MULTILAYER COIL COMPONENT

Abstract

A multilayer coil component includes a body including multiple insulating layers stacked in a direction of stacking and having first and second end surfaces opposite each other in a length direction, first and second primary surfaces opposite each other in a height direction, perpendicular to the length direction, and first and second lateral surfaces opposite each other in a width direction, perpendicular to the length direction and to the height direction; a coil inside the body and including multiple coil conductors electrically connected together; and a first outer electrode extending from at least part of the first end surface of the body to part of the first primary surface and electrically coupled to the coil. The direction of stacking of the insulating layers and the direction of the coil axis of the coil are parallel with the first primary surface, which is the mounting surface, of the body.

Description

CROSS-REFERENCE TO RELATED APPLICATION

This application claims benefit of priority to Japanese Patent Application No. 2021-023406, filed Feb. 17, 2021, the entire content of which is incorporated herein by reference.

BACKGROUND

Technical Field

The present disclosure relates to a multilayer coil component.

Background Art

As a multilayer coil component superior in radiofrequency characteristics, Japanese Unexamined Patent Application Publication No. 2019-186255 discloses a multilayer coil component having a transmission coefficient S21 at 40 GHz of −1.0 dB or more and 0 dB or less (i.e., from −1.0 dB to 0 dB).

SUMMARY

As high-speed and large-capacity communication has advanced, however, multilayer coil components are now expected to have a high transmission coefficient S21 over higher-frequency bands and be consistent in the transmission coefficient S21 in the radiofrequency and lower-frequency bands at the same time.

Accordingly, the present disclosure provides a multilayer coil component that has a high and consistent transmission coefficient S21 in the radiofrequency band.

The multilayer coil component according to the present disclosure includes a body formed by a plurality of insulating layers stacked in a direction of stacking and having first and second end surfaces opposite each other in a length direction, first and second primary surfaces opposite each other in a height direction, perpendicular to the length direction, and first and second lateral surfaces opposite each other in a width direction, perpendicular to the length direction and to the height direction. The multilayer coil component further includes a coil disposed inside the body and formed by a plurality of coil conductors electrically connected together; and a first outer electrode extending from at least part of the first end surface of the body to part of the first primary surface and electrically coupled to the coil. The direction of stacking of the insulating layers and a direction of a coil axis of the coil are parallel with the first primary surface, which is a mounting surface, of the body. At least part of the body has a magnetic phase containing Fe, Ni, Zn, and Cu and a nonmagnetic phase containing Si. The first outer electrode has, in order from a body side, an underlying electrode and a plating electrode on the underlying electrode; an end in the length direction of a portion of the plating electrode lying on the first primary surface of the body is closer to the second end surface of the body than an end in the length direction of a portion of the underlying electrode lying on the first primary surface of the body; and a distance in the length direction between the end of the plating electrode and the end of the underlying electrode is 30 μm or less.

According to the present disclosure, there can be provided a multilayer coil component that has a high and consistent transmission coefficient S21 in the radiofrequency band.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective schematic diagram illustrating an example of a multilayer coil component according to the present disclosure;

FIG. 2 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first end surface side of the body;

FIG. 3 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first primary surface side of the body;

FIG. 4 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first lateral surface side of the body;

FIG. 5 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the second lateral surface side of the body;

FIG. 6 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the second end surface side of the body;

FIG. 7 is a cross-sectional schematic diagram illustrating an example of a portion corresponding to line segment A1-A2 in FIG. 1;

FIG. 8 is a perspective schematic diagram illustrating an example of a disassembled form of the body and coil in FIG. 7;

FIG. 9 is a plan schematic diagram illustrating an example of a disassembled form of the body and coil in FIG. 7;

FIG. 10 is a side schematic view of the multilayer coil component in FIG. 1;

FIG. 11 is a schematic diagram illustrating part of a cross-section of the first body section and first outer electrode in FIG. 10 parallel with the length and height directions;

FIG. 12 is a schematic diagram illustrating part of a cross-section of the second body section and second outer electrode in FIG. 10 parallel with the length and height directions; and

FIG. 13 is a graphical representation of measured transmission coefficients S21 of multilayer coil component samples 1, 3, and 4.

DETAILED DESCRIPTION

The following describes the multilayer coil component according to the present disclosure. It should be noted that the present disclosure is not limited to the following configurations and may optionally be modified within the scope of the present disclosure. Combinations of multiple ones of the specific preferred configurations set forth below are also the present disclosure.

The multilayer coil component according to the present disclosure includes a body formed by multiple insulating layers stacked in a direction of stacking and having first and second end surfaces opposite each other in a length direction, first and second primary surfaces opposite each other in a height direction, perpendicular to the length direction, and first and second lateral surfaces opposite each other in a width direction, perpendicular to the length direction and to the height direction. The multilayer coil component further includes a coil disposed inside the body and formed by multiple coil conductors electrically connected together; and a first outer electrode extending from at least part of the first end surface of the body to part of the first primary surface and electrically coupled to the coil.

FIG. 1 is a perspective schematic diagram illustrating an example of a multilayer coil component according to the present disclosure.

As illustrated in FIG. 1, the multilayer coil component 1 has a body 10, a first outer electrode 21, and a second outer electrode 22. Although not illustrated in FIG. 1, the multilayer coil component 1 also has, as described later herein, a coil disposed inside the body 10.

As illustrated, for example in FIG. 1, length, height, and width directions are herein defined as the directions denoted by L, T, and W, respectively. The length direction L, the height direction T, and the width direction W are perpendicular to one another.

The body 10 has a first end surface 11a and a second end surface 11b opposite each other in the length direction L, a first primary surface 12a and a second primary surface 12b opposite each other in the height direction T, and a first lateral surface 13a and a second lateral surface 13b opposite each other in the width direction W and is, for example, cuboid or substantially cuboid in shape.

The first and second end surfaces 11a and 11b of the body 10 do not need to be strictly perpendicular to the length direction L. The first and second primary surfaces 12a and 12b of the body 10 do not need to be strictly perpendicular to the height direction T either. The first and second lateral surfaces 13a and 13b of the body 10, furthermore, do not need to be strictly perpendicular to the width direction W.

When the multilayer coil component 1 is mounted onto a substrate, the first primary surface 12a of the body 10 is the mounting surface.

Preferably, the body 10 has rounded corners and edges. A corner of the body 10 is a point of the body 10 at which three of its surfaces meet. An edge of the body 10 is a portion of the body 10 at which two of its surfaces meet.

FIG. 2 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first end surface side of the body. FIG. 3 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first primary surface side of the body. FIG. 4 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the first lateral surface side of the body. FIG. 5 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the second lateral surface side of the body. FIG. 6 is a plan schematic diagram illustrating the multilayer coil component in FIG. 1 when viewed from the second end surface side of the body.

As illustrated in FIGS. 1, 2, and 3, the first outer electrode 21 extends from at least part of the first end surface 11a of the body 10, from part of the first end surface 11a of the body 10 here, to part of the first primary surface 12a. The presence of the first outer electrode 21 on the first primary surface 12a, which is the mounting surface, of the body 10, improves the ease of mounting of the multilayer coil component 1.

As illustrated in FIG. 2, the first outer electrode 21 covers a region of the first end surface 11a of the body 10 including the edge at which it meets the first primary surface 12a and does not cover a region including the edge at which it meets the second primary surface 12b. This makes the first end surface 11a of the body 10 exposed in its region including the edge at which it meets the second primary surface 12b.

When the first outer electrode 21 is viewed in the length direction L, its dimension E₁ in the height direction T does not need to be constant in the width direction W, although it is constant in FIG. 2. For example, when viewed in the length direction L, the first outer electrode 21 may have an arched shape, in which the dimension E₁ in the height direction T increases from the ends toward the middle in the width direction W.

The first outer electrode 21 may be on part of the first end surface 11a of the body 10 as illustrated in FIGS. 1 and 2 or may be over the entire first end surface 11a of the body 10.

As illustrated in FIG. 3, the first outer electrode 21 covers a region of the first primary surface 12a of the body 10 including the edge at which it meets the first end surface 11a and does not cover a region including the edge at which it meets the second end surface 11b.

When the first outer electrode 21 is viewed in the height direction T, its dimension E₂ in the length direction L does not need to be constant in the width direction W, although it is constant in FIG. 3. For example, when viewed in the height direction T, the first outer electrode 21 may have an arched shape, in which the dimension E₂ in the length direction L increases from the ends toward the middle in the width direction W.

As illustrated in FIGS. 1, 4, and 5, the first outer electrode 21 may extend from part of the first end surface 11a of the body 10 to part of the first primary surface 12a and also to part of the first lateral surface 13a and part of the second lateral surface 13b. More specifically, the first outer electrode 21 may cover a region of the first lateral surface 13a of the body 10 including the vertex at which it meets the first end surface 11a and the first primary surface 12a without covering a region including the vertex at which it meets the first end surface 11a and the second primary surface 12b. The first outer electrode 21, furthermore, may cover a region of the second lateral surface 13b of the body 10 including the vertex at which it meets the first end surface 11a and the first primary surface 12a without covering a region including the vertex at which it meets the first end surface 11a and the second primary surface 12b.

Preferably, as illustrated in FIG. 4, the contours of the portion of the first outer electrode 21 covering the first lateral surface 13a of the body 10 include a first contour 50a facing the edge at which the first lateral surface 13a and the first end surface 11a meet, a second contour 50b facing the edge at which the first lateral surface 13a and the first primary surface 12a meet, and a contour diagonal to the first and second contours 50a and 50b in addition to these.

Preferably, as illustrated in FIG. 5, the contours of the portion of the first outer electrode 21 covering the second lateral surface 13b of the body 10 include a third contour 50c facing the edge at which the second lateral surface 13b and the first end surface 11a meet, a fourth contour 50d facing the edge at which the second lateral surface 13b and the first primary surface 12a meet, and a contour diagonal to the third and fourth contours 50c and 50d in addition to these.

The first outer electrode 21 may be off the first lateral surface 13a of the body 10. The first outer electrode 21, furthermore, may be off the second lateral surface 13b of the body 10.

The first outer electrode 21 may extend from the first end surface 11a of the body 10 to part of each of the first primary surface 12a, second primary surface 12b, first lateral surface 13a, and second lateral surface 13b.

As illustrated in FIGS. 1, 3, and 6, the second outer electrode 22 extends from at least part of the second end surface 11b of the body 10, from part of the second end surface 11b of the body 10 here, to part of the first primary surface 12a. The presence of the second outer electrode 22 on the first primary surface 12a, which is the mounting surface, of the body 10, improves the ease of mounting of the multilayer coil component 1.

As illustrated in FIG. 6, the second outer electrode 22 covers a region of the second end surface 11b of the body 10 including the edge at which it meets the first primary surface 12a and does not cover a region including the edge at which it meets the second primary surface 12b. This makes the second end surface 11b of the body 10 exposed in its region including the edge at which it meets the second primary surface 12b.

When the second outer electrode 22 is viewed in the length direction L, its dimension E₃ in the height direction T does not need to be constant in the width direction W, although it is constant in FIG. 6. For example, when viewed in the length direction L, the second outer electrode 22 may have an arched shape, in which the dimension E₃ in the height direction T increases from the ends toward the middle in the width direction W.

The second outer electrode 22 may be on part of the second end surface 11b of the body 10 as illustrated in FIGS. 1 and 6 or may be over the entire second end surface 11b of the body 10.

As illustrated in FIG. 3, the second outer electrode 22 covers a region of the first primary surface 12a of the body 10 including the edge at which it meets the second end surface 11b and does not cover a region including the edge at which it meets the first end surface 11a.

When the second outer electrode 22 is viewed in the height direction T, its dimension E₄ in the length direction L does not need to be constant in the width direction W, although it is constant in FIG. 3. For example, when viewed in the height direction T, the second outer electrode 22 may have an arched shape, in which the dimension E₄ in the length direction L increases from the ends toward the middle in the width direction W.

As illustrated in FIGS. 1, 4, and 5, the second outer electrode 22 may extend from part of the second end surface 11b of the body 10 to part of the first primary surface 12a and also to part of the first lateral surface 13a and part of the second lateral surface 13b. More specifically, the second outer electrode 22 may cover a region of the first lateral surface 13a of the body 10 including the vertex at which it meets the second end surface 11b and the first primary surface 12a without covering a region including the vertex at which it meets the second end surface 11b and the second primary surface 12b. The second outer electrode 22, furthermore, may cover a region of the second lateral surface 13b of the body 10 including the vertex at which it meets the second end surface 11b and the first primary surface 12a without covering a region including the vertex at which it meets the second end surface 11b and the second primary surface 12b.

Preferably, as illustrated in FIG. 4, the contours of the portion of the second outer electrode 22 covering the first lateral surface 13a of the body 10 include a fifth contour 50e facing the edge at which the first lateral surface 13a and the second end surface 11b meet, a sixth contour 50f facing the edge at which the first lateral surface 13a and the first primary surface 12a meet, and a contour diagonal to the fifth and sixth contours 50e and 50f in addition to these.

Preferably, as illustrated in FIG. 5, the contours of the portion of the second outer electrode 22 covering the second lateral surface 13b of the body 10 include a seventh contour 50g facing the edge at which the second lateral surface 13b and the second end surface 11b meet, an eighth contour 50h facing the edge at which the second lateral surface 13b and the first primary surface 12a meet, and a contour diagonal to the seventh and eighth contours 50g and 50h in addition to these.

The second outer electrode 22 may be off the first lateral surface 13a of the body 10. The second outer electrode 22, furthermore, may be off the second lateral surface 13b of the body 10.

The second outer electrode 22 may extend from the second end surface 11b of the body 10 to part of each of the first primary surface 12a, second primary surface 12b, first lateral surface 13a, and second lateral surface 13b.

The size of the multilayer coil component 1 is not critical, but preferably is the 0603, 0402, or 1005 size.

For when the multilayer coil component 1 is the 0603, 0402, or 1005 size, the following presents specific examples of preferred dimensions of the multilayer coil component 1, body 10, first outer electrode 21, and second outer electrode 22.

(1) When the multilayer coil component 1 is the 0603 size

• • Preferably, the dimension L₁ of the multilayer coil component 1 in the length direction L is 0.57 mm or more. Preferably, furthermore, the dimension L₁ of the multilayer coil component 1 in the length direction L is 0.63 mm or less.
  • Preferably, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.27 mm or more. Preferably, furthermore, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.33 mm or less.
  • Preferably, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.27 mm or more. Preferably, furthermore, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.33 mm or less.
  • Preferably, the dimension L₂ of the body 10 in the length direction L is 0.57 mm or more. Preferably, furthermore, the dimension L₂ of the body 10 in the length direction L is 0.63 mm or less.
  • Preferably, the dimension T₂ of the body 10 in the height direction T is 0.27 mm or more. Preferably, furthermore, the dimension T₂ of the body 10 in the height direction T is 0.33 mm or less.
  • Preferably, the dimension W₂ of the body 10 in the width direction W is 0.27 mm or more. Preferably, furthermore, the dimension W₂ of the body 10 in the width direction W is 0.33 mm or less.
  • Preferably, the dimension E₁ of the first outer electrode 21 in the height direction T is 0.10 mm or more and 0.20 mm or less (i.e., from 0.10 mm to 0.20 mm). If the dimension E₁ of the first outer electrode 21 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₂ of the first outer electrode 21 in the length direction L is 0.12 mm or more and 0.22 mm or less (i.e., from 0.12 mm to 0.22 mm). If the dimension E₂ of the first outer electrode 21 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₃ of the second outer electrode 22 in the height direction T is 0.10 mm or more and 0.20 mm or less (i.e., from 0.10 mm to 0.20 mm). If the dimension E₃ of the second outer electrode 22 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₄ of the second outer electrode 22 in the length direction L is 0.12 mm or more and 0.22 mm or less (i.e., from 0.12 mm to 0.22 mm). If the dimension E₄ of the second outer electrode 22 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.

(2) When the multilayer coil component 1 is the 0402 size

• • Preferably, the dimension L₁ of the multilayer coil component 1 in the length direction L is 0.38 mm or more. Preferably, furthermore, the dimension L₁ of the multilayer coil component 1 in the length direction L is 0.42 mm or less.
  • Preferably, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.18 mm or more. Preferably, furthermore, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.22 mm or less.
  • Preferably, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.18 mm or more. Preferably, furthermore, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.22 mm or less.
  • Preferably, the dimension L₂ of the body 10 in the length direction L is 0.38 mm or more. Preferably, furthermore, the dimension L₂ of the body 10 in the length direction L is 0.42 mm or less.
  • Preferably, the dimension T₂ of the body 10 in the height direction T is 0.18 mm or more. Preferably, furthermore, the dimension T₂ of the body 10 in the height direction T is 0.22 mm or less.
  • Preferably, the dimension W₂ of the body 10 in the width direction W is 0.18 mm or more. Preferably, furthermore, the dimension W₂ of the body 10 in the width direction W is 0.22 mm or less.
  • Preferably, the dimension E₁ of the first outer electrode 21 in the height direction T is 0.06 mm or more and 0.13 mm or less (i.e., from 0.06 mm to 0.13 mm). If the dimension E₁ of the first outer electrode 21 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₂ of the first outer electrode 21 in the length direction L is 0.08 mm or more and 0.15 mm or less (i.e., from 0.08 mm to 0.15 mm). If the dimension E₂ of the first outer electrode 21 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₃ of the second outer electrode 22 in the height direction T is 0.06 mm or more and 0.13 mm or less (i.e., from 0.06 mm to 0.13 mm). If the dimension E₃ of the second outer electrode 22 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₄ of the second outer electrode 22 in the length direction L is 0.08 mm or more and 0.15 mm or less (i.e., from 0.08 mm to 0.15 mm). If the dimension E₄ of the second outer electrode 22 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.

(3) When the multilayer coil component 1 is the 1005 size

• • Preferably, the dimension L₁ of the multilayer coil component 1 in the length direction L is 0.95 mm or more. Preferably, furthermore, the dimension L₁ of the multilayer coil component 1 in the length direction L is 1.05 mm or less.
  • Preferably, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.45 mm or more. Preferably, furthermore, the dimension T₁ of the multilayer coil component 1 in the height direction T is 0.55 mm or less.
  • Preferably, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.45 mm or more. Preferably, furthermore, the dimension W₁ of the multilayer coil component 1 in the width direction W is 0.55 mm or less.
  • Preferably, the dimension L₂ of the body 10 in the length direction L is 0.95 mm or more. Preferably, furthermore, the dimension L₂ of the body 10 in the length direction L is 1.05 mm or less.
  • Preferably, the dimension T₂ of the body 10 in the height direction T is 0.45 mm or more. Preferably, furthermore, the dimension T₂ of the body 10 in the height direction T is 0.55 mm or less.
  • Preferably, the dimension W₂ of the body 10 in the width direction W is 0.45 mm or more. Preferably, furthermore, the dimension W₂ of the body 10 in the width direction W is 0.55 mm or less.
  • Preferably, the dimension E₁ of the first outer electrode 21 in the height direction T is 0.15 mm or more and 0.33 mm or less (i.e., from 0.15 mm to 0.33 mm). If the dimension E₁ of the first outer electrode 21 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₂ of the first outer electrode 21 in the length direction L is 0.20 mm or more and 0.38 mm or less (i.e., from 0.20 mm to 0.38 mm). If the dimension E₂ of the first outer electrode 21 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₃ of the second outer electrode 22 in the height direction T is 0.15 mm or more and 0.33 mm or less (i.e., from 0.15 mm to 0.33 mm). If the dimension E₃ of the second outer electrode 22 in the height direction T is not constant in the width direction W, it is preferred that the maximum be in this range.
  • Preferably, the dimension E₄ of the second outer electrode 22 in the length direction L is 0.20 mm or more and 0.38 mm or less (i.e., from 0.20 mm to 0.38 mm). If the dimension E₄ of the second outer electrode 22 in the length direction L is not constant in the width direction W, it is preferred that the maximum be in this range.

For the multilayer coil component according to the present disclosure, the direction of stacking of the insulating layers and the direction of the coil axis of the coil are parallel with the first primary surface, which is the mounting surface, of the body.

FIG. 7 is a cross-sectional schematic diagram illustrating an example of a portion corresponding to line segment A1-A2 in FIG. 1.

As illustrated in FIG. 7, the body 10 is formed by multiple insulating layers 15 stacked in a direction of stacking, in the length direction L here. That is, the direction of stacking of the insulating layers 15 is parallel with the length direction L and parallel with the first primary surface 12a, which is the mounting surface, of the body 10. It should be noted that in FIG. 7, the insulating layers 15 are illustrated with lines therebetween for the convenience of description, but in actuality, no clear lines would be seen.

Inside the body 10 is a coil 30. The coil 30 is formed by multiple coil conductors 31 electrically coupled together and is, for example, solenoidal in shape. The coil conductors 31 are stacked in the length direction L together with the insulating layers 15. It should be noted that in FIG. 7, the shape of the coil 30, the positions of the coil conductors 31, the coupling between the coil conductors 31, etc., are not illustrated exactly. For example, coil conductors 31 adjacent in the length direction L are electrically coupled together by via conductors not illustrated in FIG. 7.

The coil 30 has a coil axis C. The coil axis C of the coil 30 extends in the length direction L and runs between the first and second end surfaces 11a and 11b of the body 10 at the same time. That is, the direction of the coil axis C of the coil 30 is parallel with the first primary surface 12a, which is the mounting surface, of the body 10. The coil axis C of the coil 30, furthermore, passes through the geometric center of the coil 30 when viewed in the length direction L.

In this way, the direction of stacking of the insulating layers 15 and the direction of the coil axis C of the coil 30 are parallel with the first primary surface 12a, which is the mounting surface, of the body 10.

The direction of stacking of the insulating layers 15 and the direction of the coil axis C of the coil 30 may be parallel with the length direction L as illustrated in FIG. 7 or may not. For example, it may be that the direction of stacking of the insulating layers 15 is parallel with the width direction W, and the direction of the coil axis C of the coil 30 is parallel with the length direction L. Even in this case, the direction of stacking of the insulating layers 15 and the direction of the coil axis C of the coil 30 are parallel with the first primary surface 12a, which is the mounting surface, of the body 10.

The multilayer coil component 1 may further have a first interlinking conductor 41 and a second interlinking conductor 42.

The first interlinking conductor 41 is formed by multiple via conductors, not illustrated in FIG. 7, electrically coupled together and stacked in the length direction L together with insulating layers 15. The first interlinking conductor 41 is exposed on the first end surface 11a of the body 10.

The first outer electrode 21 is electrically coupled to the coil 30 by the first interlinking conductor 41. Of the multiple coil conductors 31, the closest to the first end surface 11a of the body 10 is a coil conductor 31a. That is, the first outer electrode 21 is electrically coupled to a coil conductor 31a by the first interlinking conductor 41.

The first interlinking conductor 41 couples the first outer electrode 21 and the coil 30 together. Preferably, the first interlinking conductor 41 provides straight-line coupling between the first outer electrode 21 and the coil 30, between the first outer electrode 21 and the coil conductor 31a here. Preferably, when viewed in the length direction L, the first interlinking conductor 41 overlaps the coil conductor 31a and is closer than the coil axis C to the first primary surface 12a, which is the mounting surface, of the body 10. These make electrical coupling between the first outer electrode 21 and the coil 30 easier.

The first interlinking conductor 41 providing straight-line coupling between the first outer electrode 21 and the coil 30 means that the via conductors forming the first interlinking conductor 41 overlap when viewed in the length direction L. The via conductors forming the first interlinking conductor 41, therefore, do not need to be arranged strictly in a straight line.

Preferably, the first interlinking conductor 41 is coupled to the portion of the coil conductor 31a closest to the first primary surface 12a of the body 10. This helps reduce the area of the first outer electrode 21 on the first end surface 11a of the body 10. The resulting decrease in the stray capacitance between the first outer electrode 21 and the coil 30 improves the radiofrequency characteristics of the multilayer coil component 1 accordingly.

There may be only one first interlinking conductor 41, or there may be multiple ones.

The second interlinking conductor 42 is formed by multiple via conductors, not illustrated in FIG. 7, electrically coupled together and stacked in the length direction L together with insulating layers 15. The second interlinking conductor 42 is exposed on the second end surface 11b of the body 10.

The second outer electrode 22 is electrically coupled to the coil 30 by the second interlinking conductor 42. Of the multiple coil conductors 31, the closest to the second end surface 11b of the body 10 is a coil conductor 31d. That is, the second outer electrode 22 is electrically coupled to a coil conductor 31d by the second interlinking conductor 42.

The second interlinking conductor 42 couples the second outer electrode 22 and the coil 30 together. Preferably, the second interlinking conductor 42 provides straight-line coupling between the second outer electrode 22 and the coil 30, between the second outer electrode 22 and the coil conductor 31d here. Preferably, when viewed in the length direction L, the second interlinking conductor 42 overlaps the coil conductor 31d and is closer than the coil axis C to the first primary surface 12a, which is the mounting surface, of the body 10. These make electrical coupling between the second outer electrode 22 and the coil 30 easier.

The second interlinking conductor 42 providing straight-line coupling between the second outer electrode 22 and the coil 30 means that the via conductors forming the second interlinking conductor 42 overlap when viewed in the length direction L. The via conductors forming the second interlinking conductor 42, therefore, do not need to be arranged strictly in a straight line.

Preferably, the second interlinking conductor 42 is coupled to the portion of the coil conductor 31d closest to the first primary surface 12a of the body 10. This helps reduce the area of the second outer electrode 22 on the second end surface 11b of the body 10. The resulting decrease in the stray capacitance between the second outer electrode 22 and the coil 30 improves the radiofrequency characteristics of the multilayer coil component 1 accordingly.

There may be only one second interlinking conductor 42, or there may be multiple ones.

Preferably, the dimension L₃ of the coil 30 in the length direction L is 85% or more and 94% or less (i.e., from 85% to 94%), more preferably 90% or more and 94% or less (i.e., from 90% to 94%), of the dimension L₂ of the body 10 in the length direction L.

The dimension L₃ of the coil 30 in the length direction L indicates the distance in the length direction L from the coil conductor 31a, electrically coupled to the first outer electrode 21 by the first interlinking conductor 41, to the coil conductor 31d, electrically coupled to the second outer electrode 22 by the second interlinking conductor 42 (including the dimension of the coil conductors 31a and 31d in the length direction L). That is, the dimension L₃ of the coil 30 in the length direction L indicates the dimension in the length direction L of the region over which the coil conductors 31 are present.

If the dimension L₃ of the coil 30 in the length direction L is smaller than 85% of the dimension L₂ of the body 10 in the length direction L, a large stray capacitance of the coil 30 can affect the radiofrequency characteristics of the multilayer coil component 1. If the dimension L₃ of the coil 30 in the length direction L is larger than 94% of the dimension L₂ of the body 10 in the length direction L, a large stray capacitance between the first outer electrode 21 and the coil 30 and that between the second outer electrode 22 and the coil 30 can affect the radiofrequency characteristics of the multilayer coil component 1.

FIG. 8 is a perspective schematic diagram illustrating an example of a disassembled form of the body and coil in FIG. 7. FIG. 9 is a plan schematic diagram illustrating an example of a disassembled form of the body and coil in FIG. 7.

In the example illustrated in FIGS. 8 and 9, the body 10 is formed by insulating layers 15a, 15b, 15c, 15d, and 15e as the insulating layers 15 stacked in a direction of stacking, in the length direction L here.

When what is stated applies to all of the insulating layers 15a, 15b, 15c, 15d, and 15e herein, the term insulating layers 15 is used.

On the primary surface of the insulating layers 15a, 15b, 15c, and 15d are coil conductors 31a, 31b, 31c, and 31d, respectively, as the coil conductors 31. The coil conductors 31a, 31b, 31c, and 31d are stacked in the length direction L together with the insulating layers 15a, 15b, 15c, and 15d, and each coil conductor is electrically coupled to one another.

When what is stated applies to all of the coil conductors 31a, 31b, 31c, and 31d herein, the term coil conductors 31 is used.

In the example illustrated in FIGS. 8 and 9, the length of each of the coil conductors 31a, 31b, 31c, and 31d is the length of ¾ turns of the coil 30. That is, the number of coil conductors that need to be stacked to form three turns of the coil 30 is four. Inside the body 10, coil conductors 31a, 31b, 31c, and 31d are stacked repeatedly as one unit (equivalent of three turns).

At both ends of the coil conductors 31, there may be a land portion. More specifically, there may be a land portion at both ends of the coil conductors 31a, 31b, 31c, and 31d.

When viewed in the length direction L, the land portions of the coil conductors 31 may be round or may be polygonal.

Insulating layers 15a, 15b, 15c, and 15d have via conductors 34a, 34b, 34c, and 34d, respectively, penetrating therethrough in the length direction L.

The via conductors 34a, 34b, 34c, and 34d are coupled to one end of the coil conductors 31a, 31b, 31c, and 31d, respectively. If there is a land portion at both ends of the coil conductors 31a, 31b, 31c, and 31d as stated above, this means the via conductors 34a, 34b, 34c, and 34d are coupled to a land portion of the coil conductors 31a, 31b, 31c, and 31d, respectively.

An insulating layer 15a, having a coil conductor 31a and a via conductor 34a, an insulating layer 15b, having a coil conductor 31b and a via conductor 34b, an insulating layer 15c, having a coil conductor 31c and a via conductor 34c, and an insulating layer 15d, having a coil conductor 31d and a via conductor 34d, are stacked repeatedly as one unit (a portion enclosed by dotted lines in FIGS. 8 and 9). This makes the coil conductors 31a, 31b, 31c, and 31d electrically coupled together by the via conductors 34a, 34b, 34c, and 34d. That is, coil conductors adjacent in the length direction L are electrically coupled together by via conductors.

In this way, a solenoidal coil 30 disposed inside the body 10 is constructed.

When viewed in the length direction L, the coil 30 may be round or may be polygonal. If the coil 30 includes land portions, for example if there is a land portion at both ends of the coil conductors 31, the shape of the coil 30 indicates the shape excluding the land portions.

Preferably, when viewed in the length direction L, the inner diameter of the coil conductors 31 is 15% or more and 40% or less (i.e., from 15% to 40%) of the dimension W₂ of the body 10 in the width direction W. The inner diameter of the coil conductors 31 is synonymous with the coil diameter of the coil 30. If the coil 30 is polygonal when viewed in the length direction L, the diameter of a circle equivalent in area to the polygon is deemed to be the coil diameter of the coil 30, or the inner diameter of the coil conductors 31.

Preferably, the number of turns of the coil 30 is 35 or more, more preferably 35 or more and 45 or less (i.e., from 35 to 45). Thirty-five or more turns in the coil 30 give the multilayer coil component 1 a high impedance, and therefore a high transmission coefficient S21 in the radiofrequency band, thereby improving the radiofrequency characteristics of the multilayer coil component 1.

An insulating layer 15e has a via conductor 34e penetrating therethrough in the length direction L.

On the primary surface of the insulating layer 15e, there may be a land portion coupled to the via conductor 34e.

Multiple ones of these insulating layers 15e, having a via conductor 34e, are stacked to cover the insulating layer 15a, having a coil conductor 31a and a via conductor 34a, located at one end of the coil 30. This makes the via conductors 34e electrically coupled together to form the first interlinking conductor 41, making the first interlinking conductor 41 exposed on the first end surface 11a of the body 10. As a result, the first outer electrode 21 and the coil conductor 31a are electrically coupled together by the first interlinking conductor 41.

Multiple ones of these insulating layers 15e, having a via conductor 34e, are stacked to cover the insulating layer 15d, having a coil conductor 31d and a via conductor 34d, located at the other end of the coil 30. This makes the via conductors 34e electrically coupled together to form the second interlinking conductor 42, making the second interlinking conductor 42 exposed on the second end surface 11b of the body 10. As a result, the second outer electrode 22 and the coil conductor 31d are electrically coupled together by the second interlinking conductor 42.

Preferably, the dimension of the first interlinking conductor 41 in the length direction L and that of the second interlinking conductor 42 are each 2.5% or more and 7.5% or less (i.e., from 2.5% to 7.5%), more preferably 2.5% or more and 5.0% or less (i.e., from 2.5% to 5.0%), of the dimension L₂ of the body 10 in the length direction L. The resulting small inductance of the first and second interlinking conductors 41 and 42 improves the radiofrequency characteristics of the multilayer coil component 1.

Preferably, the dimension of the first interlinking conductor 41 in the width direction W and that of the second interlinking conductor 42 are each 8.0% or more and 20% or less (i.e., from 8.0% to 20%) of the dimension W₂ of the body 10 in the width direction W.

For when the multilayer coil component 1 is the 0603, 0402, or 1005 size, the following presents specific examples of preferred dimensions of the coil conductors 31, first interlinking conductor 41, and second interlinking conductor 42.

(1) When the multilayer coil component 1 is the 0603 size

• • Preferably, when viewed in the length direction L, the inner diameter of the coil conductors 31 is 50 μm or more and 100 μm or less (i.e., from 50 μm to 100 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the length direction L and that of the second interlinking conductor 42 are each 15 μm or more and 45 μm or less (i.e., from 15 μm to 45 μm), more preferably 15 μm or more and 30 μm or less (i.e., from 15 μm to 30 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the width direction W and that of the second interlinking conductor 42 are each 30 μm or more and 60 μm or less (i.e., from 30 μm to 60 μm).

(2) When the multilayer coil component 1 is the 0402 size

• • Preferably, when viewed in the length direction L, the inner diameter of the coil conductors 31 is 30 μm or more and 70 μm or less (i.e., from 30 μm to 70 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the length direction L and that of the second interlinking conductor 42 are each 10 μm or more and 30 μm or less (i.e., from 10 μm to 30 μm), more preferably 10 μm or more and 25 μm or less (i.e., from 10 μm to 25 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the width direction W and that of the second interlinking conductor 42 are each 20 μm or more and 40 μm or less (i.e., from 20 μm to 40 μm).

(3) When the multilayer coil component 1 is the 1005 size

• • Preferably, when viewed in the length direction L, the inner diameter of the coil conductors 31 is 80 μm or more and 170 μm or less (i.e., from 80 μm to 170 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the length direction L and that of the second interlinking conductor 42 are each 25 μm or more and 75 μm or less (i.e., from 25 μm to 75 μm), more preferably 25 μm or more and 50 μm or less (i.e., from 25 μm to 50 μm).
  • Preferably, the dimension of the first interlinking conductor 41 in the width direction W and that of the second interlinking conductor 42 are each 40 μm or more and 100 μm or less (i.e., from 40 μm to 100 μm).

As for the material for forming the coil conductors 31a, 31b, 31c, and 31d and the via conductors 34a, 34b, 34c, 34d, and 34e, examples include Ag, Au, Cu, Pd, Ni, Al, and alloys containing at least one of these metals.

For the multilayer coil component according to the present disclosure, at least part of the body has a magnetic phase containing Fe, Ni, Zn, and Cu and a nonmagnetic phase containing Si.

For the multilayer coil component 1, at least part of the body 10 has a magnetic phase containing Fe, Ni, Zn, and Cu and a nonmagnetic phase containing Si.

The magnetic phase may further contain Co, Bi, Sn, Mn, etc.

Preferably, the magnetic phase is formed by a Ni—Cu—Zn ferrite material.

Preferably, the Ni—Cu—Zn ferrite material contains, in a total of 100 mol %, 40 mol % or more and 49.5 mol % or less (i.e., from 40 mol % to 49.5 mol %) Fe in terms of an Fe₂O₃ basis, 10 mol % or more and 45 mol % or less (i.e., from 10 mol % to 45 mol %) Ni in terms of a NiO basis, 2 mol % or more and 35 mol % or less (i.e., from 2 mol % to 35 mol %) Zn in terms of a ZnO basis, and 6 mol % or more and 13 mol % or less (i.e., from 6 mol % to 13 mol %) Cu in terms of a CuO basis.

The Ni—Cu—Zn ferrite material may further contain, for example, dopants or inevitable impurities, such as Co, Bi, Sn, and Mn.

Preferably, the nonmagnetic phase is formed by a borosilicate glass material.

Preferably, the borosilicate glass material contains, in a total of 100% by weight, 70% by weight or more and 85% by weight or less (i.e., from 70% by weight to 85% by weight) Si in terms of a SiO₂ basis, 10% by weight or more and 25% by weight or less (i.e., from 10% by weight to 25% by weight) B in terms of a B₂O₃ basis, 0.5% by weight or more and 5% by weight or less (i.e., from 0.5% by weight to 5% by weight) alkali metal A in terms of an A₂O basis, and 0% by weight or more and 5% by weight or less (i.e., from 0% by weight to 5% by weight) Al in terms of an Al₂O₃ basis.

The borosilicate glass material may further contain forsterite (2MgO.SiO₂), quartz (SiO₂), etc., as filler.

The nonmagnetic phase may be formed by an oxide represented by aZnO.SiO₂ (a is 1.8 or more and 2.2 or less (i.e., from 1.8 to 2.2)). Examples of such oxides include the Zn₂SiO₄ called willemite. Such an oxide may contain Cu in place of part of Zn.

The magnetic and nonmagnetic phases are differentiated as follows. First, the multilayer coil component is polished to substantially the middle in the width direction to expose a cross-section parallel with the length and height directions like that illustrated in, for example, FIG. 7. Then the exposed cross-section of the body is subjected to elemental mapping by scanning transmission electron microscopy-energy-dispersive X-ray spectroscopy (STEM-EDX). Then the two phases are differentiated: the regions in which Fe is present constitute the magnetic phase, and the regions in which Si is present constitute the nonmagnetic phase.

FIG. 10 is a side schematic view of the multilayer coil component in FIG. 1.

In the example illustrated in FIG. 10, when, for the multilayer coil component 1, a boundary G is defined that extends parallel with the height and width directions T and W at the midpoint of the body 10 in the length direction L, the body 10 has first and second body sections 61 and 62 aligned in the length direction L with the boundary G therebetween, the first body section 61 including the first end surface 11a and the second body section 62 including the second end surface 11b. That is, the body 10 is divided into two, first and second body sections 61 and 62, by a boundary G in the length direction L.

Regarding the boundary G, the midpoint of the body 10 in the length direction L is determined as the point that bisects the maximum dimension of the body 10 in the length direction L.

The first outer electrode 21 is on the surface of the first body section 61.

The second outer electrode 22 is on the surface of the second body section 62.

For the multilayer coil component according to the present disclosure, the first outer electrode has, in order from the body side, an underlying electrode and a plating electrode on the underlying electrode, and the end in the length direction of the portion of the plating electrode lying on the first primary surface of the body is closer to the second end surface of the body than the end in the length direction of the portion of the underlying electrode lying on the first primary surface of the body.

FIG. 11 is a schematic diagram illustrating part of a cross-section of the first body section and first outer electrode in FIG. 10 parallel with the length and height directions.

As illustrated in FIG. 11, the first outer electrode 21 has, in order from the body 10 side, an underlying electrode 21a and a plating electrode 21b on the underlying electrode 21a.

The end 21ba in the length direction L of the portion of the plating electrode 21b lying on the first primary surface 12a of the body 10 is closer to the second end surface 11b of the body 10 (right in FIG. 11) than the end 21aa in the length direction L of the portion of the underlying electrode 21a lying on the first primary surface 12a of the body 10.

The end in the length direction of the underlying electrode lying on the first primary surface of the body and the end in the length direction of the plating electrode lying on the first primary surface of the body are determined on a cross-section of the multilayer coil component extending parallel with the length and height directions substantially in the middle in the width direction.

A plating electrode in an outer electrode having underlying and plating electrodes like those of the multilayer coil component according to the present disclosure can stretch much larger than the underlying electrode along the surface of the body. If an outer electrode is formed with such an overgrown plating electrode, the stray capacity between the outer electrode and the coil can be so large that it will affect the radiofrequency characteristics of the multilayer coil component.

To address this, for the multilayer coil component according to the present disclosure, the distance in the length direction between the end of the plating electrode and the end of the underlying electrode is 30 μm or less.

For the multilayer coil component 1, the distance a in the length direction L between the end 21ba in the length direction L of the portion of the plating electrode 21b lying on the first primary surface 12a of the body 10 and the end 21aa in the length direction L of the portion of the underlying electrode 21a lying on the first primary surface 12a of the body 10 is 30 μm or less. More specifically, the distance a in the length direction L between the end 21ba of the plating electrode 21b and the end 21aa of the underlying electrode 21a is greater than 0 μm and 30 μm or less (i.e., from 0 μm to 30 μm). This means the plating electrode 21b does not stretch much larger than the underlying electrode 21a along the first primary surface 12a of the body 10. The stray capacity between the coil 30 and the first outer electrode 21, therefore, is prevented from being large; as a result, the radiofrequency characteristics of the multilayer coil component 1 are improved accordingly.

If the distance a in the length direction L between the end 21ba of the plating electrode 21b and the end 21aa of the underlying electrode 21a is greater than 30 μm, the plating electrode 21b stretches much larger than the underlying electrode 21a along the first primary surface 12a of the body 10, and the stray capacity between the coil 30 and the first outer electrode 21 is not prevented from being large.

Overall, the multilayer coil component according to the present disclosure has an outer electrode, a first outer electrode here, having a plating electrode but at the same time is configured such that the distance in the length direction between the end of the plating electrode and the end of the underlying electrode is 30 μm or less. By virtue of this, the multilayer coil component is superior in radiofrequency characteristics. That is, the multilayer coil component according to the present disclosure has a high transmission coefficient S21 in the radiofrequency band and is consistent in the transmission coefficient S21 in the radiofrequency and lower-frequency bands.

Preferably, the underlying electrode 21a contains Ag.

Preferably, the plating electrode 21b contains at least one of Ni or Sn.

The plating electrode 21b may have a single-layer structure or may have a multilayer structure, but preferably has a multilayer structure. If the plating electrode 21b has a multilayer structure, it is preferred that the plating electrode 21b have, in order from the underlying electrode 21a side, a Ni plating electrode and a Sn plating electrode.

Plating electrodes like the plating electrode 21b are differentiated from underlying electrodes formed by non-plating processes like the underlying electrode 21a by elemental analysis by energy-dispersive X-ray spectroscopy (EDX) and based on information such as being dense in a cross-section parallel with the length and height directions like that illustrated in FIG. 11.

Preferably, when a first reference position H1 is defined that coincides in the height direction T with the end 21aa of the underlying electrode 21a, the first body section 61 has a first region 61a including at least the range having a dimension P₁ in the length direction L of 20 μm from the first reference position H1 toward the second end surface 11b (to the right in FIG. 11). That is, it is preferred that the first region 61a include at least the range from the point at which the distance P₁ in the length direction L from the first reference position H1 toward the second end surface 11b is 0 μm to the point at which the distance P₁ is 20 μm.

Preferably, the end 61aa of the first region 61a on the second end surface 11b side is at the point where the distance P₁ in the length direction L from the first reference position H1 is 20 μm or more and 60 μm or less (i.e., from 20 μm to 60 μm). That is, it is preferred that the first region 61a include a range from the point at which the distance P₁ in the length direction L from the first reference position H1 toward the second end surface 11b is 0 μm to the point at which the distance P₁ is α₁ μm (20≤α₁≤60).

Preferably, the first region 61a further includes at least the range having a dimension P₂ in the length direction L of 20 μm from the first reference position H1 toward the first end surface 11a (to the left in FIG. 11). That is, it is preferred that the first region 61a further include at least the range from the point at which the distance P₂ in the length direction L from the first reference position H1 toward the first end surface 11a is 0 μm to the point at which the distance P₂ is 20 μm.

Preferably, the end 61ab of the first region 61a on the first end surface 11a side is at the point where the distance P₂ in the length direction L from the first reference position H1 is 20 μm or more and 60 μm or less (i.e., from 20 μm to 60 μm). That is, it is preferred that the first region 61a further include a range from the point at which the distance P₂ in the length direction L from the first reference position H1 toward the first end surface 11a is 0 μm to the point at which the distance P₂ is α₂ μm (20α₂≤60).

Preferably, the first region 61a is totally the nonmagnetic phase or has both the nonmagnetic and magnetic phases. This prevents the plating electrode 21b from greatly outgrowing the underlying electrode 21a along the first primary surface 12a of the body 10 during its formation, making it more certain that the distance a in the length direction L between the end 21ba of the plating electrode 21b and the end 21aa of the underlying electrode 21a is 30 μm or less. The end 21ba of the plating electrode 21b, therefore, is forced to stay, preferably at a point where it is within the first region 61a as illustrated in FIG. 11.

Preferably, in the first region 61a, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases is 60% by volume or more. More specifically, it is preferred that the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in the first region 61a be 60% by volume or more and 100% by volume or less (i.e., from 60% by volume to 100% by volume). This makes it more certain that the distance a in the length direction L between the end 21ba of the plating electrode 21b and the end 21aa of the underlying electrode 21a is 30 μm or less when the plating electrode 21b is formed.

Preferably, the first region 61a contains, in a total of 100% by weight, 30.0% by weight or more Si in terms of a SiO₂ basis. This makes it more certain that the distance a in the length direction L between the end 21ba of the plating electrode 21b and the end 21aa of the underlying electrode 21a is 30 μm or less when the plating electrode 21b is formed.

Preferably, the first region 61a contains, in a total of 100% by weight, 85.0% by weight or less Si in terms of a SiO₂ basis.

Preferably, the first region 61a contains, in a total of 100% by weight, 30.0% by weight or more and 85.0% by weight or less (i.e., from 30.0% by weight to 85.0% by weight) Si in terms of a SiO₂ basis, 4.0% by weight or more and 15.0% by weight or less (i.e., from 4.0% by weight to 15.0% by weight) B in terms of a B₂O₃ basis, 0% by weight or more and 45.0% by weight or less (i.e., from 0% by weight to 45.0% by weight) Fe in terms of an Fe₂O₃ basis, 0% by weight or more and 15.0% by weight (i.e., from 0% by weight to 15.0% by weight) Ni in terms of a NiO basis, 0% by weight or more and 8.0% by weight or less (i.e., from 0% by weight to 8.0% by weight) Zn in terms of a ZnO basis, and 0% by weight or more and 5.0% by weight or less (i.e., from 0% by weight to 5.0% by weight) Cu in terms of a CuO basis.

Preferably, the first region 61a further contains, in a total of 100% by weight, 0.3% by weight or more and 1.5% by weight or less (i.e., from 0.3% by weight to 1.5% by weight) K in terms of a K₂O basis and 0.9% by weight or more and 3.5% by weight or less (i.e., from 0.9% by weight to 3.5% by weight) Mg in terms of a MgO basis.

Preferably, the first body section 61 has a second region 61b, which is all but the first region 61a.

Preferably, the second region 61b is totally the magnetic phase or has both the magnetic and nonmagnetic phases. In that case the impedance of the multilayer coil component 1 tends to be high. As a result, the radiofrequency characteristics of the multilayer coil component 1 tend to be improved.

Preferably, in the second region 61b, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases is 50% by volume or less. More specifically, it is preferred that the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in the second region 61b be 0% by volume or more and 50% by volume or less (i.e., from 0% by volume to 50% by volume). In that case the percentage by volume of the magnetic phase to the total volume of the magnetic and nonmagnetic phase in the second region 61b is at least comparable to the percentage by volume of the nonmagnetic phase there, and, therefore, the impedance of the multilayer coil component 1 tends to be high. As a result, the radiofrequency characteristics of the multilayer coil component 1 tend to be improved.

In each of the first and second regions, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases is determined as follows. First, the multilayer coil component is polished to substantially the middle in the width direction to expose a cross-section parallel with the length and height directions like that illustrated in, for example, FIGS. 7 and 11. Then, if the percentage by volume of the nonmagnetic phase in the first region is measured on the exposed cross-section in the first body section, the range having a dimension in the length direction of 20 μm from the first reference position toward the second end surface is selected as the region of interest. If the percentage by volume of the nonmagnetic phase in the second region is measured on the exposed cross-section in the first body section, the range having a dimension in the length direction of 20 μm from the first end surface toward the second end surface is selected as the region of interest. Within that region of interest three 20-μm square areas are picked, and then the magnetic and nonmagnetic phases are differentiated as described above by performing elemental mapping by scanning transmission electron microscopy-energy-dispersive X-ray spectroscopy. After that, in each of these three areas, the percentage by area of the nonmagnetic phase to the total area of the magnetic and nonmagnetic phases is measured on the elemental mapping image using image analysis software. Then these measured percentages by area are averaged, and the calculated average is reported as the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases.

Preferably, the second region 61b contains, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO₂ basis. In that case the impedance of the multilayer coil component 1 tends to be high. As a result, the radiofrequency characteristics of the multilayer coil component 1 tend to be improved.

It should be noted that the second region 61b may be Si-free.

Preferably, the second region 61b contains, in a total of 100% by weight, 0% by weight or more and 25.0% by weight or less (i.e., from 0% by weight to 25.0% by weight) Si in terms of a SiO₂ basis, 0% by weight or more and 5.0% by weight or less (i.e., from 0% by weight to 5.0% by weight) B in terms of a B₂O₃ basis, 45.0% by weight or more and 70.0% by weight or less (i.e., from 45.0% by weight to 70.0% by weight) Fe in terms of an Fe₂O₃ basis, 10.0% by weight or more and 20.0% by weight or less (i.e., from 10.0% by weight to 20.0% by weight) Ni in terms of a NiO basis, and 5.0% by weight or more and 12.0% by weight or less (i.e., from 5.0% by weight to 12.0% by weight) Zn in terms of a ZnO basis.

Preferably, the Si content of the first region 61a in a total of 100% by weight is larger than the Si content of the second region 61b in a total of 100% by weight by 7.0% by weight or more in terms of a SiO₂ basis. That is, it is preferred that the difference between the Si content of the first region 61a in a total of 100% by weight and the Si content of the second region 61b in a total of 100% by weight be 7.0% by weight or more in terms of a SiO₂ basis. Preferably, furthermore, the difference between the Si content of the first region 61a in a total of 100% by weight and the Si content of the second region 61b in a total of 100% by weight is 60.0% by weight or less. The Si content of the second region 61b in a total of 100% by weight may be 0% by weight.

The composition of the first and second regions is checked by analyzing each region of interest described above by inductively coupled plasma atomic emission spectroscopy/mass spectrometry (ICP-AES/MS).

The first body section 61 may be totally the first region 61a, although it is preferred that it have the first and second regions 61a and 61b.

Preferably, the second body section 62 and the second outer electrode 22, too, have the same structure and construction as the first body section 61 and the first outer electrode 21 as presented below.

FIG. 12 is a schematic diagram illustrating part of a cross-section of the second body section and second outer electrode in FIG. 10 parallel with the length and height directions.

As illustrated in FIG. 12, the second outer electrode 22 has, in order from the body 10 side, an underlying electrode 22a and a plating electrode 22b on the underlying electrode 22a.

The end 22ba in the length direction L of the portion of the plating electrode 22b lying on the first primary surface 12a of the body 10 is closer to the first end surface 11a of the body 10 (left in FIG. 11) than the end 22aa in the length direction L of the portion of the underlying electrode 22a lying on the first primary surface 12a of the body 10.

The distance b in the length direction L between the end 22ba in the length direction L of the portion of the plating electrode 22b lying on the first primary surface 12a of the body 10 and the end 22aa in the length direction L of the portion of the underlying electrode 22a lying on the first primary surface 12a of the body 10 is 30 μm or less. More specifically, the distance b in the length direction L between the end 22ba of the plating electrode 22b and the end 22aa of the underlying electrode 22a be greater than 0 μm and 30 μm or less (i.e., from 0 μm to 30 μm).

A preferred structure and construction for the underlying and plating electrodes 22a and 22b is the same as a preferred structure and construction for the underlying and plating electrodes 21a and 21b, respectively.

Preferably, when a second reference position H2 is defined that coincides in the height direction T with the end 22aa of the underlying electrode 22a, the second body section 62 has a first region 62a including at least the range having a dimension Q₁ in the length direction L of 20 μm from the second reference position H2 toward the first end surface 11a (to the left in FIG. 12). That is, it is preferred that the first region 62a include at least the range from the point at which the distance Q₁ in the length direction L from the second reference position H2 toward the first end surface 11a is 0 μm to the point at which the distance Q₁ is 20 μm.

Preferably, the end 62aa of the first region 62a on the first end surface 11a side is at the point where the distance Q₁ in the length direction L from the second reference position H2 is 20 μm or more and 60 μm or less (i.e., from 20 μm to 60 μm). That is, it is preferred that the first region 62a include a range from the point at which the distance Q₁ in the length direction L from the second reference position H2 toward the first end surface 11a is 0 μm to the point at which the distance Q₁ is β₁ μm (20≤β₁≤60).

Preferably, the first region 62a further includes at least the range having a dimension Q₂ in the length direction L of 20 μm from the second reference position H2 toward the second end surface 11b (to the right in FIG. 12). That is, it is preferred that the first region 62a further include at least the range from the point at which the distance Q₂ in the length direction L from the second reference position H2 toward the second end surface 11b is 0 μm to the point at which the distance Q₂ is 20 μm.

Preferably, the end 62ab of the first region 62a on the second end surface 11b side is at the point where the distance Q₂ in the length direction L from the second reference position H2 is 20 μm or more and 60 μm or less (i.e., from 20 μm to 60 μm). That is, it is preferred that the first region 62a further include a range from the point at which the distance Q₂ in the length direction L from the second reference position H2 toward the second end surface 11b is 0 μm to the point at which the distance Q₂ is β₂ μm (20≤β₂≤60).

Preferably, the first region 62a is totally a nonmagnetic phase or has both nonmagnetic and magnetic phases.

Preferably, the second body section 62 has a second region 62b, which is all but the first region 62a.

Preferably, the second region 62b is totally a magnetic phase or has both magnetic and nonmagnetic phases.

A preferred percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in each of the first and second regions 62a and 62b is the same as a preferred percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in each of the first and second regions 61a and 61b.

For the second body section, too, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in each of the first and second regions is determined as described above. This time, if the percentage by volume of the nonmagnetic phase in the first region is measured on the exposed cross-section in the second body section, the range having a dimension in the length direction of 20 μm from the second reference position toward the first end surface is selected as the region of interest. If the percentage by volume of the nonmagnetic phase in the second region is measured on the exposed cross-section in the second body section, the range having a dimension in the length direction of 20 μm from the second end surface toward the first end surface is selected as the region of interest.

A preferred composition for the first and second regions 62a and 62b is the same as a preferred composition for the first and second regions 61a and 61b, respectively.

The second body section 62 may be totally the first region 62a, although it is preferred that it have the first and second regions 62a and 62b.

The multilayer coil component 1 is produced by, for example, the following method.

Magnetic Material Preparation Step

First, predetermined proportions of Fe₂O₃, NiO, ZnO, and CuO are weighed out.

Then these measured materials are wet-mixed and then ground to give slurry. The duration of mixing of the materials is, for example, 4 hours or more and 8 hours or less (i.e., from 4 hours to 8 hours).

Then the resulting slurry is dried and then calcined. The calcination temperature is, for example, 700° C. or above and 800° C. or below (i.e., from 700° C. to 800° C.). The duration of calcination is, for example, 2 hours or more and 5 hours or less (i.e., from 2 hours to 5 hours).

In such a way, a powdery magnetic material, more specifically a powdery ferrite material, is prepared.

Preferably, the ferrite material contains, in a total of 100 mol %, 40 mol % or more and 49.5 mol % or less (i.e., from 40 mol % to 49.5 mol %) Fe in terms of an Fe₂O₃ basis, 10 mol % or more and 45 mol % or less (i.e., from 10 mol % to 45 mol %) Ni in terms of a NiO basis, 2 mol % or more and 35 mol % or less (i.e., from 2 mol % to 35 mol %) Zn in terms of a ZnO basis, and 6 mol % or more and 13 mol % or less (i.e., from 6 mol % to 13 mol %) Cu in terms of a CuO basis.

Nonmagnetic Material Preparation Step

First, a borosilicate glass powder containing Si, B, an alkali metal, and Al in predetermined proportions is prepared.

Preferably, the borosilicate glass material contains, in a total of 100% by weight, 70% by weight or more and 85% by weight or less (i.e., from 70% by weight to 85% by weight) Si in terms of a SiO₂ basis, 10% by weight or more and 25% by weight or less (i.e., from 10% by weight to 25% by weight) B in terms of a B₂O₃ basis, 0.5% by weight or more and 5% by weight or less (i.e., from 0.5% by weight to 5% by weight) alkali metal A in terms of an A₂O basis, and 0% by weight or more and 5% by weight or less (i.e., from 0% by weight to 5% by weight) Al in terms of an Al₂O₃ basis.

Then, as filler, a forsterite powder and a quartz powder are prepared.

Then the borosilicate glass, forsterite, and quartz powders are wet-mixed in predetermined proportions and then ground to give a nonmagnetic material.

Green Sheet Preparation Step

First, predetermined proportions of the magnetic and nonmagnetic materials are weighed out. Then these measured materials, an organic binder, such as a polyvinyl butyral resin, organic solvents, such as ethanol and toluene, a plasticizer, etc., are mixed together and then ground to give slurry. Then the resulting slurry is shaped, for example by doctor blading, into sheets having a predetermined thickness, and then a predetermined shape is punched out of them to give green sheets.

In preparing the green sheets, the proportions of blending of the magnetic and nonmagnetic materials are adjusted so that type 1 green sheets, in which the percentage by volume of the magnetic material to the total volume of the magnetic and nonmagnetic materials is 60% by volume or more, and type 2 green sheets, in which the percentage by volume of the magnetic material to the total volume of the magnetic and nonmagnetic materials is 50% by volume or less, will result.

In addition, in preparing the green sheets, the proportions of blending of the magnetic and nonmagnetic materials may be adjusted so that type 3 green sheets, which contain, in a total of 100% by weight, 30.0% by weight or more Si in terms of a SiO₂ basis, and type 4 green sheets, which contain, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO₂ basis, will result.

When what is stated applies to all of type 1, type 2, type 3, and type 4 green sheets hereinafter, the simple term “green sheet” is used.

In the following steps, a case in which the green sheets are a combination of type 1 and type 2 green sheets is described. The same applies if the green sheets are a combination of type 3 and type 4 green sheets.

Conductor Pattern Formation Step

First, a predetermined point of the green sheet is irradiated with a laser to create a via hole.

Then an electrically conductive paste, such as Ag paste, is coated onto the surface of the green sheet and put into the via hole at the same time, for example by screen printing. Through this, a conductor pattern for via conductors is formed in the via hole in the green sheet, and a conductor pattern for coil conductors, coupled to the conductor pattern for via conductors, is formed on the surface of the green sheet at the same time. In such a way, a coil sheet is prepared as a green sheet with a conductor pattern for coil conductors formed thereon and a conductor pattern for via conductors formed therein. Multiple ones of these coil sheets are prepared, with each coil sheet having a conductor pattern for coil conductors corresponding to a coil conductor illustrated in FIGS. 8 and 9 formed thereon and a conductor pattern for via conductors corresponding to a via conductor illustrated in FIGS. 8 and 9 formed therein.

Separately from the coil sheets, a via sheet is prepared as a green sheet with a conductor pattern for via conductors formed therein by putting an electrically conductive paste, such as Ag paste, into the via hole, for example by screen printing. Multiple ones of these via sheets, too, are prepared, with each via sheet having a conductor pattern for via conductors corresponding to a via conductor illustrated in FIGS. 8 and 9 formed therein.

In preparing the coil sheets and via sheets, those that will be placed in the region the manufacturer wants to be the first region in the first and second body sections of the finished bodies are made using type 1 green sheets, and those that will be placed in the region the manufacturer wants to be the second region are made using type 2 green sheets.

Multilayer Block Preparation Step

The coil sheets and via sheets are stacked in the direction of stacking in an order corresponding to FIGS. 8 and 9 and then joined together by heat and pressure bonding to give a multilayer block. This makes the multilayer block have type 1 green sheets in the region the manufacturer wants to be the first region in the first and second body sections of the finished bodies and type 2 green sheets in the region the manufacturer wants to be the second region.

Body and Coil Production Step

First, the multilayer block is cut, for example with a dicer, into a predetermined size to give singulated chips.

Then the singulated chips are fired. The firing temperature is, for example, 900° C. or above and 920° C. or below (i.e., from 900° C. to 920° C.). The duration of firing, is, for example, 2 hours or more and 4 hours or less (i.e., from 2 hours to 4 hours).

Firing the singulated chips will turn the green sheets, which are coil sheets and via sheets, into insulating layers, thereby giving bodies that are formed by multiple insulating layers stacked in a direction of stacking, in the length direction here.

As mentioned above, in preparing the multilayer block, type 1 green sheets are placed in the region the manufacturer wants to be the first region in the first and second body sections of the finished bodies, and type 2 green sheets are placed in the region the manufacturer wants to be the second region. In the first and second body sections of the bodies produced in this step, therefore, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in the first region is 60% by volume or more. In the second region, furthermore, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases is 50% by volume or less.

Firing the singulated chips will turn the conductor pattern for coil conductors on and the conductor pattern for via conductors in the coil sheets into a coil conductor and a via conductor, respectively, thereby giving coils that are formed by multiple coil conductors stacked in the length direction and electrically coupled together by via conductors.

In this way, bodies and coils disposed inside the bodies are produced. The direction of stacking of the insulating layers and the direction of the coil axis of the coil are parallel with the first primary surface, which is the mounting surface, of the body, parallel with the length direction here.

Firing the singulated chips will turn the conductor pattern for via conductors in the via sheets into via conductors, thereby producing first and second interlinking conductors that are formed by multiple via conductors stacked in the length direction and electrically coupled together. The first interlinking conductor will become exposed on the first end surface of the body. The second interlinking conductor will become exposed on the second end surface of the body.

The corners and edges of the bodies may be rounded, for example by barrel polishing.

Outer Electrode Formation Step

First, an electrically conductive paste containing Ag and glass frit is stretched to a predetermined thickness, and the bodies are dipped diagonally into the resulting layer. Then the resulting coating is baked to form an underlying electrode that extends from part of the first end surface of the body to part of each of the first primary surface, first lateral surface, and second lateral surface. Likewise, an underlying electrode is formed that extends from part of the second end surface of the body to part of each of the first primary surface, first lateral surface, and second lateral surface. The temperature for baking the coating is, for example, 800° C. or above and 820° C. or below (i.e., from 800° C. to 820° C.).

Then, for example by electrolytic plating, a Ni plating electrode and a Sn plating electrode are formed on each underlying electrode in sequence.

During this, the end in the length direction of the portion of the plating electrode lying on the first primary surface of the plating electrode comes closer to the second end surface of the body than the end in the length direction of the portion of the underlying electrode lying on the first primary surface of the body. This is done in such a manner that the distance in the length direction between the end of the plating electrode, the end of the Sn plating electrode here, and the end of the underlying electrode will be 30 μm or less.

An example of how to make the distance in the length direction between the end of the plating electrode and the end of the underlying electrode 30 μm or less is to place type 1 green sheets in the region the manufacturer wants to be the first region in the first and second body sections of the body in preparing the multilayer block. Using such a method ensures the percentage by volume of the magnetic phase to the total volume of the magnetic and nonmagnetic phases in the first region will be 60% by volume or more in the first and second body sections of the finished bodies, thereby making is more certain that the distance in the length direction between the end of the plating electrode and the end of the underlying electrode will be 30 μm or less when the plating electrode is formed.

In such a way, a first outer electrode, electrically coupled to the coil by the first interlinking conductor, and a second outer electrode, electrically coupled to the coil by the second interlinking conductor, are formed.

Through this, multilayer coil components 1 are produced.

Examples

The following presents examples in which the multilayer coil component according to the present disclosure is disclosed more specifically. It should be noted that the present disclosure is not limited to these examples.

Multilayer coil component samples 1 to 5 were produced by the following method.

Magnetic Material Preparation Step

First, proportions of Fe₂O₃, NiO, ZnO, and CuO were weighed out so that Fe₂O₃ would constitute 48.0 mol %, NiO 14.0 mol %, ZnO 30.0 mol %, and CuO 8.0 mol %. Then these measured materials were mixed in a ball mill with purified water and a PSZ (partially stabilized zirconia) medium for 6 hours and then ground to give slurry. Then the resulting slurry was dried and then calcined at 800° C. for 2 hours. In such a way, a powdery magnetic material, more specifically a powdery ferrite material, was prepared.

Nonmagnetic Material Preparation Step

First, a borosilicate glass powder containing Si, B, an alkali metal, and Al in predetermined proportions was prepared. Then, as filler, a forsterite powder and a quartz powder were prepared. Then the borosilicate glass powder, forsterite powder, and quartz powder are wet-mixed in such proportions that the glass powder would constitute 72% by weight, forsterite 4% by weight, and quartz 24% by weight, and then ground to give a nonmagnetic material.

Separately, body samples were prepared by the following method for checking the composition of the body of finished multilayer coil component samples 1 to 5 with. First, amounts of the magnetic and nonmagnetic materials were weighed out so that the magnetic material would constitute 100% by volume, and the nonmagnetic material 0% by volume. Then these measured materials, a polyvinyl butyral resin as an organic binder, ethanol and toluene as organic solvents, and a plasticizer were mixed together in a ball mill with a PSZ medium and then ground to give slurry. Then the resulting slurry was shaped into sheets by doctor blading, and these sheets were stacked and joined together by heat and pressure bonding to give a green block. A portion was punched out of the green block and fired at 910° C. for 4 hours, giving disk-shaped body sample A having a thickness of 0.5 mm and a diameter of 10 mm.

Then body samples B, C, and D were prepared in the same way as body sample A, except that the magnetic and nonmagnetic materials were blended in the proportions specified in Table 1.

Body samples A, B, C, and D were analyzed by inductively coupled plasma atomic emission spectroscopy/mass spectrometry, confirming that they had the compositions presented in Table 1.

When looking at the compositions presented in Table 1, one can say that green sheets C and D are categorized into type 3 green sheets, which contain, in a total of 100% by weight, 30.0% by weight or more Si in terms of a SiO₂ basis. One can also say that green sheets A and B are categorized into type 4 green sheets, which contain, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO₂ basis.

	TABLE 1
	Body Samples
	A	B	C	D
Percentage by	Magnetic material	100	50	40	0
volume	Nonmagnetic	0	50	60	100
(% by volume)	material
Composition	K2O	—	0.4	0.5	1.2
(% by weight)	B2O3	—	3.8	4.9	12.9
	SiO2	—	23.9	31.4	82.3
	Al2O3	—	0.1	0.1	0.2
	MgO	—	1.0	1.3	3.4
	Fe2O3	66.1	46.8	40.8	—
	NiO	18.8	13.3	11.6	—
	ZnO	9.7	6.9	6.0	—
	CuO	5.4	3.8	3.4	—

Green Sheet Preparation Step

Green sheets A as building units for a green block as described above were prepared using materials having the same composition as body sample A. That is, in the finished bodies, a region formed by green sheets A would have the same composition as body sample A.

Likewise, green sheets B were prepared using materials having the same composition as body sample B, green sheets C were prepared using materials having the same composition as body sample C, and green sheets D were prepared using materials having the same composition as body sample D. In the finished bodies, a region formed by green sheets B would have the same composition as body sample B, a region formed by green sheets C would have the same composition as body sample C, and a region formed by green sheets D would have the same composition as body sample D.

Green sheets C and D are categorized into type 1 green sheets, in which the percentage by volume of the nonmagnetic material to the total volume of the magnetic and nonmagnetic materials is 60% by volume or more. Green sheets A and B are categorized into type 2 green sheets, in which the percentage by volume of the nonmagnetic material to the total volume of the magnetic and nonmagnetic materials is 50% by volume or less.

Conductor Pattern Formation Step

First, a predetermined point of the green sheet was irradiated with a laser to create a via hole.

Then Ag paste was coated onto the surface of the green sheet and put into the via hole at the same time by screen printing. Through this, a conductor pattern for via conductors was formed in the via hole in the green sheet, and a conductor pattern for coil conductors, coupled to the conductor pattern for via conductors, was formed on the surface of the green sheet at the same time. In such a way, a coil sheet was prepared as a green sheet with a conductor pattern for coil conductors formed thereon and a conductor pattern for via conductors formed therein. Multiple ones of these coil sheets were prepared, with each coil sheet given a conductor pattern for coil conductors corresponding to a coil conductor illustrated in FIGS. 8 and 9 formed thereon and a conductor pattern for via conductors corresponding to a via conductor illustrated in FIGS. 8 and 9 formed therein.

Separately from the coil sheets, a via sheet was prepared as a green sheet with a conductor pattern for via conductors formed therein by putting Ag paste into the via hole by screen printing. Multiple ones of these via sheets, too, were prepared, with each via sheet given a conductor pattern for via conductors corresponding to a via conductor illustrated in FIGS. 8 and 9 formed therein.

Multilayer Block Preparation Step

The coil sheets and via sheets were stacked in the direction of stacking in an order corresponding to FIGS. 8 and 9 and then joined together by heat and pressure bonding to give a multilayer block.

Body and Coil Production Step

First, the multilayer block was cut with a dicer into a predetermined size to give singulated chips.

Then the singulated chips were fired at 910° C. for 4 hours.

Firing the singulated chips turned the green sheets, which were coil sheets and via sheets, into insulating layers, thereby giving bodies that were formed by multiple insulating layers stacked in a direction of stacking, in the length direction here.

Firing the singulated chips turned the conductor pattern for coil conductors on and the conductor pattern for via conductors in the coil sheets into a coil conductor and a via conductor, respectively, thereby giving coils that were formed by multiple coil conductors stacked in the length direction and electrically coupled together by via conductors.

In this way, bodies and coils disposed inside the bodies were produced. The direction of stacking of the insulating layers and the direction of the coil axis of the coil were parallel with the first primary surface, which was the mounting surface, of the body, parallel with the length direction here.

Firing the singulated chips turned the conductor pattern for via conductors in the via sheets into via conductors, thereby producing first and second interlinking conductors that were formed by multiple via conductors stacked in the length direction and electrically coupled together. The first interlinking conductor became exposed on the first end surface of the body. The second interlinking conductor became exposed on the second end surface of the body.

Then the corners and edges of the bodies were rounded by barrel-polishing with a medium in a rotary barrel.

Outer Electrode Formation Step

First, an electrically conductive paste containing Ag and glass frit was stretched to a predetermined thickness, and the bodies were dipped diagonally into the resulting layer. Then the resulting coating was baked at 810° C. to form an underlying electrode that extended from part of the first end surface of the body to part of each of the first primary surface, first lateral surface, and second lateral surface. Likewise, an underlying electrode was formed that extended from part of the second end surface of the body to part of each of the first primary surface, first lateral surface, and second lateral surface. The thickness of each underlying electrode was 5 μm.

Then, by electrolytic plating, a Ni plating electrode and a Sn plating electrode were formed on each underlying electrode in sequence.

In such a way, a first outer electrode, electrically coupled to the coil by the first interlinking conductor, and a second outer electrode, electrically coupled to the coil by the second interlinking conductor, were formed.

Through this, multilayer coil component samples 1 to 5 were produced. Multilayer coil component samples 1 to 5 each had a dimension in the length direction of 0.6 mm, a dimension in the height direction of 0.3 mm, and a dimension in the width direction of 0.3 mm.

For multilayer coil component samples 1 to 5, when a first reference position is defined that coincides in the height direction with the end in the length direction of the portion of the underlying electrode in the first outer electrode lying on the first primary surface of the body, the first region in the first body section of the body was a combined range consisting of the range having a dimension in the length direction of 20 μm from the first reference position toward the second end surface (dimension P₁ in FIG. 11) and the range having a dimension in the length direction of 20 μm from the first reference position toward the first end surface (dimension P₂ in FIG. 11). For multilayer coil component samples 1 to 5, furthermore, the second region in the first body section was all but the first region.

For multilayer coil component samples 1 to 5, when a second reference position is defined that coincides in the height direction with the end in the length direction of the portion of the underlying electrode in the second outer electrode lying on the first primary surface of the body, the first region in the second body section of the body was a combined range consisting of the range having a dimension in the length direction of 20 μm from the second reference position toward the first end surface (dimension Q₁ in FIG. 12) and the range having a dimension in the length direction of 20 μm from the second reference position toward the second end surface (dimension Q₂ in FIG. 12). For multilayer coil component samples 1 to 5, furthermore, the second region in the second body section was all but the first region.

For multilayer coil component samples 1 to 5, the green sheets forming the first and second regions in the first and second body sections were combined as specified in Table 2. As a result, for multilayer coil component samples 1 to 5, the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in the first region and the percentage by volume of the nonmagnetic phase to the total volume of the magnetic and nonmagnetic phases in the second region in the first and second body sections were as presented in Table 2. For multilayer coil component samples 1 to 5, furthermore, the Si content in terms of a SiO₂ basis of the first region and the Si content in terms of a SiO₂ basis of the second region in the first and second body sections were as presented in Table 2 (labeled as “SiO₂ content” in Table 2).

Testing

Multilayer coil component samples 1 to 5 were tested as follows.

Position of the Underlying and Plating Electrodes

First, the multilayer coil component sample was sealed by filling its surroundings with resin, upright in such a manner that the first lateral surface was exposed upside. Then the multilayer coil component sample was polished using a grinder to substantially the middle in the width direction to expose a cross-section parallel with the length and height directions. After that, the exposed cross-section of the multilayer coil component sample underwent focused ion beam (FIB) milling using SII NanoTechnology's “SMI3050R” focused ion beam mill, giving a cross-section for observation.

Then on the cross-section for observation of the multilayer coil component sample, the portion of the underlying and plating electrodes in the first outer electrode lying on the first primary surface of the body was imaged using a scanning electron microscope (SEM). Likewise, the portion of the underlying and plating electrodes in the second outer electrode lying on the first primary surface of the body was imaged. After that, the position of the underlying and plating electrodes was checked on the resulting images, with the result that in the length direction, the end of the plating electrode was closer than the end of the underlying electrode to the midpoint of the body. The distance in the length direction between the end of the plating electrode and the end of the underlying electrode, furthermore, was as presented in Table 2.

	TABLE 2
	*Sample 1	*Sample 2	Sample 3	Sample 4	Sample 5
First region	Green sheets	A	B	C	C	D
	Nonmagnetic phase	0	50	60	60	100
	(% by volume)
	SiO2 content	—	23.9	31.4	31.4	82.3
	(% by weight)
Second region	Green sheets	A	A	A	B	B
	Nonmagnetic phase	0	0	0	50	50
	(% by volume)
	SiO2 content	—	—	—	23.9	23.9
	(% by weight)
Difference in SiO2 content between	—	23.9	31.4	7.5	58.4
the first and second regions
(% by weight)
Distance in the length direction between	40	50	22	20	15
the end of the plating electrode and
the end of the underlying electrode (μm)

In Table 2, the samples having a name with an * are comparative examples, examples falling out of the scope of the present disclosure.

As shown in Table 2, for multilayer coil component samples 3, 4, and 5, the distance in the length direction between the end of the plating electrode and the end of the underlying electrode was not longer than 30 μm.

For multilayer coil component samples 1 and 2, on the other hand, the distance in the length direction between the end of the plating electrode and the end of the underlying electrode was longer than 30 μm.

That is, for multilayer coil component samples 3, 4, and 5, compared with multilayer coil component samples 1 and 2, the plating electrode was prevented from outgrowing the underlying electrode along the first primary surface of the body.

Transmission Coefficient S21

With multilayer coil component samples 1, 3, and 4, the transmission coefficient S21, determined from the ratio of the power of the transmitted signal to that of the incident signal, was measured at varying frequencies from 30 GHz to 70 GH using a network analyzer.

FIG. 13 is a graphical representation of measured transmission coefficients S21 of multilayer coil component samples 1, 3, and 4.

As shown in FIG. 13, multilayer coil component samples 3 and 4, compared with multilayer coil component sample 1, had a high transmission coefficient S21 in the radiofrequency band, for example at 40 GHz and 50 GHz, and were consistent in the transmission coefficient S21 in the radiofrequency and lower-frequency bands. Although not shown, multilayer coil component sample 5 was also found to have a high and consistent transmission coefficient S21 in the radiofrequency band like multilayer coil component samples 3 and 4.

Claims

1. A multilayer coil component comprising: a body including a plurality of insulating layers stacked in a direction of stacking and having first and second end surfaces opposite each other in a length direction, first and second primary surfaces opposite each other in a height direction, perpendicular to the length direction, and first and second lateral surfaces opposite each other in a width direction, perpendicular to the length direction and to the height direction;a coil disposed inside the body and configured by a plurality of coil conductors electrically connected together; anda first outer electrode extending from at least a portion of the first end surface of the body to a portion of the first primary surface and electrically connected to the coil, wherein:the direction of stacking of the insulating layers and a direction of a coil axis of the coil are parallel with the first primary surface, which is a mounting surface, of the body;at least a portion of the body has a magnetic phase containing Fe, Ni, Zn, and Cu and a nonmagnetic phase containing Si;the first outer electrode has, in order from a body side, an underlying electrode and a plating electrode on the underlying electrode;an end of the plating electrode lying in the length direction of a portion of the plating electrode lying on the first primary surface of the body is closer to the second end surface of the body than an end of the underlying electrode in the length direction of a portion of the underlying electrode lying on the first primary surface of the body; anda distance in the length direction between the end of the plating electrode and the end of the underlying electrode is 30 μm or less.

2. The multilayer coil component according to claim 1, wherein: when a boundary is defined that extends parallel with the height and width directions at a midpoint of the body in the length direction, the body has first and second body sections aligned in the length direction with the boundary therebetween, the first body section including the first end surface and the second body section including the second end surface;when a first reference position is defined that coincides in the height direction with the end of the underlying electrode, the first body section has a first region including at least a range having a dimension of 20 μm in the length direction from the first reference position toward the second end surface; andthe first region is totally the nonmagnetic phase or has both the nonmagnetic and magnetic phases.

3. The multilayer coil component according to claim 2, wherein the first region contains, in a total of 100% by weight, 30.0% by weight or more Si in terms of a SiO2 basis.

4. The multilayer coil component according to claim 3, wherein the first region contains, in a total of 100% by weight,Si being from 30.0% by weight to 85.0% by weight in terms of a SiO2 basis,B being from 4.0% by weight to 15.0% by weight in terms of a B2O3 basis,Fe being from 0% by weight to 45.0% by weight in terms of an Fe2O3 basis,Ni being from 0% by weight to 15.0% by weight in terms of a NiO basis,Zn being from 0% by weight to 8.0% by weight in terms of a ZnO basis, andCu being from 0% by weight to 5.0% by weight in terms of a CuO basis.

5. The multilayer coil component according to claim 4, wherein the first region contains, in a total of 100% by weight,K being from 0.3% by weight to 1.5% by weight in terms of a K2O basis andMg being from 0.9% by weight to 3.5% by weight in terms of a MgO basis.

6. The multilayer coil component according to claim 2, wherein: the first body section further has a second region other than the first region; andthe second region is totally the magnetic phase or has both the magnetic and nonmagnetic phases.

7. The multilayer coil component according to claim 6, wherein the second region contains, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO2 basis.

8. The multilayer coil component according to claim 7, wherein the second region contains, in a total of 100% by weight,Si being from 0% by weight to 25.0% by weight in terms of a SiO2 basis,B being from 0% by weight to 5.0% by weight in terms of a B2O3 basis,Fe being from 45.0% by weight to 70.0% by weight in terms of an Fe2O3 basis,Ni being from 10.0% by weight to 20.0% by weight in terms of a NiO basis, andZn being from 5.0% by weight to 12.0% by weight in terms of a ZnO basis.

9. The multilayer coil component according to claim 6, wherein a Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.

10. The multilayer coil component according to claim 3, wherein: the first body section further has a second region other than the first region; andthe second region is totally the magnetic phase or has both the magnetic and nonmagnetic phases.

11. The multilayer coil component according to claim 4, wherein: the first body section further has a second region other than the first region; andthe second region is totally the magnetic phase or has both the magnetic and nonmagnetic phases.

12. The multilayer coil component according to claim 5, wherein: the first body section further has a second region other than the first region; andthe second region is totally the magnetic phase or has both the magnetic and nonmagnetic phases.

13. The multilayer coil component according to claim 10, wherein the second region contains, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO2 basis.

14. The multilayer coil component according to claim 11, wherein the second region contains, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO2 basis.

15. The multilayer coil component according to claim 12, wherein the second region contains, in a total of 100% by weight, 25.0% by weight or less Si in terms of a SiO2 basis.

16. The multilayer coil component according to claim 7, wherein a Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.

17. The multilayer coil component according to claim 8, wherein A Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.

18. The multilayer coil component according to claim 10, wherein A Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.

19. The multilayer coil component according to claim 11, wherein a Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.

20. The multilayer coil component according to claim 12, wherein a Si content of the first region in a total of 100% by weight is larger than a Si content of the second region in a total of 100% by weight by 7.0% by weight or more in terms of a SiO2 basis.