Patent ID: 12198857

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will be described with reference to the accompanying drawings. In the drawings, the same or corresponding portions are denoted by the same reference numerals.

Multilayer Ceramic Capacitor

FIG.1is a perspective view showing a multilayer ceramic capacitor according to a preferred embodiment of the present invention.FIG.2is a cross-sectional view taken along the line II-II of the multilayer ceramic capacitor shown inFIG.1. FIG.3is a cross-sectional view taken along the line III-III of the multilayer ceramic capacitor shown inFIG.1. The multilayer ceramic capacitor1shown inFIGS.1to3includes a multilayer body10and external electrodes40. The external electrodes40include a first external electrode41and a second external electrode42.

FIGS.1to3each show an XYZ orthogonal coordinate system. The X direction refers to the length direction L of the multilayer ceramic capacitor1and the multilayer body10, the Y direction refers to the width direction W of the multilayer ceramic capacitor1and the multilayer body10, and the Z direction refers to the lamination (stacking) direction T of the multilayer ceramic capacitor1and the multilayer body10. Thus, the cross section shown inFIG.2is also referred to as a cross section LT, and the cross section shown inFIG.3is also referred to as a cross section WT.

The length direction L, the width direction W, and the lamination direction T are not necessarily orthogonal or substantially orthogonal to each other, and may intersect each other.

The multilayer body10includes a rectangular or substantially rectangular parallelepiped shape, and includes a first main surface TS1 and a second main surface TS2 which are opposed to each other in the lamination direction T, a first side surface WS1 and a second side surface WS2 which are opposed to each other in the width direction W, and a first end surface LS1 and a second end surface LS2 which are opposed to each other in the length direction L.

The corners and ridges of the multilayer body10are preferably rounded. The corners are each a portion where the three surfaces of the multilayer body10intersect, and the ridges are each a portion where the two surfaces of the multilayer body10intersect.

As shown inFIGS.2and3, the multilayer body10includes a plurality of dielectric layers20and a plurality of internal electrode layers30laminated in the lamination direction T. Furthermore, the multilayer body10includes an inner layer portion100, and a first outer layer portion101and a second outer layer portion102that sandwich the inner layer portion100in the lamination direction T.

The inner layer portion100includes a portion of the plurality of dielectric layers20and a plurality of internal electrode layers30. In the inner layer portion100, the plurality of internal electrode layers30are opposed to each other with the dielectric layers20interposed therebetween. The inner layer portion100generates capacitance and substantially defines and functions as a capacitor.

The first outer layer portion101is provided adjacent to the first main surface TS1 of the multilayer body10, and the second outer layer portion102is provided adjacent to the second main surface TS2 of the multilayer body10. More specifically, the first outer layer portion101is provided between the internal electrode layer30closest to the first main surface TS1 of the plurality of internal electrode layers30and the first main surface TS1, and the second outer layer portion102is provided between the internal electrode layer30closest to the second main surface TS2 of the plurality of internal electrode layers30and the second main surface TS2. The first outer layer portion101and the second outer layer portion102do not include the internal electrode layers30, but include portions of the plurality of dielectric layers20other than portions for the inner layer portion100. The first outer layer portion101and the second outer layer portion102define and function as protective layers of the inner layer portion100.

As a material of the dielectric layers20, for example, a dielectric ceramic including BaTiO3, CaTiO3, SrTiO3, CaZrO3, or the like as a main component can be used. Furthermore, as a material of the dielectric layers20, for example, a Mn compound, an Fe compound, a Cr compound, a Co compound, a Ni compound, or the like may be added as a subcomponent.

The thickness of the dielectric layer20is not particularly limited, but is preferably, for example, about 0.40 μm or more and about 0.50 μm or less, and more preferably about 0.40 μm or more and about 0.45 μm or less. The number of dielectric layers20is not particularly limited, but is preferably, for example, 100 or more and 2000 or less. The number of the dielectric layers20refers to a total number of the number of the dielectric layers of the inner layer portion and the number of the dielectric layers of the outer layer portions.

The plurality of internal electrode layers30include a plurality of first internal electrode layers31and a plurality of second internal electrode layers32. The plurality of first internal electrode layers31and the plurality of second internal electrode layers32are alternately provided in the lamination direction T of the multilayer body10.

The first internal electrode layers31each include a counter electrode portion311and an extension electrode portion312, and the second internal electrode layers32each include a counter electrode portion321and an extension electrode portion322.

The counter electrode portion311and the counter electrode portion321are opposed to each other with a dielectric layer20interposed therebetween in the lamination direction T of the multilayer body10. The shapes of the counter electrode portion311and the counter electrode portion321are not particularly limited, and may be rectangular or substantially rectangular, for example. The counter electrode portion311and the counter electrode portion321are portions which substantially define and function as capacitors for generating capacitances.

The extension electrode portions312each extend from the counter electrode portion311toward the first end surface LS1 of the multilayer body10, and are each exposed at the first end surface LS1. The extension electrode portions322each extend from the counter electrode portion321toward the second end surface LS2 of the multilayer body10, and are each exposed at the second end surface LS2. The shapes of the extension electrode portion312and the extension electrode portion322are not particularly limited, and may be rectangular or substantially rectangular, for example.

Thus, the first internal electrode layers31are each connected to the first external electrode41, and a gap exists between each of the first internal electrode layers31and the second end surface LS2 of the multilayer body10, i.e., the second external electrode42. Furthermore, the second internal electrode layers32are each connected to the second external electrode42, and a gap exists between each of the second internal electrode layers32and the first end surface LS1 of the multilayer body10, i.e., the first external electrode41.

The first internal electrode layer31and the second internal electrode layer32include, for example, Ni as a main component. Furthermore, the first internal electrode layer31and the second internal electrode layer32may include, for example, at least one selected from metals such as Cu, Ag, Pd, and Au or alloys including at least one of these metals such as Ag—Pd alloy as a main component, or may include a component other than the main component. Furthermore, the first internal electrode layer31and the second internal electrode layer32may include, for example, dielectric particles having the same composition as the ceramic included in the dielectric layer20as components other than the main component. In the present disclosure, the metal of the main component is defined as a metal component having the highest weight %.

The thicknesses of the first internal electrode layer31and the second internal electrode layer32are not particularly limited, but are preferably, for example, about 0.30 μm or more and about 0.40 μm or less, and more preferably about 0.30 μm or more and about 0.35 μm or less. The number of the first internal electrode layers31and the second internal electrode layers32is not particularly limited, but is preferably, for example, 10 or more and 1000 or less.

As shown inFIG.3, the multilayer body10includes an electrode counter portion W30in which the internal electrode layers30are opposed to each other in the width direction W, and a first side gap portion WG1 and a second side gap portion WG2 that sandwich the electrode counter portion W30. The first side gap portion WG1 is positioned between the electrode counter portion W30and the first side surface WS1, and the second side gap portion WG2 is positioned between the electrode counter portion W30and the second side surface WS2. More specifically, the first side gap portion WG1 is positioned between the end of the internal electrode layer30adjacent to the first side surface WS1 and the first side surface WS1, and the second side gap portion WG2 is positioned between the end of the internal electrode layer30adjacent to the second side surface WS2 and the second side surface WS2. The first side gap portion WG1 and the second side gap portion WG2 do not include the internal electrode layers30, and include only the dielectric layers20. The first side gap portion WG1 and the second side gap portion WG2 are portions functioning as protective layers of the internal electrode layer30. The first side gap portion WG1 and the second side gap portion WG2 are each also referred to as a W gap.

As shown inFIG.2, the multilayer body10includes an electrode counter portion L30in which the first internal electrode layers31and the second internal electrode layers32of the internal electrode layer30are opposed to each other in the length direction L, a first end gap portion LG1, and a second end gap portion LG2. The first end gap portion LG1 is positioned between the electrode counter portion L30and the first end surface LS1, and the second end gap portion LG2 is positioned between the electrode counter portion L30and the second end surface LS2. More specifically, the first end gap portion LG1 is positioned between the ends of the second internal electrode layers32adjacent to the first end surface LS1 and the first end surface LS1, and the second end gap portion LG2 is positioned between the ends of the first internal electrode layer31adjacent to the second end surface LS2 and the second end surface LS2. The first end gap portion LG1 does not include the second internal electrode layers32and includes the first internal electrode layers31and the dielectric layers20, and the second end gap portion LG2 does not include the first internal electrode layers31and includes the second internal electrode layers32and the dielectric layers20. The first end gap portion LG1 functions as an extension electrode portion toward the first end surface LS1 of the first internal electrode layers31, and the second end gap portion LG2 functions as an extension electrode portion to the second end surface LS2 of the second internal electrode layers32. The first end gap portion LG1 and the second end gap portion LG2 are each also referred to as an L gap.

The counter electrode portions311of the first internal electrode layers31and the counter electrode portions321of the second internal electrode layers32are positioned in the electrode counter portion L30. Furthermore, the extension electrode portions312of the first internal electrode layers31are positioned in the first end gap portion LG1, and the extension electrode portions322of the second internal electrode layers32are positioned in the second end gap portion LG2.

The dimensions of the multilayer body10are not particularly limited, but, for example, the length in the length direction L is preferably about 0.05 mm or more and about 1.00 mm or less, the width in the width direction W is preferably about 0.10 mm or more and about 0.50 mm or less, and the thickness in the lamination direction T is preferably about 0.10 mm or more and about 0.50 mm or less. In the multilayer body10, when the dimension in the length direction L is defined as L1, the dimension in the width direction W is defined as W1, and the dimension in the lamination direction T is defined as T1, L1>T1>W1 may be satisfied. As a result, it is possible to obtain a multilayer ceramic capacitor having a higher height and a large T1 while satisfying the predetermined L1 and W1, and it is possible to achieve a reduction in size and a higher capacitance.

As a method of measuring the thicknesses of the dielectric layers20and the internal electrode layers30, for example, there is a method of observing the cross section LT in the vicinity of the center in the width direction of the multilayer body exposed by polishing with a scanning electron microscope. Furthermore, each value may be an average value of measurement values at a plurality of positions in the length direction, or may be an average value of measurement values at a plurality of positions in the lamination direction.

Similarly, as a method of measuring the thickness of the multilayer body10, for example, there is a method of observing with a scanning electron microscope the cross section LT in the vicinity of the center in the width direction of the multilayer body exposed by polishing or the cross section WT in the vicinity of the center in the length direction of the multilayer body exposed by polishing. Furthermore, each value may be an average value of measurement values at a plurality of positions in the length direction or the width direction. Similarly, as a method of measuring the length of the multilayer body10, for example, there is a method of observing the cross section LT in the vicinity of the center in the width direction of the multilayer body exposed by polishing with a scanning electron microscope. Furthermore, each value may be an average value of measurement values at a plurality of locations in the lamination direction. Similarly, as a method of measuring the width of the multilayer body10, for example, there is a method of observing with a scanning electron microscope the cross section WT in the vicinity of the center in the length direction of the multilayer body exposed by polishing. Furthermore, each value may be an average value of measurement values at a plurality of locations in the lamination direction.

The external electrodes40include the first external electrode41and the second external electrode42.

The first external electrode41is provided on the first end surface LS1 of the multilayer body10and is connected to the first internal electrode layers31. The first external electrode41may extend from the first end surface LS1 to a portion of the first main surface TS1 and a portion of the second main surface TS2. Furthermore, the first external electrode41may extend from the first end surface LS1 to a portion of the first side surface WS1 and a portion of the second side surface WS2.

The second external electrode42is provided on the second end surface LS2 of the multilayer body10and is connected to the second internal electrode layers32. The second external electrode42may extend from the second end surface LS2 to a portion of the first main surface TS1 and a portion of the second main surface TS2. The second external electrode42may extend from the second end surface LS2 to a portion of the first side surface WS1 and a portion of the second side surface WS2.

The first external electrode41includes a first base electrode layer415and a first plated layer416, and the second external electrode42includes a second base electrode layer425and a second plated layer426. The first external electrode41may include only the first plated layer416, and the second external electrode42may include only the second plated layer426.

The first base electrode layer415and the second base electrode layer425may be fired layers including, for example, metal and glass. Examples of the glass include glass components containing at least one selected from B, Si, Ba, Mg, Al, Li, and the like. As a specific example, borosilicate glass can be used. The metal includes, for example, Cu as a main component. For example, the metal may include at least one selected from metals such as Ni, Ag, Pd, or Au or alloys such as Ag—Pd alloy as a main component, or may include a component other than the main component.

The fired layer is a layer obtained by applying a conductive paste including a metal and glass to a multilayer body by, for example, a dipping method and firing the multilayer body. The firing may be performed after firing the internal electrode layer, or may be performed simultaneously with the internal electrode layer. The fired layer may include a plurality of layers.

Alternatively, the first base electrode layer415and the second base electrode layer425may each be, for example, a resin layer including electrically conductive particles and a thermosetting resin. The resin layer may be provided on the fired layer described above, or may be provided directly on the multilayer body without providing the fired layer.

The resin layer is a layer obtained by applying an electrically conductive paste including electrically conductive particles and a thermosetting resin to a multilayer body by, for example, a coating method and firing the multilayer body. The firing may be performed after firing the internal electrode layers, or may be performed simultaneously with the internal electrode layers. The resin layer may include a plurality of layers.

The thickness per layer of each of the first base electrode layer415and the second base electrode layer425defining and functioning as a fired layer or a resin layer is not particularly limited, and may be, for example, about 1 μm or more and about 10 μm or less.

Alternatively, the first base electrode layer415and the second base electrode layer425may be formed by a thin film formation method such as, for example, a sputtering method or a deposition method, and may be a thin film layer having a thickness of, for example, about 1 μm or less in which metal particles are deposited.

The first plated layer416covers at least a portion of the first base electrode layer415, and the second plated layer426covers at least a portion of the second base electrode layer425. Examples of the first plated layer416and the second plated layer426include at least one selected from metals such as Cu, Ni, Ag, Pd, or Au, or alloys such as an Ag—Pd alloy.

Each of the first plated layer416and the second plated layer426may include a plurality of layers. A two-layer structure including, for example, Ni plating and Sn plating is preferable. The Ni-plated layer can prevent the base electrode layer from being eroded by solder when the ceramic electronic component is mounted, and the Sn-plated layer can improve wettability of the solder when the ceramic electronic component is mounted, and thus can be easily mounted.

The thickness per layer of each of the first plated layer416and the second plated layer426is not particularly limited, and may be, for example, about 1 μm or more and about 10 μm or less.

As shown inFIGS.1to3, in the mounting structure of the multilayer ceramic capacitor1, the multilayer ceramic capacitor1is mounted on a circuit board CB such that the second main surface TS2 faces the circuit board CB.

Internal Electrode Layer

Next, the internal electrode layers30, that is, the first internal electrode layers31and the second internal electrode layers32, will be further described.FIG.4is an enlarged cross-sectional view of the internal electrode layers of the multilayer body in the multilayer ceramic capacitor shown inFIG.2. As shown inFIG.4, among the internal electrode layers30, that is, among the first internal electrode layers31and the second internal electrode layers32, internal electrode layers provided closer to the first main surface TS1 than the center in the lamination direction T of the multilayer body10are referred to as first main surface-side internal electrode layers301, and internal electrode layers provided closer to the second main surface TS2 than the center in the lamination direction T of the multilayer body10are referred to as second main surface-side internal electrode layers302.

Each of first solid solution layers301A in which a subcomponent metal, for example, Sn, different from a main component metal, for example, Ni, is present as a solid solution is provided at an interface between the first main surface-side internal electrode layer301and the dielectric layer20, the interface is included in the first main surface-side internal electrode layer301. On the other hand, each of second solid solution layer302A in which a subcomponent metal, for example, Sn, is present as a solid solution is provided on the interface between the second main surface-side internal electrode layer302and the dielectric layer20, the interface is included in the second main surface-side internal electrode layer302. The metal present as a solid solution in the first solid solution layer301A and the second solid solution layer302A may be, for example, at least one metal selected from Sn, In, Ga, Zn, Bi, Pb, Fe, V, Y, and Cu.

The concentration (content) of the subcomponent metal, for example, Sn in the second solid solution layer302A is higher than the concentration (content) of the subcomponent metal, for example, Sn in the first solid solution layer301A. The situation in which the concentration (content) of the subcomponent metal such as Sn is high in the internal electrode layer indicates that the concentration (content) of the main component metal such as, for example, Ni is low, that is, the coverage of the main component metal such as, for example, Ni is low.

By mounting the multilayer ceramic capacitor1on the circuit board CB with the second main surface TS2 side on which the internal electrode layer having low coverage of the main component metal such as, for example, Ni is provided facing the circuit board CB, it is possible to reduce or prevent the generation of “acoustic noise”. Therefore, since there is no need to thicken the second outer layer portion102, it is possible to provide more internal electrode layers30, and it is also possible to make the multilayer ceramic capacitor1thinner (smaller) and higher in capacitance.

The content (molar ratio) of the subcomponent metal such as, for example, Sn in the first solid solution layer301A is preferably, for example, about 0.2 mol % or more and about 0.8 mol % or less with respect to the main component metal such as, for example, Ni and 100 mol. On the other hand, the content (molar ratio) of the subcomponent metal, for example, Sn, in the second solid solution layer302A may be higher than that of the first solid solution layer301A at, for example, about 1.5 mol % or more and about 2.5 mol % or less with respect to the main component metal, for example, Ni and 100 mol. The ratio of the first main surface-side internal electrode layers301including the first solid solution layers301A to the total number of the internal electrode layers30is preferably, for example, about 60% or more, and the ratio of the second main surface-side internal electrode layers302including the second solid solution layers302A to the total number of the internal electrode layers30is preferably, for example, about 40% or less.

Here, for example, the dielectric layers20may be thinned in order to make the multilayer ceramic capacitor1thinner (smaller) and higher in capacitance. However, the reduction in the thicknesses of the dielectric layers20may increase the intensity of the electric field applied per layer, and may lower the lifetime, i.e., reliability, of the multilayer ceramic capacitor1.

In this respect, when the first solid solution layers301A and the second solid solution layers302A of the subcomponent metal such as, for example, Sn are provided at the interfaces between the dielectric layers20and the internal electrode layers30, the insulating property is improved at the interfaces where the first solid solution layers301A and the second solid solution layers302A are provided, between the dielectric layers20and the internal electrode layers30, and it is possible to reduce or prevent an increase in electric field intensity in the dielectric layer20. Therefore, it is possible to reduce or prevent a decrease in the lifetime, i.e., reliability, of the multilayer ceramic capacitor1.

When the content of the subcomponent metal such as, for example, Sn in the second solid solution layer302A (and the first solid solution layer301A) is less than about 1.5 mol %, the advantageous effects of including the subcomponent metal such as, for example, Sn described above is small. On the other hand, when the content of the subcomponent metal such as, for example, Sn in the first solid solution layer301A (and the second solid solution layer302A) exceeds about 2.5 mol %, the melting point of the internal electrode layer30decreases, and the main component metal of the internal electrode layer30, e.g., Ni, may form beads. When the main component metal, for example, Ni, forms beads, the internal electrode layer30is locally thick, the dielectric layer20is locally thin, the electric field intensity locally increases, and the advantageous effects of the subcomponent metal such as Sn described above is canceled.

TEM analysis is included among examples of a method of measuring the molar ratio of the content (mol %) of the subcomponent metal such as, for example, Sn in the first solid solution layer301A with respect to the main component metal such as, for example, Ni and 100 mol in the first main surface-side internal electrode layer301and the molar ratio of the content (mol %) of the subcomponent metal such as, for example, Sn in the second solid solution layer302A with respect to the main component metal such as, for example, Ni and 100 mol in the second main surface-side internal electrode layer302. The internal electrode layers provided in the lamination direction were divided into three regions, and the internal electrode layers at the center of each region were measured at 10 points in the in-plane direction at 10 nm inner side from the interface by TEM analysis, and averaged to obtain a molar ratio.

The thickness of the first solid solution layer301A is preferably, for example, about 1 nm or more and about 20 nm or less. On the other hand, the thickness of the second solid solution layer302A is preferably, for example, about 1 nm or more and about 20 nm or less. Examples of a method of measuring the thicknesses of the first solid solution layer301A and the second solid solution layer302A include a method of observing the cross section LT in the vicinity of the center in the width direction of the multilayer body exposed by polishing, similar to the above-described method of measuring the thicknesses of the dielectric layers20and the internal electrode layers30. Examples of the measuring instrument include wavelength dispersive X-ray analysis (WDX) or energy dispersive X-ray analysis (EDX), and scanning electron microscope (SEM) or transmission electron microscope (TEM). In the first solid solution layer301A, the content (molar ratio) of the subcomponent metal, for example, Sn, is about 0.2 mol % or more and about 0.8 mol % or less with respect to 100 mol of the main component metal, for example, Ni, and in the second solid solution layer302A, the content (molar ratio) of the subcomponent metal, for example, Sn is about 1.5 mol % or more and about 2.5 mol % or less with respect to 100 mol of the main component metal, for example, Ni.

Manufacturing Method

Next, a non-limiting example of a method of manufacturing the above-described multilayer ceramic capacitor1will be described. First, a dielectric sheet for forming the dielectric layer20and an electrically conductive paste for forming the internal electrode layer30are provided. The dielectric sheet includes Sn. For example, an insulator sheet including dielectric grains of a core-shell structure whose surface is coated with Sn is used. The content of Sn in the dielectric sheet is made different between the dielectric sheet adjacent to the first main surface-side internal electrode layer301and the dielectric sheet adjacent to the second main surface-side internal electrode layer302. The dielectric sheet and the conductive paste include a binder and a solvent. As the binder and the solvent, well-known materials can be used.

Next, an internal electrode pattern is formed on the dielectric sheet by printing an electrically conductive paste on the dielectric sheet in a predetermined pattern, for example. Examples of a method of forming the internal electrode pattern include screen printing, gravure printing, or the like.

Next, a predetermined number of dielectric sheets for forming the second outer layer portion102on which no internal electrode pattern is printed are laminated. A dielectric sheet for forming the inner layer portion100on which the internal electrode pattern is printed is sequentially laminated thereon. A predetermined number of dielectric sheets for forming the first outer layer portion101on which no internal electrode pattern is printed are laminated thereon. Thus, a laminated sheet is produced.

Next, the laminated sheet is pressed in the lamination direction by means such as hydrostatic pressing to produce a laminated block. Next, the laminated block is cut into a predetermined size, and the laminated chip is cut out. At this time, the corners and ridges of the laminated chip are rounded by barrel polishing or the like.

Next, the laminated chip is fired to produce a multilayer body10. The firing temperature is preferably, for example, about 900° C. or higher and about 1400° C. or lower, although it depends on the material of the dielectric and the internal electrode. At this time, solid solution layers, in which Sn originating from the dielectric layer20is segregated and present as a solid solution, are formed at the interfaces between the internal electrode layers30and the dielectric layers20, the interfaces are included in the internal electrode layers30. For example, as described above, by making the content of Sn different between the dielectric sheet adjacent to the first main surface-side internal electrode layer301and the dielectric sheet adjacent to the second main surface-side internal electrode layer302, the first solid solution layers301A in which Sn originating from the dielectric layer20is segregated and present as a solid solution are formed at the interfaces between the first main surface side internal electrode layers301and the dielectric layers20, the interfaces are included in the first main surface side internal electrode layers301, and the second solid solution layers302A in which Sn originating from the dielectric layer20is segregated and present as a solid solution are formed at the interfaces between the second main surface side internal electrode layers302and the dielectric layers20, the interfaces are included in the second main surface side internal electrode layers302.

Next, by employing, for example, a dipping method to immerse the first end surface LS1 of the multilayer body10in an electrically conductive paste which is an electrode material for forming the base electrode layer, the electrically conductive paste for forming the first base electrode layer415is applied to the first end surface LS1. Similarly, by employing, for example, the dipping method to immerse the second end surface LS2 of the multilayer body10in an electrically conductive paste which is an electrode material for forming the base electrode layer, the electrically conductive paste for forming the second base electrode layer425is applied to the second end surface LS2. Thereafter, these electrically conductive pastes are fired, such that a first base electrode layer415and a second base electrode layer425, which are fired layers, are formed. The firing temperature is preferably, for example, about 600° C. or higher and about 900° C. or lower.

As described above, the first base electrode layer415and the second base electrode layer425, which are resin layers, may be formed by applying an electrically conductive paste including electrically conductive particles and a thermosetting resin by a coating method and firing, or the first base electrode layer415and the second base electrode layer425which are thin films may be formed by a thin film formation method such as, for example, a sputtering method or a deposition method.

Thereafter, the first plated layer416is formed on the surface of the first base electrode layer415to form the first external electrode41, and the second plated layer426is formed on the surface of the second base electrode layer425to form the second external electrode42. Through the above steps, the above-described multilayer ceramic capacitor1is obtained.

As described above, according to the multilayer ceramic capacitor1of the present preferred embodiment, the first solid solution layers301A in which the subcomponent metal, for example, Sn, different from the main component metal, for example, Ni, is present as a solid solution, are formed in the first main surface-side internal electrode layers301provided adjacent to the first main surface TS1, and the second solid solution layers302A in which the subcomponent metal, for example, Sn, different from the main component metal, for example, Ni, is present as a solid solution, are formed in the second main surface-side internal electrode layers302provided adjacent to the second main surface TS2. Furthermore, the concentration (content) of the subcomponent metal, for example, Sn, in the second solid solution layers302A is higher than the concentration (content) of the subcomponent metal, for example, Sn, in the first solid solution layer301A. The situation in which the concentration (content) of the subcomponent metal such as, for example, Sn is high in the internal electrode layer indicates that the concentration (content) of the main component metal such as, for example, Ni is low, that is, the coverage of the main component metal such as, for example, Ni is low.

By mounting the multilayer ceramic capacitor1on the circuit board CB with the second main surface TS2 side on which the internal electrode layer having low coverage of the main component metal such as, for example, Ni is provided facing the circuit board CB, it is possible to reduce or prevent generation of “acoustic noise”. Therefore, since there is no need to thicken the second outer layer portion102, it is possible to provide more internal electrode layers30, and it is also possible to make the multilayer ceramic capacitor1thinner (smaller) and higher in capacitance. Therefore, it is possible to reduce or prevent the generation of “acoustic noise” without reducing or preventing the reduction in thickness (reduction in size) and the increase in capacitance of the multilayer ceramic capacitor1.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to the preferred embodiments described above, and various changes and modifications thereto are possible. For example, in the above-described preferred embodiments, the multilayer ceramic capacitor is exemplified in which the boundary between the first main surface-side internal electrode layer301and the second main surface-side internal electrode layer302is in the vicinity of the center of the multilayer body10in the lamination direction T. However, the present invention is not limited thereto, and the boundary between the first main surface-side internal electrode layer301and the second main surface-side internal electrode layer302may be offset toward the first main surface TS1 or toward the second main surface TS2. Alternatively, an internal electrode layer different from these internal electrode layers may be further provided between the first main surface-side internal electrode layer301and the second main surface-side internal electrode layer302. For example, the concentration (content) of the subcomponent metal such as Sn in the solid solution layers of the internal electrode layers from the first main surface TS1 to the second main surface TS2 may increase in two or more stages, or no solid solution layer in which the subcomponent metal such as Sn is present as a solid solution may be provided in the internal electrode layers between the first main surface-side internal electrode layers301and the second main surface-side internal electrode layers302.

Furthermore, in the above-described preferred embodiments, the multilayer ceramic capacitor is exemplified in which the thickness of the second outer layer portion102is the same or substantially the same as the thickness of the first outer layer portion101. However, the present invention is not limited thereto, and the second outer layer portion102may be thicker than the first outer layer portion101, as shown inFIGS.5and6. In other words, the interval between the internal electrode layer30closest to the second main surface TS2 and the second main surface TS2 may be larger than the interval between the internal electrode layer30closest to the first main surface TS1 and the first main surface TS1. In this modified example, the advantageous effects of reducing the thickness (the size) and increasing the capacitance is lower than that in the above-described preferred embodiments, but the advantageous effect of reducing or preventing the occurrence of “acoustic noise” is higher. Therefore, in this modified example, it is possible to reduce or prevent the generation of “acoustic noise” without significantly reducing or preventing the reduction in thickness (reduction in size) and the increase in capacitance of the multilayer ceramic capacitor1.

The measuring method of the thicknesses of the first outer layer portion101and the second outer layer portion102may be the same as the measuring method of the thicknesses of the dielectric layer20and the internal electrode layer30. For example, the cross section LT in the vicinity of the center in the width direction of the multilayer body exposed by polishing can be observed with a scanning electron microscope. Each value may be an average value of a plurality of measurement values in the length direction.

Furthermore, as a non-limiting example of a manufacturing method of the multilayer ceramic capacitor, a method of applying a dielectric of a side gap to the side surfaces WS1 and WS2 of the multilayer body10in the width direction W later may be applied. In this case, in the multilayer ceramic capacitor, both end portions of the internal electrode layer in the width direction W are aligned (e.g., aligned by an error of about 5 μm).

While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.