This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2022-095942, filed Jun. 14, 2022, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a wiring board, a semiconductor device, and a method for manufacturing a semiconductor device.
A semiconductor device in which a semiconductor memory and a memory controller are packaged together is known. In such a semiconductor device, semiconductor memory chips, a memory controller, and the like are sometimes flip-chip bonded to a substrate.
In flip-chip bonding, bumps on a semiconductor chip are connected to terminals on a substrate with solder, but the solder may spread over the electrodes beyond the range assumed in the design and this may cause undesirable results.
Embodiments provide a wiring board, a semiconductor device, and a method for manufacturing a semiconductor device that can reduce issues that might otherwise be caused by solder spreading over electrodes when a semiconductor element is flip-chip connected to a wiring board.
In general, according to one embodiment, a wiring board, includes a conductive layer on a first surface and an insulating layer covering a portion of the conductive layer. The conductive layer includes a first connection portion exposed from the insulating layer and having a first wettability to solder, a lead-out portion connected to the first connection portion and exposed from the insulating layer and having a second wettability to solder, and a wiring portion connected to the first connection portion via the lead-out portion and covered with the insulating layer.
In general, according to one embodiment, a wiring board includes: a conductive layer formed on a main surface and an insulating layer covering a portion of the conductive layer. The conductive layer includes: a first connection portion having a first wettability to solder and exposed from the insulating layer; a lead-out portion connected to the first connection portion that has a second wettability to the solder, which is lower than the first wettability, and is exposed from the insulating layer; and a wiring portion connected to the first connection portion via the lead-out portion and covered with the insulating layer.
A wiring board according to another embodiment includes a conductive layer formed on a main surface and an insulating layer covering a portion of the conductive layer. The conductive layer includes: a first connection portion formed with a first metal containing gold as a main component; a lead-out portion connected to the first connection portion, formed with a second metal containing copper as a main component, and exposed from the insulating layer; and a wiring portion connected to the first connection portion via the lead-out portion and covered with the insulating layer.
A semiconductor device according to still another embodiment includes a wiring board with a conductive layer formed on a main surface and an insulating layer covering a portion of the conductive layer. The conductive layer includes: a first connection portion having a first wettability to solder and exposed from the insulating layer; a lead-out portion connected to the first connection portion that has a second wettability to the solder, which is smaller than the first wettability, and is exposed from the insulating layer; and a wiring portion connected to the first connection portion via the lead-out portion and covered with the insulating layer. The semiconductor device further includes a first semiconductor element having a first electrode connected to the first connection portion.
A method for manufacturing a semiconductor device according to an embodiment includes: forming a conductive layer having a second wettability to solder or a conductive layer containing a second metal containing copper as a main component on a main surface; forming an insulating layer covering a first conductive portion that is a portion of the conductive layer; forming a resist layer covering a second conductive portion that is a portion of another portion of the conductive layer exposed from the insulating layer; when a third conductive portion that is a portion of the conductive layer exposed from the insulating layer and the resist layer has the second wettability, forming a first connection portion based on the third conductive portion by treating the third conductive portion so as to have a first wettability larger than the second wettability to the solder or, when third conductive portion contains the second material, forming the first connection portion based on the third conductive portion by forming the first metal containing gold as a main component on the third conductive portion by plating; removing the resist layer; and connecting a first electrode of a first semiconductor element to the first connection portion so that the first electrode faces the first connection portion.
Hereinafter, certain example embodiments will be described with reference to the accompanying drawings. For facilitating understanding of the description, the same components in each drawing are denoted by the same reference symbols, and redundant description of repeated aspects in the drawings may be omitted. A configuration of a semiconductor device 10 according to the embodiment will be described below. Each drawing may have an x axis, a y axis, and a z axis. The x axis, the y axis, and the z axis form a right-handed three-dimensional perpendicular coordinate system. Hereinafter, the arrow direction of the x axis may be referred to as a positive side of the x axis, and the opposite direction of the arrow may be referred to as a negative side of the x axis. The same applies to the other axes. It is noted that the positive side of the z axis and the negative side of the z axis are sometimes referred to as the “upper side” and the “lower side”, respectively. In addition, in some cases, the z axis direction is referred to as the “stacking direction”. In addition, planes perpendicular to the x axis, the y axis, or the z axis are sometimes called a yz-plane, a zx-plane, or a xy-plane.
As illustrated in
Hereinafter, each of the memory chips 60a, 60b, 60c, and 60d may be referred to as a memory chip 60 (a second semiconductor element).
The wiring board 20 includes solder resist layers 20a and 20e (insulating layers), conductive layers 20b and 20d, and an insulating layer 20c.
The solder resist layer 20a, the conductive layer 20b, the insulating layer 20c, the conductive layer 20d, and the solder resist layer 20e are layers extending substantially parallel to the xy plane and are stacked in this order from the upper side to the lower side.
The insulating layer 20c has an upper surface (hereinafter, sometimes referred to as a main surface 20f) that is substantially parallel to the xy plane and a lower surface (hereinafter, sometimes referred to as a main surface 20g) that is substantially parallel to the xy plane. The insulating layer 20c is formed of, for example, a “prepreg” material for electrical circuit boards, printed circuit boards, or the like. It is noted that in some examples one or more internal conductive layers may be formed inside the insulating layer 20c.
The conductive layers 20b and 20d are made of, for example, a metal (hereinafter, sometimes referred to as a second metal) containing copper as a main component. The conductive layers 20b and 20d have patterns 21 and 22, respectively, which are wiring patterns (hereinafter, “wiring patterns” may be simply referred to as “patterns”). The patterns 21 and 22 are formed on the main surfaces 20f and 20g, respectively.
The pattern 21 includes a plurality of first connection portions 21a (third conductive portions), a plurality of lead-out portions 21b, a plurality of wiring portions 21c, a plurality of second connection portions 21d, and a plurality of third connection portions 21e. The first connection portion 21a, the lead-out portion 21b, and the wiring portion 21c are integrally formed in this example.
The first connection portion 21a and the second connection portion 21d are board-side flip-chip mounting terminals (also referred to as flip chip pads) used for flip-chip connecting the logic/interface chip 62 to the wiring board 20.
The third connection portion 21e is a wire bonding mounting terminal (also referred to as a wire bonding pad) used for wire bonding between the memory chip 60 and the wiring board 20. Each of the first connection portion 21a, the second connection portion 21d, and the third connection portion 21e includes an electroless NiPdAu plating 31 (electroless plated film(s)). Details of the electroless NiPdAu plating 31 will be described later.
A plurality of through via holes 72 are formed in the insulating layer 20c. Some of the electrodes provided in the pattern 21 and some of the electrodes provided in the pattern 22 are electrically connected by connections made through the through via holes 72.
The solder resist layer 20a includes solder resists 23a and 23b (solder resist portions). Each of the solder resists 23a and 23b covers a portion of the pattern 21 and a portion of the main surface 20f of the insulating layer 20c from the upper side. When the wiring board 20 is completed, the pattern 21, the insulating layer 20c, or the electroless NiPdAu plating 31 is exposed where the solder resist 23a or 23b is not formed (absent).
The solder resist layer 20e includes a solder resist 24. The solder resist 24 covers a portion of the pattern 22 and a portion of the main surface 20g of the insulating layer 20c from the lower side. A plurality of openings are formed in the solder resist 24 when the wiring board 20 is finished. Ball lands 73 are formed in the plurality of openings in the solder resist 24. Specifically, the patterns 22 provided with the electroless NiPdAu plating 31 are provided in the plurality of openings. It is noted that in some examples patterns 22 covered with an organic solderability preservative (OSP) film, which may be referred to as CuOSP or anti-tarnish film, may be provided in the plurality of openings instead of the patterns 22 with the electroless NiPdAu plating 31 thereon.
Solder balls 74 are formed on the electroless NiPdAu plating 31 in the plurality of openings. It is noted that solder in this specification takes the meaning of those skilled in the art as a meltable metal or metal alloy used for making connections between (joining) different components. In general, the solder is electrically conductive. For example, the solder may have tin (Sn) as the main component.
The logic/interface chip 62 is flip-chip connected to the upper side of the wiring board 20. Specifically, the logic/interface chip 62 includes a plurality of chip-side flip-chip mounting terminals 62a (first electrodes) and a plurality of chip-side flip-chip mounting terminals 62d (second electrodes).
The chip-side flip-chip mounting terminals 62a include copper pillars 62b extending downward from the lower surface of the logic/interface chip 62 and solder bumps 62c provided at distal ends of the copper pillars 62b. The chip-side flip-chip mounting terminals 62d have the same general configuration as the chip-side flip-chip mounting terminals 62a.
The chip-side flip-chip mounting terminals 62a are, for example, terminals for transmitting control signals for causing the memory chip 60 to read and write data. The chip-side flip-chip mounting terminals 62d are, for example, terminals for connecting the logic/interface chip 62 to power supply lines or ground electrodes on the wiring board 20.
The plurality of chip-side flip-chip mounting terminals 62a are connected to the plurality of first connection portions 21a, that is, the flip chip pads 21a with the solder bumps 62c, respectively, and the plurality of chip-side flip-chip mounting terminals 62d are connected to the plurality of the second connection portions 21d, that is, the flip chip pads 21d with the solder bumps, respectively. Accordingly, the logic/interface chip 62 is flip-chip connected to the wiring board 20.
The memory chips 60 are stacked on the logic/interface chip 62. Specifically, in this example, the spacer 63 is adhered to the upper surface of the solder resist 23a with the adhesive film 64. The memory chip 60d is adhered to the upper surface of the spacer 63 and the upper surface of the logic/interface chip 62 with the die attach film 61d.
Above the memory chip 60d, the memory chips 60c, 60b, and 60a are adhered to the lower adjacent memory chip 60 with the die attach films 61c, 61b, and 61a, respectively.
In this example, when upper memory chip 60 is adhered to the lower memory chip 60, a portion of the upper surface of the lower memory chip 60 is left exposed (that is, adjacent memory chips are partially offset from one another in position along the x direction or the like). The upper surface of the uppermost memory chip 60, that is, the memory chip 60a, is entirely exposed (that is, no other memory chip 60 covers the upper surface of memory chip 60a).
Electrodes 69a, 69b, 69c, and 69d are provided on the exposed upper surfaces of the memory chips 60a, 60b, 60c, and 60d, respectively. Hereinafter, each of the electrodes 69a, 69b, 69c, and 69d may be referred to as an electrode 69. The bonding wire 68 electrically connects an electrode 69 and a third connection portion 21e, that is, the wire bonding pad 21e.
The underfill resin 65 is provided in a region between the chip-side flip-chip mounting terminals 62a and 62d and the memory chip 60d and the wiring board 20.
The underfill resin 65 is used in order to relieve stress on the chip-side flip-chip mounting terminals 62a and 62d of the logic/interface chip 62.
The mold resin 66 is provided in a region between the memory chip 60d and the wiring board 20. The mold resin 66 is a resin for sealing (encapsulating) the memory chip 60 and the logic/interface chip 62 and can be a thermosetting resin such as an epoxy resin. The mold resin 66 may contain glass fibers and inorganic particles as fillers. The mold resin 66 may contain a higher content of fillers than the underfill resin 65. The mold resin 66 also has a higher elastic modulus and Young's modulus than the underfill resin 65. It is noted that a heat dissipation sheet may be provided between the mold resin 66 and the underfill resin 65 in some examples.
As illustrated in
The flip chip pad 21a has a wettability of a first value (a first wettability) towards solder. The Au layer 31a contains gold (sometimes referred to as a first metal) as a main component and is located on the front side of the flip chip pad 21a. The first metal provides the first wettability towards solder.
As illustrated in
Specifically, the electroless NiPdAu plating 31 is formed on the Cu wiring 32. In the electroless NiPdAu plating 31, the Ni layer 31c, the Pd layer 31b, and the Au layer 31a are located in this order from the Cu wiring 32. That is, the Ni layer 31c is in contact with the Cu wiring 32. The Au layer 31a is located on the outermost side, is exposed, and has a first wettability. The Pd layer 31b is located between the Au layer 31a and the Ni layer 31c.
The lead-out portion 21b is connected to the flip chip pad 21a and has a wettability of a second value (a second wettability) towards solder. The second wettability is less than the first wettability (that is, the solder is less wettable on the lead-out portion 21b than on the Au layer 31a. Specifically, the second metal is located on the front side of the lead-out portion 21b. The second metal provides the second wettability.
In an embodiment, the lead-out portion 21b is a bare Cu wiring 33 when the wiring board 20 is completed. That is, the second metal having a second wettability is exposed in the lead-out portion 21b.
The wiring portion 21c is connected to the flip chip pad 21a through the lead-out portion 21b and is covered with the solder resist 23a. The height of the lead-out portion 21b from the main surface 20f and the height of the wiring portion 21c from the main surface 20f are substantially the same.
In an embodiment, the conductive layer 20b has the same thickness over substantially the entire main surface 20f. The pattern 21 is formed by etching the conductive layer 20b. In an embodiment, the thickness of the pattern 21 is substantially the same regardless of the location since a process of irradiating the pattern 21 with laser light is not used. Therefore, the thickness of the lead-out portion 21b and the thickness of the wiring portion 21c can be substantially the same. With such a configuration, the deterioration of electrical characteristics based on the increase in electrical resistance can be reduced upon reductions in the thickness of the pattern 21 can be avoided.
As illustrated in
The area A3 is covered with the solder resist 23b which has a plurality of openings 51 (first openings). The flip chip pad 21d is formed in an opening 51 and has a first wettability. The Au layer 31a is located on the front side of the flip chip pad 21d.
The outer edge of the area A3 is rectangular in this example. In the area A3, a plurality of slot-shaped openings 51 are provided in the solder resist 23b. The flip chip pad 21d includes the electroless NiPdAu plating 31 and the Cu electrode 34 that is a portion of the pattern 21.
The Cu electrode 34 provided in the pattern 21 is exposed in an opening 51. The electroless NiPdAu plating 31 is provided on the upper surface of the Cu electrode 34 so as not to be in contact with the outer edge of the opening 51.
That is, when the wiring board 20 is completed, the Cu electrode 34 is left exposed in an annular region along the edge of each opening 51.
The planar area of the opening 51 is smaller than the planar area of the Cu electrode 34. That is, the over-resist design is made such that the opening 51 of the solder resist 23b becomes the land size. The flip chip pad 21d is a Solder Mask Defined (SMD) type pad.
The area A2 includes the flip chip pads 21a and the lead-out portions 21b. The area A2 surrounds the area A3 in an XY plane.
The area A2 is rectangular. The solder resists 23a and 23b are not provided in area A2. Therefore, in the area A2, when the wiring board 20 is completed, the main surface 20f, the flip chip pads 21a, and the lead-out portions 21b of the insulating layer 20c are left exposed. That is, the flip chip pad 21a is a Nonsolder Mask Defined (NSMD) type pad.
The area A1 includes the wiring portion 21c and is covered with the solder resist 23a. The area A1 surrounds the area A2 in an XY plane.
The area A1 is rectangular. A plurality of openings 52 (second openings) are formed in the solder resist 23a. The wire bonding pads 21e are formed in the openings 52. The wire bonding pad 21e has a first wettability.
The wire bonding pad 21e includes the electroless NiPdAu plating 31 and the Cu electrode 35 that is a portion of the pattern 21. The planar area of the opening 52 is less than the size of the Cu electrode 35. That is, the wire bonding pad 21e is an SMD type pad. It is noted that the wire bonding pad 21e may be an NSMD type pad in other examples.
The electroless NiPdAu plating 31 is provided on the upper surface of the Cu electrode 35 so as to be in contact with the edge of the opening 52. When the wiring board 20 is completed, the Au layer 31a of the electroless NiPdAu plating 31 is exposed in the opening 52.
The wiring portion 21c is covered with the solder resist 23a. Therefore, when the wiring board 20 is completed, the wiring portion 21c is not left exposed.
As illustrated in
In this process, the melted solder bump 62c is in contact with both the copper pillar 62b and the electroless NiPdAu plating 31 (hereinafter, this state is sometimes referred to as a both-contacted state). However, since the Au layer 31a has a high wettability (first wettability) towards solder, the solder bump 62c spreads over the entire Au layer 31a. The amount of solder between the copper pillar 62b and the electroless NiPdAu plating 31 may be insufficient for such coverage, and thus, sometimes, the both-contacted state is less likely to be maintained.
In addition, the logic/interface chip 62 may be warped in the reflow process. When such warping occurs, the distance between the flip chip pad 21a and the copper pillar 62b may become larger than intended or designed. For the flip chip pad 21a at such a large distance from the copper pillar 62b, the both-contacted state is even less likely to be maintained.
When the both-contacted state cannot be maintained, the copper pillar 62b and the flip chip pad 21a are not electrically connected and will be in an open electrical state (non-connection).
As illustrated in
In a reflow process, the solder bumps 62c on the chip-side flip-chip mounting terminals 62a are in a both-contacted state. Since the second wettability of the surface of the bare Cu wiring 33 in the lead-out portion 21b is less than the first wettability of the surface of the Au layer 31a in the flip chip pad 21a, the spread of the solder bump 62c is likely stop at the boundary between the flip chip pad 21a and the lead-out portion 21b.
Accordingly, the possibility of maintaining both-contacted state can be increased since a sufficient amount of solder can be provided between the copper pillar 62b and the electroless NiPdAu plating 31.
In addition, even when the logic/interface chip 62 is warped in the reflow process, the possibility of maintaining the both-contacted state can be increased since solder spread is limited. Therefore, the occurrence of an open state (non-connection) can be reduced.
In plan from the upper direction, the area of the flip chip pad 21d is larger than the area of the flip chip pad 21a. In the case of the pad having a large area such as the flip chip pad 21d, the position of the opening 51 of the solder resist 23b can be aligned with the position of the flip chip pad 21d.
On the other hand, when the formation accuracy of the openings in the solder resist is not sufficient for such alignment, the positions for the flip chip pads can not be formed with a high accuracy. In particular, when the area of the pad is small (like the flip chip pad 21a), the opening at the position of the pad is less likely to be formed accurately.
In the present disclosure, by setting the flip chip pad 21a (having a small area) as an NSMD type pad and preparing the lead-out portion 21b connected to the flip chip pad 21a, the outflow of solder can be reduced without using a solder resist. Therefore, even when the formation accuracy of the openings in the solder resist is not high, a configuration for reducing the outflow of solder from the flip chip pads can still be achieved.
As illustrated in
In such a case, even when the amount of solder on the solder bumps 62c is large in the reflow process and the melted solder bumps 62c flow beyond the edge of the electroless NiPdAu plating 31, the spread of the solder can be reduced in the lead-out portions 21b. Accordingly, since a sufficient amount of solder can be secured between the copper pillar 62b and the electroless NiPdAu plating 31, the possibility of maintaining the both-contacted state can be increased. Therefore, the occurrence of the open state can be reduced.
Hereinafter, a method for manufacturing a semiconductor device 10 will be described below as an example of the method for manufacturing a semiconductor device according to the present disclosure.
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Next, the logic/interface chip 62 is flip-chip connected to the wiring board 20 by connecting the chip-side flip-chip mounting terminals 62a and 62d of the logic/interface chip 62 to the flip chip pads 21a and 21d, respectively.
A method for manufacturing a semiconductor device according to a comparative example (“Comparative Example”) will be described below.
For the Comparative Example, the process of manufacturing the semiconductor device 10 illustrated in FIGS. to 10C is performed.
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Subsequently, the OSP film 41 can be removed by flux or the like.
Next, the logic/interface chip 62 is flip-chip connected to the wiring board 20r.
When an OSP film 41 is not formed, an oxide film on the surface of the second metal forms containing copper as a main component on an unprotected OSP target portion 21h and the oxide film may become thick. As the oxide film becomes thicker, the adhesion to solder is deteriorated. When the time from the completion of the wiring board 20r to the time of the flip-chip connection of the logic/interface chip 62 becomes long, the solderability can be significantly deteriorated. Therefore, the process of forming the OSP film 41 on the OSP target portion 21h must generally be performed in order to limit the oxidation of the surface of the second metal.
In addition, for the OSP target portion 21h electrically connected to the wire bonding pad 21e through the pattern 21, in the acid etching treatment performed before the forming of the OSP film 41, a battery (electrochemical cell) is formed with gold of the Au layer 31a, copper in the OSP target portion 21h, and the like. In such a process, the copper in the flip chip pad may be becomes copper ions and dissolve into the acid etching solution, at least some portion of the OSP target portion 21h is consumed/lost.
For to the OSP target portion 21h not electrically connected to the wire bonding pad 21e through the pattern 21, since no battery (electrochemical cell) is formed, consumption of the OSP target portion 21h is reduced. That is, the thickness of the OSP target portion 21h may vary depending on the presence or absence of an electrical connection with the wire bonding pad 21e through the pattern 21. For this reason, the thickness of the flip chip pads varies, and thus, the possibility of the deterioration in the connectivity during the flip chip connection becomes high.
On the other hand, for the wiring board 20 illustrated in
Since a natural oxide film is not formed on the Au layer 31a of the electroless NiPdAu plating 31, the deterioration in adhesion to the soldering can be reduced without requiring the forming of any OSP film. Therefore, the process of forming the OSP film and the process of removing such a film by flux are not required, and thus, the process of manufacturing the wiring board 20 can be simplified, and the manufacturing cost of the wiring board 20 can be reduced.
In addition, for the wiring board 20 illustrated in
In addition, even if the acid etching is performed for some purpose, since the electroless NiPdAu plating 31 is applied to all the flip chip pads 21a and the wire bonding pads 21e, no battery is formed between these pads. In other words, with respect to the wiring board 20 illustrated in
(a) Although the configuration in which the electroless NiPdAu plating 31 is applied to the pattern 22 has been described as an embodiment, the present disclosure is not limited thereto. The pattern 22 may be applied with other types of plating such as electrolytic NiAu plating. When the wettability of the flip chip pad 21a (first wettability) is larger than the wettability of the lead-out portion 21b (second wettability), plating does not necessarily need to be applied to the flip chip pad 21a.
Although an example in which the first metal is a metal containing gold as a main component has been described, the present disclosure is not limited thereto. The first metal may contain a metal other than Au as a main component. In addition, while an example in which the second metal is a metal containing copper as a main component has been described, the present disclosure is not limited thereto. The second metal may contain a metal other than Cu as a main component.
(b) In an embodiment, a configuration in which the lead-out portion 21b is the bare Cu wiring 33 has been described, but the present disclosure is not limited thereto. If the second wettability of the lead-out portion 21b is less than the first wettability of the flip chip pad 21a, a configuration in which plating is applied to the lead-out portion 21b may be adopted.
Embodiments have been described above with reference to specific examples. However, the present disclosure is not limited to these specific examples. Modifications of these specific examples which would be obvious to those of ordinary skill in the art are also in the scope of the present disclosure. Example components described above may be modified in various aspects such as relative arrangements, processing conditions, shapes, and the like so long as the modifications still incorporate features of the present disclosure. The various components provided in the specific examples described above may be changed and/or combined as appropriate.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the disclosure. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the disclosure. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the disclosure.
Number | Date | Country | Kind |
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2022-095942 | Jun 2022 | JP | national |