  12 . The diameter of the hole  12  is constant from its one end to the other end, and is substantially equal to the diameter of the ceramic shaft  20 . Thereafter, firing was performed at 1600° C. in the atmosphere, resulting in the ceramic structure  50 . For the ceramic structure  50 , images of cross sections shown in  FIGS. 3 to 5  were captured, and it was observed that spaces were provided almost uniformly over the interface between the ceramic shaft  20  and the ceramic tube  10 . Further, as a result of measurement for an area of the spaces per 1 μm of an interface length over 100 μm of the interface, the area of the spaces was 0.3 μm 2 /μm. 
     A characteristic (durability) of the ceramic structure  50  was evaluated. Specifically, a test (thermal shock test) was conducted where one cycle of the test incudes a process of: repeatedly changing a voltage applied to the electrodes  22 ; increasing the temperature of the ceramic structure  50  to 600° C. in 10 seconds; and cooling it to 100° C. in 20 seconds. As a comparative example, a ceramic structure was manufactured in a conventional manufacturing method, that is, by preparing a ceramic sheet that is constituted of alumina and has Pt electrodes printed on its surface, wrapping the ceramic sheet around a ceramic shaft constituted of alumina while pressing the ceramic shaft against the ceramic sheet, and then firing the assembly at 1600° C. in the atmosphere. In the ceramic structure of the comparative example, the interface between the ceramic sheet and the ceramic shaft were entirely bonded and spaces were hardly observed at the interface. Specifically, the area of spaces was less than 0.01 μm 2 /μm. 
     As a result of the test above, the ceramic structure of the comparative example had cracks at the interface between the ceramic sheet and the ceramic shaft in 20 th  cycle. On the other hand, in the ceramic structure  50 , no cracks were observed at the interface between the ceramic shaft  20  and the ceramic tube  10  even after 100 cycles. It has been confirmed that in the ceramic structure  50 , the spaces  40  between the ceramic shaft  20  and the ceramic tube  10  mitigate thermal shock due to the thermal expansion rate difference between the electrodes  22  and the ceramic (the ceramic shaft  20  and the ceramic tube  10 ) and suppress degradation of the ceramic. 
     In the embodiment above, the ceramic structure  50  is described as including the ceramic tube  10  in which the hole  12 , of which diameter is constant from its one end to the other end, is defined. However, such as a ceramic structure  50   a  illustrated in  FIG. 8 , a ceramic tube  10   a  in which the hole  12  includes a recess  14  at a bottom surface  12   a  and a plurality of recesses  16  at an inner circumferential surface  12   b  can be used. The recesses  16  extend entirely on the inner circumferential surface of the ceramic tube  10   a . By providing the recess  14 , a space is surely provided between the ceramic shaft  20  and the ceramic tube  10   a  at the end surface of the ceramic shaft  20 . Similarly, by providing the recesses  16 , spaces are surely provided between the ceramic shaft  20  and the ceramic tube  10   a  at the outer circumferential surface of the ceramic shaft  20 . 
     As a variant of the ceramic structure  50   a , only the recess  14  may be provided and the recesses  16  may not be provided, or the recess  14  may not be provided and only the recesses  16  may be provided. Further, the recesses  16  may not entirely extend on the inner circumferential surface of the ceramic tube  10   a , for example, may be provided at intervals in the circumferential direction. Alternatively, the recesses  16  may be provided to face the ceramic shaft  20  in portions where the electrodes  22  are not provided. 
     Second Embodiment 
     Referring to  FIGS. 9 and 10 , a ceramic structure  50   b  is described. The ceramic structure  50   b  is a variant of the ceramic structure  50 , and comprises a ceramic shaft  20   b  and a ceramic tube  10   b  including through holes, which is different from the ceramic shaft  20  and the ceramic tube  10  of the ceramic structure  50 . Elements of the ceramic structure  50   b  that are substantially the same as those of the ceramic structure  50  are denoted with the same reference signs as those used for the ceramic structure  50  and descriptions for these elements may be omitted.  FIG. 9  corresponds to the cross section illustrated in  FIG. 2  in connection with the ceramic structure  50 , and  FIG. 10  corresponds to the cross section illustrated in  FIG. 5  in connection with the ceramic structure  50 . 
     As illustrated in  FIG. 9 , the ceramic shaft  20   b  includes a first through hole  24  axially extending from one end to the other end. That is, the ceramic shaft  20   b  has a hollow structure. As illustrated in  FIG. 10 , the first through hole  24  is open at both axial ends. The diameter of the first through hole  24  is adjusted to 200 to 3000 μm (may be 200 to 1000 μm). Further, the electrodes  22  are disposed on the outer circumferential surface of the ceramic shaft  20   b  at intervals circumferentially. The electrodes  22  are embedded in a ceramic resulting from the ceramic shaft  20   b  and the ceramic tube  10   b  being bonded and integrated. 
     The ceramic tube  10   b  includes a second through hole  18  extending from the bottom (surface contacting the axial end surface of the ceramic shaft  20   b ) of the hole (housing portion)  12  to the outside of the ceramic tube  10   b . The second through hole  18  communicates with the first through hole  24 . The diameter of the second through hole  18  is adjusted to 20 to 1000 μm (may be 20 to 300 μm). That is, the diameter of the second through hole  18  may be smaller than the diameter of the first through hole  24 . The ceramic structure  50   b  can be considered to include a through hole extending axially from its one end to the other end (the first through hole  24  and the second through hole  18 ). 
     With matter (liquid, solid) disposed within the first through hole  24 , the ceramic structure  50   b  can be used as a heater for heating the matter. Further, the ceramic structure  50   b  can be used as a vacuum adsorption device that adsorbs another substance to the matter within the first through hole  24  by depressurizing the first through hole  24  though deaeration of gas in the first through hole  24  via the second through hole  18 . In this case, it is possible to adsorb another substance to the matter while heating the matter within the first through hole  24  by turning on the heater. Typically, the higher the temperature of the matter becomes, the faster the adsorption rate becomes. The ceramic structure  50   b  can be used as a vacuum adsorption device with a heater. 
     As a variant of the ceramic structure  50   b , a configuration may be employed in which the ceramic shaft  20   b  includes the first through hole  24  and the ceramic tube  10   b  does not include the second through hole  18  (i.e., a configuration in which the ceramic tube  10  is used instead of the ceramic tube  10   b ). Such a configuration can also allow for placement of matter within the first through hole  24  and heating thereof. The diameters of the first through hole  24  and the second through hole  18  can be varied appropriately depending on the purpose, for example, the diameters of the first through hole  24  and the second through hole can be equal to each other. 
     While specific examples of the present disclosure have been described above in detail, these examples are merely illustrative and place no limitation on the scope of the patent claims. The technology described in the patent claims also encompasses various changes and modifications to the specific examples described above. The technical elements explained in the present description or drawings provide technical utility either independently or through various combinations. The present disclosure is not limited to the combinations described at the time the claims are filed. Further, the purpose of the examples illustrated by the present description or drawings is to satisfy multiple objectives simultaneously, and satisfying any one of those objectives gives technical utility to the present disclosure.