PATENT ABSTRACT
A wiring board includes: a first wiring layer; a first insulating layer formed on the first wiring layer and including a reinforcing material therein, the first insulating layer having a first opening; a contact layer formed on the first insulating layer and having a second opening communicated with the first opening; and a second wiring layer comprising a second via and a second wiring pattern connected to the second via. The second wiring pattern is formed on the contact layer, and the second via is filled in the first and second openings. An adhesion property between the contact layer and the second wiring pattern is higher than that between the first insulating layer and the second wiring pattern, and a thickness of the contact layer is smaller than that of the first insulating layer.

PATENT DESCRIPTION
This application claims priority from Japanese Patent Application No. 2011-198564, filed on Sep. 12, 2011, the entire contents of which are herein incorporated by reference. 
     BACKGROUND 
     1. Technical Field 
     Embodiments described herein relate to a wiring board and a method for manufacturing the wiring board. 
     2. Related Art 
     Increase in density of a mounted semiconductor chip has heretofore advanced, so that reduction in thickness of a wiring board and increase in density of wiring patterns have been required. To meet such requirements, a wiring board after removal of a core board (support board) having high rigidity and thicker than an interlayer insulating film, that is, a so-called coreless board has been proposed. 
     In a basic process of the coreless board, a temporary board is first prepared as a support board. A wiring layer serving as pads is formed on the temporary board. Then, after a required number of wiring layers and insulating layers are built up, the temporary board is finally removed. 
     A technique of providing any one of formed insulating layers in this type coreless board as an insulating layer improved in mechanical strength by a reinforcing material to reduce warping of the board has been proposed recently (e.g. see JP-A-2007-96260). 
     However, in the wiring board having the reinforcing material-containing insulating layer, there is a problem that fine wirings cannot be formed on the reinforcing material-containing insulating layer. To describe in detail, for example, when wiring patterns are formed on the reinforcing material-containing insulating layer by a semi-additive method, the upper surface of the insulating layer is etched by desmear processing so that the roughness of the upper surface of the insulating layer becomes large (e.g. about 800 nm to about 1000 nm in terms of surface roughness Ra value). When the upper surface (front surface) is roughened in this manner, it is difficult to form fine wirings on the upper surface with high accuracy. Specifically, it is difficult to form fine wirings of L/S (Line/Space)=15 μm/15 μm or less on the reinforcing material-containing insulating layer with high accuracy after the desmear processing. 
     SUMMARY OF THE INVENTION 
     According to one or more illustrative aspects of the present invention, there is provided a wiring board. The wiring board comprises: a first wiring layer; a first insulating layer formed on the first wiring layer and comprising a reinforcing material therein, the first insulating layer having a first opening; a contact layer formed on the first insulating layer and having a second opening communicated with the first opening, wherein the first wiring layer is exposed through the first and second openings; and a second wiring layer comprising a second via and a second wiring pattern connected to the second via, wherein the second wiring pattern is formed on the contact layer, and the second via is filled in the first and second openings. An adhesion property between the contact layer and the second wiring pattern is higher than an adhesion property between the first insulating layer and the second wiring pattern, and a thickness of the contact layer is smaller than that of the first insulating layer. 
     According to one or more illustrative aspects of the present invention, there is provided a wiring board. The wiring board comprises: a plurality of multilayer wiring structures stacked one on top of another. Each of the plurality of multilayer wiring structures comprises: an insulating layer comprising a reinforcing material therein, the insulating layer having a first opening; a contact layer formed on the insulating layer and having a second opening communicated with the first opening; and a wiring layer comprising a via and a wiring pattern connected to the via, wherein the wiring pattern is formed on the contact layer, and the via is filled in the first and second openings. An adhesion property between the contact layer and the wiring pattern is higher than an adhesion property between the insulating layer and the wiring pattern, and a thickness of the contact layer is smaller than that of the insulating layer. 
     According to one or more illustrative aspects of the present invention, there is provided a method of manufacturing a wiring board. The method comprises: (a) forming a multilayer wiring structure comprising a first wiring layer and a first insulating layer on a support board; (b) forming a second insulating layer comprising a reinforcing material therein on the multilayer wiring structure; (c) forming a contact layer on the second insulating layer; (d) forming a hole through the second insulating layer and the contact layer to expose the first wiring layer; (e) forming a second wring layer in the hole and on the contact layer; and (f) removing the support board. An adhesion property between the contact layer and the second wiring layer is higher than an adhesion property between the second insulating layer and the second wiring layer, and a thickness of the contact layer is smaller than that of the second insulating layer. 
     Other aspects and advantages of the present invention will be apparent from the following description, the drawings and the claims. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a schematic sectional view showing a wiring board according to a first embodiment; 
         FIG. 2  is a schematic sectional view showing a semiconductor package in the first embodiment; 
         FIGS. 3A to 3E  are schematic sectional views showing a method of manufacturing the wiring board according to the first embodiment; 
         FIGS. 4A to 4C  are schematic sectional views showing the method of manufacturing the wiring board according to the first embodiment; 
         FIGS. 5A to 5C  are schematic sectional views showing the method of manufacturing the wiring board according to the first embodiment; 
         FIGS. 6A to 6C  are schematic sectional views showing the method of manufacturing the wiring board according to the first embodiment; 
         FIGS. 7A and 7B  are schematic sectional views showing the method of manufacturing the wiring board according to the first embodiment; 
         FIG. 8A  is a schematic sectional views showing the method of manufacturing the wiring board according to the first embodiment; 
         FIG. 8B  is a schematic sectional view showing a method of manufacturing a semiconductor package according to the first embodiment; 
         FIGS. 9A and 9B  are schematic sectional views showing the method of manufacturing the semiconductor package according to first embodiment; 
         FIGS. 10A and 10B  are schematic sectional views showing a wiring board according to a modification of the first embodiment; 
         FIG. 11  is a schematic sectional view showing a wiring board according to a modification of the first embodiment; 
         FIG. 12A  is a schematic sectional view showing a wiring board according to Example 1; 
         FIG. 12B  is a table showing simulation conditions; 
         FIG. 12C  is an explanatory view showing a method for measuring warping; 
         FIGS. 13A to 13F  are schematic sectional views showing wiring boards according to Examples 2 and 3 and Comparative Examples 1 to 4; 
         FIG. 14  is a schematic sectional view showing a wiring board according to a second embodiment; 
         FIGS. 15A to 15C  are schematic sectional views showing a method of manufacturing the wiring board according to the second embodiment; 
         FIGS. 16A to 16C  are schematic sectional views showing the method of manufacturing the wiring board according to the second embodiment; and 
         FIG. 17  is a schematic sectional view showing a wiring board according to a modification of the second embodiment. 
     
    
    
     DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS 
     Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In all the drawings for the explanation of the embodiments, the members having the same functions are represented by the same reference numerals, and repeated description thereof will be omitted. 
     First Embodiment 
     A first embodiment will be described below with reference to  FIGS. 1 ,  2 ,  3 A- 3 E,  4 A- 4 C,  5 A- 5 C,  6 A- 6 C,  7 A- 7 B,  8 A- 8 B and  9 A- 9 B. 
     Structure of Wiring Board According to First Embodiment 
     The structure of a wiring board  1  will be described first. 
     As shown in  FIG. 1 , the wiring board  1  has such a structure that a first wiring layer  11 , a first insulating layer  20 , a second wiring layer  21 , a second insulating layer  30 , a third wiring layer  31 , a third insulating layer  40 , a fourth wiring layer  42 , a fourth insulating layer  50 , a fifth wiring layer  51 , a fifth insulating layer  60  and a sixth wiring layer  61  are formed successively. In this manner, the wiring board  1  according to this embodiment has the form of a “coreless board” not containing any support base material differently from a wiring board (a laminate obtained in such a manner that a required number of build-up layers are formed successively on both surfaces or one surface of a core board as a support base material) produced by a general build-up method. 
     Incidentally, metal such as copper, copper alloy, etc. can be used as the material of each of the second to sixth wiring layers  21 ,  31 ,  42 ,  51  and  61 . 
     In the wiring board  1 , the first wiring layer  11  is formed as the lowermost layer in  FIG. 1 . The first wiring layer  11  has a first conductive layer  12 , and a second conductive layer  13 . For example, a conductive layer in which a gold (Au) film, a palladium (Pd) film and a nickel (Ni) film are formed successively in this order so that the Au film is exposed out of the wiring board  1  can be used as the first conductive layer  12 . For example, a conductive layer containing a copper (Cu) layer or the like can be used as the second conductive layer  13 . 
     Parts of the first wiring layer  11 , that is, a first principal surface  12 A (a lower surface in the drawing) of the first conductive layer  12  are exposed out of the first insulating layer  20  and serve as electrode pads  11 P electrically connected to a semiconductor chip  70  (see  FIG. 2 ). That is, in this embodiment, a surface where the electrode pads  11 P are formed is provided as a chip mount surface. For example, the planer shape of the first wiring layer  11  exposed out of the first insulating layer  20  is circular. For example, the diameter of each circle can be set to be in a range of about 40 μm to about 120 μm. For example, the pitch of the first wiring layer  11  exposed out of the first insulating layer  20  can be set to be in a range of about 100 μm to about 200 μm. For example, the thickness of the first wiring layer  11  can be set to be in a range of about 10 μm to about 20 μm. 
     The first insulating layer  20  is formed so that a second principal surface (an upper surface in the drawing) and side surfaces of the first wiring layer  11  are covered but the first principal surface  12 A of the first wiring layer  11  is exposed. An epoxy-based insulating resin having thermosetting characteristic can be used as the material of the first insulating layer  20 . Incidentally, the insulating resin is not limited to a resin having thermosetting characteristic but an insulating resin having photosensitivity may be used. For example, the thickness of the first insulating layer  20  can be set to be in a range of about 15 μm to about 35 μm. 
     The second wiring layer  21  is formed on the first insulating layer  20 . The second wiring layer  21  has via-wirings  21   a  packed in via-holes VH 1  which are formed through the first insulating layer  20  to expose the upper surface of the first wiring layer  11 , and wiring patterns  21   b  formed on the first insulating layer  20 . The via-wirings  21   a  are electrically connected to the first wiring layer  11  (exposed in the bottoms of the via-holes VH 1 ). Incidentally, each of the via-holes VH 1  and the via-wirings  21   a  formed in the via-holes VH 1  is tapered to have a shape having its diameter increasing as the position goes from the lower side (electrode pad  11 P (chip mount surface) side) to the upper side (sixth wiring layer  61  side) in  FIG. 1 . For example, the thickness of the wiring patterns  21   b  of the second wiring layer  21  can be set to be in a range of about 20 μm to about 35 μm. 
     The second insulating layer  30  is formed on the first insulating layer  20  so that the second wiring layer  21  is covered with the second insulating layer  30 . For example, an insulating resin having the same composition as that of the first insulating layer  20  can be used as the material of the second insulating layer  30 . For example, the thickness of the second insulating layer  30  can be set to be in a range of about 15 μm to about 35 μm. 
     The third wiring layer  31  is formed on the second insulating layer  30 . The third wiring layer  31  has via-wirings  31   a  packed in via-holes VH 2  which are formed through the second insulating layer  30  to expose the upper surface of the second wiring layer  21 , and wiring patterns  31   b  formed on the second insulating layer  30 . The via-wirings  31   a  are electrically connected to the second wiring layer  21  exposed in the bottoms of the via-holes VH 2 . Incidentally, each of the via-holes VH 2  and the via-wirings  31   a  is tapered to have a shape having its diameter increasing as the position goes from the lower side to the upper side in  FIG. 1 . For example, the thickness of the wiring patterns  31   b  of the third wiring layer  31  can be set to be in a range of about 20 μm to about 35 μm. 
     The third insulating layer  40  has an insulating layer  40 A, and a contact layer  41 A. The insulating layer  40 A is formed on the second insulating layer  30  so that the upper surface and side surfaces of the third wiring layer  31  (specifically, the wiring patterns  31   b ) are covered with the insulating layer  40 A. The insulating layer  40 A is a reinforcing material-containing insulating layer, i.e. an insulating layer higher in mechanical strength (rigidity, hardness, etc.) than the other insulating layers  20 ,  30 ,  50  and  60 . For example, an insulating resin obtained by adding a reinforcing material into a thermosetting resin can be used as the material of the insulating layer  40 A. Specifically, a reinforcing material-containing insulating resin obtained by impregnating woven or unwoven fabric of glass, aramid or LCP (Liquid Crystal Polymer) fiber with an epoxy-based or polyimide-based thermosetting resin can be used as the material of the insulating layer  40 A. It is preferable that an insulating resin adjusted so that the glass transition temperature Tg of the insulating layer  40 A is higher (e.g. about 200° C. to 250° C.) than the glass transition temperature Tg (e.g. about 150° C.) of the other insulating layers  20 ,  30 ,  50  and  60  is used as the material of the insulating layer  40 A. It is more preferable that an insulating resin adjusted so that the thermal expansion coefficient of the insulating layer  40 A becomes close to the thermal expansion coefficient (e.g. about 17 ppm/° C.) of copper which is the material of each of the third and fourth wiring layers  31  and  42  is used as the material of the insulating layer  40 A. Incidentally, for example, the thickness of the insulating layer  40 A can be set to be in a range of about 30 μm to about 60 μm. It is preferable from the viewpoint of improving mechanical strength that the insulating layer  40 A is formed to be thicker than the other insulating layers  20 ,  30 ,  50  and  60  containing no reinforcing material. 
     The contact layer  41 A is formed on the insulating layer  40 A so that the upper surface of the insulating layer  40 A is covered with the contact layer  41 A. The contact layer  41 A is an insulating layer which is higher in the degree of adhesion to a metal film (e.g. electroless plating) than the insulating layer  40 A and which is thinner than the insulating layer  40 A. The contact layer  41 A can be formed so as to be thinner than the wiring patterns  42   b  of the fourth wiring layer  42  formed on the contact layer  41 A. That is, because the contact layer  41 A is formed on the insulating layer  40 A which covers the third wiring layer  31  as a lower layer, and the contact layer  41 A does not have to cover the wiring layer to keep insulation between formed wiring layers, unlike the insulating layer  40 A and the other insulating layers  20 , etc., the contact layer  41 A can be formed so as to be thinner than the wiring patterns  42   b . For this reason, it is preferable from the viewpoint of reduction in thickness of the wiring board  1  that the contact layer  41 A is set to be thinner than the wiring patterns  42   b . Speaking more, it is preferable from the viewpoint of reduction in warp of the wiring board  1  that the contact layer  41 A is set to be sufficiently thinner than the insulating layer  40 A. Specifically, it is preferable that the thickness of the contact layer  41 A is not larger than 17% of the thickness of the insulating layer  40 A, and it is more preferable that the thickness of the contact layer  41 A is not larger than 10% of the thickness of the insulating layer  40 A. For example, the thickness of the contact layer  41 A can be set to be in a range of about 0.5 μm to about 5 μm. 
     For example, an insulating resin containing a thermosetting resin containing an epoxy-based resin as its main component, and an inorganic filler can be used as the material of the contact layer  41 A. Specifically, an insulating resin having a composition (e.g. epoxy resin and inorganic filler contents) adjusted so that the peel strength when the contact layer  41 A is electrolessly plated is at least higher than the peel strength (e.g. 100 to 200 N/m) when the insulating layer  40 A is electrolessly plated is preferred as the material of the contact layer  41 A. The term “peel strength” mentioned herein means a value (strength of peeling) indicating adhesion force between a conductor pattern (electroless plating) and an insulating layer. The peel strength is expressed in force (N/m) required for peeling a 1 m-wide conductor pattern from an insulating layer when the conductor pattern is pulled perpendicularly to be peeled from the insulating layer. The peel strength indicates that the adhesion strength between the conductor pattern and the insulating layer increases as the value of the force increases. An insulating resin adjusted so that the peel strength when the contact layer  41 A is electrolessly plated is not lower than 850 N/m which is higher than the peel strength (e.g. 600 N/m to 700 N/m) when the first insulating layer  20  is electrolessly plated is further preferred as the material of the contact layer  41 A. It is preferable that an insulating resin more excellent in chemical resistance (e.g. desmear resistance) than the insulating layer  40 A is used as the material of the contact layer  41 A. That is, it is preferable that an insulating resin hardly etched by a desmear processing liquid is used as the material of the contact layer  41 A. It is preferable that an insulating resin adjusted so that the glass transition temperature Tg of the contact layer  41 A is not lower than 150° C. is used as the material of the contact layer  41 A. It is preferable that an insulating resin, for example, containing 30 vol % or more of an epoxy resin, and a relatively small amount (e.g. 1 vol % to 50 vol %, both inclusively) of an inorganic filler is used as a specific material of the contact layer  41 A for achieving the aforementioned characteristic. It is more preferable that an insulating resin containing 30 vol % to 65 vol % (both inclusively) of an epoxy resin, and 1 vol % to 30 vol % (both inclusively) of an inorganic filler is used as a specific material of the contact layer  41 A. Incidentally, the thermal expansion coefficient of the contact layer  41 A takes a relatively high value of about 40 ppm/° C. to about 100 ppm/° C. because the inorganic filler content is relatively small as described above. 
     Moreover, the contact layer  41 A is an insulating layer higher in surface smoothness than the insulating layer  40 A. That is, the upper surface of the contact layer  41 A (a surface opposite to a surface being in contact with the insulating layer  40 A) is an even smooth surface (low roughness surface). Specifically, the upper surface of the contact layer  41 A is a low roughness surface where shallow fine irregularities are formed. More specifically, the roughness of the upper surface of the contact layer  41 A is set to be in a range of 50 nm to 350 nm in terms of surface roughness Ra value. The surface roughness Ra value mentioned herein is a kind of numerical value expressing surface roughness and is called arithmetic average roughness. Specifically, the surface roughness Ra value is calculated in such a manner that the absolute value of a height varying in a measurement region is measured from a surface as an average line and subjected to arithmetic averaging. 
     The fourth wiring layer  42  is formed on the contact layer  41 A. The fourth wiring layer  42  has via-wirings  42   a  packed in via-holes VH 3  which are formed through the third insulating layer  40  (the insulating layer  40 A and the contact layer  41 A) to expose the upper surface of the third wiring layer  31 , and wiring patterns  42   b  formed on the contact layer  41 A. The via-wirings  42   a  are electrically connected to the third wiring layer  31  exposed in the bottoms of the via-holes VH 3 . Incidentally, each of the via-holes VH 3  and the via-wirings  42   a  is tapered to have a shape having its diameter increasing as the position goes from the lower side to the upper side in  FIG. 1 . For example, the thickness of the wiring patterns  42   b  of the fourth wiring layer  42  can be set to be in a range of about 20 μm to 35 μm. 
     The fourth insulating layer  50  is formed on the contact layer  41 A so that the fourth wiring layer  42  is covered with the fourth insulating layer  50 . For example, an insulating resin having the same composition as that of the first insulating layer  20  can be used as the material of the fourth insulating layer  50 . For example, the thickness of the fourth insulating layer  50  can be set to be in a range of about 15 μm to about 35 μm. 
     The fifth wiring layer  51  is formed on the fourth insulating layer  50 . The fifth wiring layer  51  has via-wirings  51   a  packed in via-holes VH 4  which are formed through the fourth insulating layer  50  to expose the upper surface of the fourth wiring layer  42 , and wiring patterns  51   b  formed on the fourth insulating layer  50 . The via-wirings  51   a  are electrically connected to the fourth wiring layer  42  exposed in the bottoms of the via-holes VH 4 . Incidentally, each of the via-holes VH 4  and the via-wirings  51   a  is tapered to have a shape having its diameter increasing as the position goes from the lower side to the upper side in  FIG. 1 . For example, the thickness of the wiring patterns  51   b  of the fifth wiring layer  51  can be set to be in a range of about 20 μm to about 35 μm. 
     The fifth insulating layer  60  is formed on the fourth insulating layer  50  so that the fifth wiring layer  51  is covered with the fifth insulating layer  60 . For example, an insulating resin having the same composition as that of the first insulating layer  20  can be used as the material of the fifth insulating layer  60 . For example, the thickness of the fifth insulating layer  60  can be set to be in a range of about 15 μm to about 35 μm. 
     The sixth wiring layer  61  is an uppermost (outermost) wiring layer formed on the fifth insulating layer  60 . The sixth wiring layer  61  has via-wirings  61   a  packed in via-holes VH 5  which are formed through the fifth insulating layer  60  to expose the upper surface of the fifth wiring layer  51 , and wiring patterns  61   b  formed on the fifth insulating layer  60 . The via-wirings  61   a  are electrically connected to the fifth wiring layer  51  exposed in the bottoms of the via-holes VH 5 . Incidentally, each of the via-holes VH 5  and the via-wirings  61   a  is tapered to have a shape having its diameter increasing as the position goes from the lower side to the upper side in  FIG. 1 . For example, the thickness of the wiring patterns  61   b  of the sixth wiring layer  61  can be set to be in a range of about 20 μm to about 35 μm. 
     A solder resist layer  62  is formed on the outermost fifth insulating layer  60  on a side (upper side in  FIG. 1 ) opposite to the surface where the electrode pads  11 P are formed. For example, an epoxy-based insulating resin can be used as the material of the solder resist layer  62 . For example, the thickness of the solder resist layer  62  can be set to be in a range of about 15 μm to about 35 μm. 
     Opening portions  62 X for exposing parts of the wiring patterns  61   b  of the sixth wiring layer  61  as external connection pads  61 P are formed in the solder resist layer  62 . The external connection pads  61 P are configured so that external connection terminals such as solder balls, lead pins, etc. which are used when the wiring board  1  is mounted in a mother board or the like can be connected to the external connection pads  61 P. That is, in this embodiment, the surface where the external connection pads  61 P are formed serves as an external connection terminal surface. Incidentally, if necessary, a metal layer may be formed on each of the wiring patterns  61   b  exposed out of the opening portions  62 X so that each of the external connection terminals can be connected to the metal layer. An Au layer, an Ni/Au layer (a metal layer formed in such a manner that an Ni layer and an Au layer are formed in this order), an Ni/Pd/Au layer (a metal layer formed in such a manner that an Ni layer, a Pd layer and an Au layer are formed in this order), etc. can be listed as examples of the metal layer. Alternatively, the wiring patterns  61   b  exposed out of the opening portions  62 X (or a metal layer when the metal layer is formed on the wiring patterns  61   b ) may be directly used as external connection terminals. 
     The planer shape of each of the opening portions  62 X (external connection pads  61 P) of the solder resist layer  62  is, for example, circular. For example, the diameter of each circle can be set to be in a range of about 200 μm to about 1000 μm. For example, the pitch of the external connection pads  61 P can be set to be in a range of about 500 μm to about 1200 μm. 
     Structure of Semiconductor Package According to First Embodiment 
     The structure of a semiconductor package  2  using the wiring board  1  will be described below in accordance with  FIG. 2 . Incidentally, the wiring board  1  in  FIG. 2  is drawn to be upside down, compared with that in  FIG. 1 . 
     As shown in  FIG. 2 , the semiconductor package  2  has a wiring board  1 , a semiconductor chip  70  connected to the wiring board  1  by flip chip bonding, and an underfill resin  72 . Solder  14  is formed on the electrode pads  11 P of the wiring board  1 . For example, eutectic solder or lead (Pb)-free solder (Sn—Ag-based, Sn—Cu-based, Sn—Ag—Cu-based, etc) can be used as the solder  14 . 
     The semiconductor chip  70  has a circuit-forming surface (lower surface in  FIG. 2 ) where bumps  71  are formed. The semiconductor chip  70  is electrically connected to the electrode pads  11 P of the wiring board  1  through the bumps  71  and the solder  14 . 
     The underfill resin  72  is provided so that a gap between the wiring board  1  and the semiconductor chip  70  is filled with the underfill resin  72 . The underfill resin  72  is a resin for improving connection strength of connection portions between the bumps  71  and the electrode pads  11 P and for suppressing occurrence of corrosion or electromigration of the electrode pads  11 P to prevent reliability of the electrode pads  11 P from being lowered. For example, an epoxy-based insulating resin can be used as the material of the underfill resin  72 . 
     (Operation) 
     In the wiring board  1 , the insulating layer  40 A improved in mechanical strength by addition of a reinforcing material compared with the insulating layers  20 ,  30 ,  50  and  60  is provided so as to be located near the center in the direction of lamination of the wiring board  1  formed by lamination. As a result, the insulating layers  20  and  30  and the wiring layers  11 ,  21  and  31  provided under the reinforcing material-containing insulating layer  40 A as the center are disposed so as to be substantially symmetrical with the insulating layers  50  and  60  and the wiring layers  42 ,  51  and  61  provided above the reinforcing material-containing insulating layer  40 A as the center. Accordingly, vertical balance of the wiring board  1  with respect to the insulating layer  40 A as the center becomes so good that occurrence of warping in the wiring board  1  can be suppressed. 
     Moreover, in the wiring board  1 , the contact layer  41 A is formed on the reinforcing material-containing insulating layer  40 A, and the wiring patterns  42   b  are formed on the contact layer  41 A. Here, the contact layer  41 A is an insulating layer which has a low roughness surface as its upper surface (a surface where the wiring patterns  42   b  are formed) and which is higher in adhesion to a metal film (electroless plating) than the insulating layer  40 A. For this reason, the wiring patterns  42   b  formed on the low roughness surface of the contact layer  41 A can be provided as fine patterns. 
     Method of Manufacturing Wiring Board According to First Embodiment 
     A method of manufacturing the wiring board  1  will be described below. 
     First, for production of the wiring board  1 , a support board  80  is prepared as shown in  FIG. 3A . For example, a metal plate or metal foil can be used as the support board  80 . In this embodiment, for example, copper foil is used as the support board  80 . For example, the thickness of the support board  80  is in a range of 35 μm to 100 μm. 
     Then, in the step shown in  FIG. 3B , a resist layer  81  having opening portions  81 X is formed on one surface (upper surface in the drawing) of the support board  80 . The opening portions  81 X are formed so that portions of the upper surface of the support board  80  corresponding to regions where the first wiring layer  11  (see  FIG. 1 ) will be formed are exposed. A photosensitive dry film or a liquid photo-resist (e.g. a liquid resist made of a novolac-based resin, an epoxy-based resin, or the like) or the like can be used as the material of the resist layer  81 . For example, when a photosensitive dry film is used, the dry film is formed on the upper surface of the support board  80  by thermo-compression bonding and patterned by exposure and development to thereby form the resist layer  81  having opening portions  81 X of predetermined patterns corresponding to the regions where the first wiring layer  11  will be formed. Incidentally, when a liquid photo-resist is used, the resist layer  81  can be also formed through the same step. 
     Successively, in the step shown in  FIG. 3C , electrolytic plating using the support board  80  as a plating power feeding layer is applied to the upper surface of the support board  80  while the resist layer  81  is used as a plating mask. Specifically, by applying an electrolytic plating method to the upper surface of the support board  80  exposed out of the opening portions  81 X of the resist layer  81 , the first conductive layer  12  and the second conductive layer  13  are formed successively in the opening portions  81 X to form the first wiring layer  11 . For example, when the first conductive layer  12  has a structure in which an Au film, a Pd film and an Ni film are formed successively in this order, and the second conductive layer  13  is a Cu layer, the first conductive layer  12  is first formed in such a manner that the Au film, the Pd film and the Ni film are formed successively by an electrolytic plating method using the support board  80  as a plating power feeding layer. The second conductive layer  13  is then formed in such a manner that the Cu layer is formed on the first conductive layer  12  by an electrolytic plating method using the support board  80  as a plating power feeding layer. 
     Then, in the step (insulating layer forming step) shown in  FIG. 3D , the resist layer  81  shown in  FIG. 3C  is removed and the first insulating layer  20  is formed on the upper surface of the support board  80  so that the first wiring layer  11  is covered with the first insulating layer  20 . Incidentally, for example, the first insulating layer  20  can be formed in such a manner that a resin film is formed on the support board  80  and then the resin film is heated at a temperature of about 130 to 150° C. while pressed so as to be hardened. 
     Successively, in the step shown in  FIG. 3E , the via-holes VH 1  are formed in predetermined places of the first insulating layer  20  so that the upper surface of the first wiring layer  11  is exposed. For example, the via-holes VH 1  can be formed by a laser machining method using a carbon dioxide laser, a UV-YAG laser or the like. Incidentally, for example, when the first insulating layer  20  is made of a photosensitive resin, the required via-holes VH 1  may be formed by photolithography. 
     When the via-holes VH 1  are formed by a laser machining method, desmear processing is then performed to remove a resin residue (resin smear) of the first insulating layer  20  deposited on the upper surface of the first wiring layer  11  exposed in the bottoms of the via-holes VH 1 . 
     Then, in the step (wiring layer forming step) shown in  FIG. 4A , the via-holes VH 1  of the first insulating layer  20  are filled with a via-conductor so that via-wirings  21   a  are formed and wiring patterns  21   b  electrically connected to the first wiring layer  11  through the via-wirings  21   a  are formed on the first insulating layer  20 . These via-wirings  21   a  and wiring patterns  21   b , that is, the second wiring layer  21  can be formed by one of various wiring forming methods such as a semi-additive method, a subtractive method, etc. 
     Then, in the step shown in  FIG. 4B , the steps shown in  FIGS. 3D to 4A  are repeated to laminate the second insulating layer  30  and the third wiring layer  31 . That is, as shown in  FIG. 4B , the second insulating layer  30  is formed on the first insulating layer  20  and the second wiring layer  21 , and the via-holes VH 2  reaching the upper surfaces of the wiring patterns  21   b  are formed in the second insulating layer  30 . Then, via-wirings  31   a  are formed in the via-holes VH 2 , and wiring patterns  31   b  electrically connected to the via-wirings  31   a  are formed. 
     Successively, in the step shown in  FIG. 4C , an insulating layer  40 B serving as an insulating layer  40 A (see  FIG. 1 ) is prepared, that is, a reinforcing material-containing insulating layer  40 B made of woven or unwoven fabric of glass, aramid or LCP (Liquid Crystal Polymer) fiber impregnated with an unhardened thermosetting resin is prepared. A B-stage (semi-hardened state) layer is used as the insulating layer  40 B. For example, the thickness of the insulating layer  40 B can be set to be in a range of 30 μm to 80 μm. 
     In the step shown in  FIG. 4C , a structure  82 A in which an insulating layer  41 B serving as a contact layer  41 A (see  FIG. 1 ) is bonded to a carrier  82  is prepared. An insulating resin containing 30 vol % or more of an unhardened epoxy resin, and 1 to 50 vol % of an inorganic filler can be used as the material of the insulating layer  41 B. A semi-hardened state layer is used as the insulating layer  41 B. For example, the thickness of the insulating layer  41 B can be set to be in a range of about 1 μm to about 4 μm. For example, copper foil can be used as the carrier  82  for carrying the insulating layer  41 B. For example, the thickness of the carrier  82  can be set to be in a range of about 2 μm to about 18 μm. 
     In the step (first process) shown in  FIG. 4C , the insulating layer  40 B and the structure  82 A are disposed sequentially from bottom on the upper surface side of the structure shown in  FIG. 4B . On this occasion, the structure  82 A is disposed in a state where the insulating layer  41 B faces downward so that the insulating layer  41 B faces the insulating layer  40 B. Then, the structure shown in  FIG. 4B , the insulating layer  40 B and the structure  82 A are pressed while heated at a temperature of about 190° C. to about 250° C. in a vacuum atmosphere from both sides. Consequently, as shown in  FIG. 5A , the insulating layers  40 B and  41 B are hardened so that the insulating layer  40 A and the contact layer  41 A are formed on the second insulating layer  30  and the third wiring layer  31 . Moreover, as the insulating layers  40 B and  41 B are hardened, the second insulating layer  30  and the third wiring layer  31  are bonded to the insulating layer  40 A while the insulating layer  40 A is bonded to the contact layer  41 A. Consequently, the third insulating layer  40  in which the insulating layer  40 A and the contact layer  41 A are formed in this order is formed on the second insulating layer  30  and the third wiring layer  31 . Incidentally, for example, when the thickness of the insulating layer  40 B before lamination is 60 μm and the thickness of the wiring patterns  31   b  is 35 μm, the thickness of the insulating layer  40 A after lamination is about 40 μm. 
     Successively, in the step shown in  FIG. 5B , the carrier  82  (copper foil) shown in  FIG. 5A  is selectively removed from the contact layer  41 A. For example, wet etching using an aqueous solution of ferric chloride, an aqueous solution of cupric chloride, an aqueous solution of ammonium persulfate or the like can be used for selectively removing the carrier  82  (copper foil) from the contact layer  41 A. 
     Then, in the step shown in  FIG. 5C , via-holes VH 3  are formed in predetermined places of the insulating layer  40 A and the contact layer  41 A so that the upper surfaces of the wiring patterns  31   b  of the third wiring layer  31  are exposed. For example, the via-holes VH 3  can be formed by a laser machining method using a carbon dioxide laser, a UV-YAG laser or the like. Incidentally, the via-holes VH 3  formed by a laser machining method are provided as concave portions each shaped like a frustum of a circular cone which has an opening portion on a side where the fourth insulating layer  50  (see  FIG. 1 ) will be formed, and a bottom formed by the upper surface of the third wiring layer  31  so that the area of the opening portion is larger than the area of the bottom. 
     When the via-holes VH 3  are formed by a laser machining method, desmear processing is then performed to remove a resin residue of the insulating layer  40 A and the contact layer  41 A deposited on the upper surface of the third wiring layer  31  exposed in the bottoms of the via-holes VH 3 . For example, this desmear processing can be performed by a permanganate method or the like. In this desmear processing, a desmear liquid (etchant) is also fed to the surface of the contact layer  41 A, so that the surface of the contact layer  41 A is etched with the desmear liquid, and the surface of the contact layer  41 A is roughened. However, on this occasion, the contact layer  41 A is less subject to the desmear processing, that is, the contact layer  41 A is excellent in desmear resistance because the thermosetting resin (epoxy-based resin in the contact layer  41 A) content is high to be not lower than 30 vol % and the inorganic filler content is relatively low to be in the range of 1-50 vol %, compared with the insulating layer  40 A. For this reason, the contact layer  41 A is hardly etched with the desmear liquid so that the surface of the contact layer  41 A is kept as low roughness after the desmear processing. Specifically, the roughness of the surface of the contact layer  41 A after the desmear processing is kept at a low value of about 50-350 nm in terms of surface roughness Ra value. In other words, the composition (e.g. epoxy-based resin content and inorganic filler content) of the contact layer  41 A is adjusted to obtain such desmear resistance that the roughness of the surface of the contact layer  41 A after the desmear processing can be kept at a low value of about 50-350 nm in terms of surface roughness Ra value even when the desmear processing is performed. 
     Then, in the step shown in  FIG. 6A , a seed layer  83  of copper or the like is formed on the upper surfaces of the wiring patterns  31   b  exposed in the bottoms of the via-holes VH 3 , the inner wall surfaces of the via holes VH 3  and the upper surface of the contact layer  41 A. For example, the seed layer  83  is formed by an electroless copper plating method or a sputtering method. On this occasion, the inorganic filler content of the contact layer  41 A causing lowering of adhesion to the seed layer  83  (e.g. electroless copper plating) is so relatively low that the seed layer  83  adheres to the contact layer  41 A well. Specifically, the inorganic filler content of the contact layer  41 A is equal to or lower than the inorganic filler content of an interlayer insulating layer (the first insulating layer  20  or the like) containing no reinforcing material. For this reason, the adhesion strength between the contact layer  41 A and the seed layer  83  is equal to or higher than the adhesion strength between the first insulating layer  20  and the seed layer. Moreover, because the roughness of the upper surface of the contact layer  41 A is low as described above, the fourth wiring layer  42  formed on the contact layer  41 A can be provided as a fine line structure. 
     Successively, in the step shown in  FIG. 6B , a dry film resist (DFR) or the like having opening portions  84 X corresponding to the patterns of the fourth wiring layer  42  is used for forming a resist layer  84  on the seed layer  83 . For example, this resist layer  84  is formed by photolithography. 
     Then, in the step shown in  FIG. 6C , the opening portions  84 X of the resist layer  84  containing the via-holes VH 3  are filled with a metal plating layer  42 C of copper or the like by an electrolytic plating method using the seed layer  83  as a power feeding layer. In the via-holes VH 3 , plating is performed on the inside from the seed layer  83 , so that the via-holes VH 3  are filled with a via-conductor  42 D. Consequently, via-wirings  42   a  constituted by the seed layer  83  and the via-conductor  42 D are formed, and wiring patterns  42   b  constituted by the seed layer  83  and the metal plating layer  42 C are formed. On this occasion, the wiring patterns  42   b  are formed on the contact layer  41 A of the low roughness surface as described above, so that the wiring patterns  42   b  can be provided as a fine line structure. 
     Then, in the step shown in  FIG. 7A , the resist layer  84  shown in  FIG. 6C  is removed and then the unnecessary seed layer  83  is removed by etching while the metal plating layer  42 C and the via-conductor  42 D are used as a mask. By the steps (second process) shown in  FIGS. 6A to 7A , the fourth wiring layer  42  having the via-wirings  42   a  and the wiring patterns  42   b  is formed on the insulating layer  40 A and the contact layer  41 A. That is, the fourth wiring layer  42  is formed by a semi-additive method. 
     Then, in the step shown in  FIG. 7B , the steps shown in  FIGS. 3D to 4A  are repeated again to laminate insulating layers and wiring layers alternately. That is, as shown in  FIG. 7B , a fourth insulating layer  50  is formed on the contact layer  41 A and the fourth wiring layer  42 , and via-holes VH 4  reaching the upper surface of the fourth wiring layer  42  are formed in the fourth insulating layer  50 . Then, via-wirings  51   a  are formed in the via-holes VH 4 , and wiring patterns  51   b  electrically connected to the via-wirings  51   a  are formed to thereby provide a fifth wiring layer  51 . Then, a fifth insulating layer  60  is formed on the fourth insulating layer  50  and the fifth wiring layer  51 , and via-holes VH 5  reaching the upper surfaces of the wiring patterns  51   b  are formed in the fifth insulating layer  60 . Then, via-wirings  61   a  are formed in the via-holes VH 5 , and wiring patterns  61   b  electrically connected to the via-wirings  61   a  are formed to thereby provide a sixth wiring layer  61 . 
     Then, in the step shown in  FIG. 7B , a solder resist layer  62  having opening portions  62 X for exposing external connection pads  61 P set in required places of the sixth wiring layer  61  is formed on the fifth insulating layer  60  and the sixth wiring layer  61 . For example, this solder resist layer  62  can be formed in such a manner that a photosensitive solder resist film is formed or a liquid solder resist is applied so that the resist is patterned into a required shape. Consequently, parts of the sixth wiring layer  61  are exposed as external connection pads  61 P out of the opening portions  62 X of the solder resist layer  62 . Incidentally, if necessary, a metal layer, for example, obtained by laminating an Ni layer and an Au layer in this order may be formed on the external connection pads  61 P. For example, this metal layer can be formed by an electroless plating method. 
     Then, in the step shown in  FIG. 8A , the support board  80  (see  FIG. 7B ) used as a temporary board is removed. For example, when copper foil is used as the support board  80 , the support board  80  can be removed by wet etching using an aqueous solution of ferric chloride, an aqueous solution of cupric chloride, an aqueous solution of ammonium persulfate or the like. On this occasion, the outermost layer of the first wiring layer  11  exposed out of the first insulating layer  20  is an Au film or the like, so that only the support board  80  provided as copper foil can be etched selectively. However, when the sixth wiring layer  61  is a copper layer, it is necessary to perform the aforementioned wet etching while using the sixth wiring layer  61  as a mask in order to prevent the sixth wiring layer  61  exposed in the bottoms of the opening portions  62 X from being etched together with the support board  80 . 
     By the aforementioned producing process, the wiring board  1  according to this embodiment can be produced. 
     Method of Manufacturing Semiconductor Package According to First Embodiment 
     A method of manufacturing a semiconductor package  2  using the wiring board  1  produced as described above will be described below. 
     First, in the step shown in  FIG. 8B , solder  14  is formed on the electrode pads  11 P of the wiring board  1 . For example, the solder  14  can be formed by applying solder paste or mounting solder balls. Successively, in the step shown in  FIG. 9A , a semiconductor chip  70  having terminals on which bumps  71  are formed is positioned on the electrode pads  11 P, and the solder  14  and the bumps  71  are melted so that the semiconductor chip  70  is electrically connected to the electrode pads  11 P (flip chip bonding). In the step shown in  FIG. 9B , a gap between the semiconductor chip  70  and the first insulating layer  20  of the wiring board  1  is filled with a liquid underfill resin  72 , and the liquid underfill resin  72  is hardened. By the aforementioned manufacturing steps, the semiconductor package  2  according to this embodiment can be manufactured. 
     According to the embodiment as described above, the following effects can be obtained. 
     (1) In the configuration of the wiring board  1 , the contact layer  41 A is formed on the reinforcing material-containing insulating layer  40 A and the wiring patterns  42   b  are formed on the contact layer  41 A. Here, the contact layer  41 A is an insulating layer which has an upper surface (a surface where the wiring patterns  42   b  are formed) provided as a low roughness surface and which is higher in adhesion to a metal film (electroless plating) than the insulating layer  40 A. For this reason, the wiring patterns  42   b  formed on the low roughness surface of the contact layer  41 A can be provided as fine patterns. Specifically, the wiring patterns  42   b  can be formed finely up to about L/S=8 μm/8 μm. 
     (2) The wiring patterns  42   b  are formed on the contact layer  41 A which is more excellent in desmear resistance than the reinforcing material-containing insulating layer  40 A. Here, the surface roughness of the upper surface of the contact layer  41 A after desmear processing is kept at a low value of 50 to 350 nm in terms of surface roughness Ra value. For this reason, when the wiring patterns  42   b  are formed on such an upper surface (low roughness surface) of the contact layer  41 A, a semi-additive method can be used for forming fine wiring. 
     (3) In the producing method according to this embodiment, the wiring layers  11 ,  21  and  31  and the insulating layers  20  and  30  are supported by the support board  80  when the wiring layers  11 ,  21  and  31  and the insulating layers  20  and  30  are formed. Accordingly, occurrence of warping can be suppressed favorably. Moreover, because the wiring layers  11 ,  21  and  31  and the insulating layers  20  and  30  are formed while supported by the support board  80  having high rigidity, the problem of thin board conveyance which may occur at the time of production of the wiring board can be prevented from occurring. 
     After the second insulating layer  30  and the third wiring layer  31  are formed, the third insulating layer  40  containing the insulating layer  40 A high in mechanical strength is formed by lamination. The wiring layers  42 ,  51  and  61  and the insulating layers  50  and  60  are formed on the third insulating layer  40  containing the insulating layer  40 A high in mechanical strength. For this reason, the wiring layers  42 ,  51  and  61  and the insulating layers  50  and  60  are supported by the third insulating layer  40  and the support board  80 , so that occurrence of warping can be suppressed favorably even when the wiring layers  42 ,  51  and  61  and the insulating layers  50  and  60  are formed. 
     (4) Because the wiring board  1  can be produced without largely altering the multilayer wiring board producing process heretofore performed, reduction in equipment cost can be attained. Thus, reduction in production cost of the wiring board  1  can be attained. 
     (5) In the wiring board  1 , the insulating layer  40 A more improved in mechanical strength than the insulating layers  20 ,  30 ,  50  and  60  by addition of a reinforcing material is provided so as to be located near the center in the direction of lamination of the wiring board  1  formed by lamination. Consequently, the insulating layers  20  and  30  and the wiring layers  11 ,  21  and  31  provided in the lower portion with respect to the reinforcing material-containing insulating layer  40 A provided as the center are disposed so as to be substantially symmetrical with the insulating layers  50  and  60  and the wiring layers  42 ,  51  and  61  provided in the upper portion with respect to the reinforcing material-containing insulating layer  40 A provided as the center. Accordingly, vertical balance with respect to the insulating layer  40 A of the wiring board  1  as the center becomes so good that occurrence of warping in the wiring board  1  can be suppressed. Incidentally, when warping occurs in the wiring board  1  because of a difference in thermal expansion coefficient between an insulating layer made of a resin and a wiring layer made of a metal, the semiconductor chip  70  cannot be mounted on the wiring board  1  appropriately so that mounting reliability is lowered. On the contrary, according to this embodiment, occurrence of warping can be suppressed as described above. Accordingly, the semiconductor chip  70  can be mounted on the wiring board  1  appropriately so that mounting reliability can be improved. 
     Incidentally, the first embodiment can be carried out in the following forms which have been changed properly. 
     Modifications of First Embodiment 
     In the first embodiment, the insulating layer  40  having the reinforcing material-containing insulating layer  40 A and the contact layer  41 A having low roughness and improved in adhesion to electroless plating is provided near the center in the direction of lamination. The invention is not limited thereto as long as at least one of interlayer insulating layers formed in the wiring board is the insulating layer  40  having the insulating layer  40 A and the contact layer  41 A. Accordingly, the position where the insulating layer  40  is formed and the number of such insulating layers  40  are not particularly limited. 
     For example, as shown in  FIG. 10A , a plurality of insulating layers  40  (two in this modification) each having a reinforcing material-containing insulating layer  40 A and a contact layer  41 A may be provided near the center in the direction of lamination. That is, a wiring board  1 A having the two insulating layers  40  is configured so that an insulating layer  40  (upper insulating layer  40 ) and a wiring layer  43  formed on the insulating layer  40  are added to the wiring board  1  shown in  FIG. 1 . The wiring layer  43  has via-wirings  43   a  packed in via-holes VH 6  which are formed through the reinforcing material-containing insulating layer  40 A and the contact layer  41 A to expose the upper surface of the wiring layer  42 , and wiring patterns  43   b  formed on the contact layer  41 A. By this structure, the rigidity of the wiring board  1 A can be more improved in the vicinity of the center in the direction of lamination. Consequently, the reinforcing effect based on the insulating layers  40  can be improved so that warping of the wiring board  1 A can be reduced effectively. In other words, the plurality of insulating layers  40  exhibit the same effect as in a core board (support member) having high rigidity. 
     In a wiring board configured so that a build-up wiring layer and an insulating layer are formed on each of upper and lower surfaces of a core board, it is necessary to form through-holes in the core board. There is however a problem that increases in total density of the wiring board cannot be attained because it is difficult to form the through-holes finely. Moreover, there is another problem that it is difficult to form through-hole plating voidlessly when plating is applied to the through-holes. 
     On the contrary, in accordance with the structure shown in  FIG. 10A , the wiring layers  42  and  43  formed on the plurality of insulating layers  40  are interlayer-connected through via-wirings  42   a  and  43   a  packed in the via-holes VH 3  and VH 6  formed in the insulating layers  40  respectively. It is easy to form such via-wirings  42   a  and  43   a  finely and voidlessly. For this reason, increase in total density of the wiring board can be achieved so that reliability of interlayer connection of the wiring layers can be improved. 
     For example, as shown in  FIG. 10B , the interlayer insulating layer which is the outermost layer on the external connection terminal surface side may be replaced by an insulating layer  40  having a reinforcing material-containing insulating layer  40 A and a contact layer  41 A. That is, in a wiring board  1 B, the fifth insulating layer  60  in the wiring board  1  in  FIG. 1  is replaced by an insulating layer  40 , and the insulating layer  40  in the wiring board  1  is replaced by an insulating layer  44  containing no reinforcing material. In the wiring board  1 B, a wiring layer  63  formed on the insulating layer  40  has via-wirings  63   a  packed in via-holes VH 7  which are formed through the reinforcing material-containing insulating layer  40 A and the contact layer  41 A to expose the upper surface of the wiring layer  51 , and wiring patterns  63   b  formed on the contact layer  41 A. Incidentally, the wiring layer  63  exposed out of the opening portions  62 X of the solder resist layer  62  serves as external connection pads  63 P. In this manner, the insulating layer  40  having the reinforcing material-containing insulating layer  40 A and the contact layer  41 A may be provided so as to be biased toward the external connection terminal surface side. Though not shown, the insulating layer  40  having the reinforcing material-containing insulating layer  40 A and the contact layer  41 A may be provided so as to be biased toward the chip mounting surface side. 
     For example, as shown in  FIG. 11 , all interlayer insulating layers may be replaced by insulating layers  40  each having a reinforcing material-containing insulating layer  40 A and a contact layer  41 A. That is, in a wiring board  1 C, all the insulating layers  20 ,  30 ,  50  and  60  in the wiring board  1  shown in  FIG. 1  are replaced by the insulating layers  40 . In this case, warping of the wiring board  1 C can be reduced effectively. For example, when there is the possibility that warping of the wiring board  1 C will become intensive in consideration of stress of materials, etc. used in the wiring board  1 C, the number of built-up layers, the thickness of each layer, etc., it is preferable that all the interlayer insulating layers are replaced by the insulating layers  40  each having the reinforcing material-containing insulating layer  40 A and the contact layer  41 A as described in this modification. 
     As described above, in the wiring board  1  according to the first embodiment, any one of the interlayer insulating layers to be formed may be replaced by the insulating layer  40  having the insulating layer  40 A and the contact layer  41 A. In other words, in accordance with the method of manufacturing the wiring board  1  according to the first embodiment, any insulating layer can be replaced by the insulating layer  40 . That is, any insulating layer can be replaced by the insulating layer  40  suitably in accordance with characteristic (the number of built-up layers, the thickness of each layer, the area occupied by each wiring layer, etc.) of the wiring board. 
     EXAMPLES 
     The first embodiment and its modifications will be described below more specifically in connection with examples and comparative examples. 
     Here is described a result of verification as to whether a contact layer  41 A exerts a bad influence on improvement in warping of the wiring board or not, when the contact layer  41 A is added. That is, the inorganic filler content of the contact layer  41 A is so relatively small that the thermal expansion coefficient of the contact layer  41 A becomes higher (e.g. about 40-100 ppm/° C.) than those of the other insulating layers  20 ,  30 ,  40 A, etc. The thermal expansion coefficient of the contact layer  41 A is largely different from the thermal expansion coefficient (e.g. about 17 ppm/° C.) of a wiring layer (copper). For this reason, there is the possibility that warping may occur in the wiring board  1  because of the difference between the thermal expansion coefficients. That is, warping of the wiring board is improved by addition of the reinforcing material-containing insulating layer  40 A and the fine structure of wiring patterns is achieved by formation of the contact layer  41 A but there is the possibility that addition of the contact layer  41 A will exert a bad influence on improvement in warping due to the insulating layer  40 A. Therefore, as shown in  FIGS. 12A and 13 , simulation of warping is applied on each of wiring boards (Examples 1 to 3) in which at least one insulating layer  40  having an insulating layer  40 A and a contact layer  41 A is provided, wiring boards (Comparative Examples 1 to 3) in which only an insulating layer  40 A is provided in place of each insulating layer  40  and a wiring board (Comparative Example 4) in which the insulating layer  40 A and the contact layer  41 A are not provided. 
     Example 1 
     As shown in  FIG. 12A , the wiring board according to Example 1 is formed in such a manner that seven wiring layers C 1  to C 7  and six insulating layers A 1  to A 6  are formed alternately and a solder resist layer SR is formed on the lowermost insulating layer A 6 . The wiring board is formed by successively laminating the chip mounting surface side wiring layers C 1  to C 7  and insulating layers A 1  to A 6  on the support board in the same manner as in the method of manufacturing the wiring board  1  according to the first embodiment. Here, the insulating layer A 4  is an insulating layer  40  which is a laminate of a reinforcing material-containing insulating layer  40 A and a contact layer  41 A, and the other insulating layers A 1  to A 3 , A 5  and A 6  are insulating layers containing no reinforcing material. 
     As a condition for simulation, the thermal expansion coefficient and Young&#39;s modulus of the insulating layer  40 A are adjusted to 16.5 ppm/° C. and about 30000 MPa respectively and the thermal expansion coefficient and Young&#39;s modulus of the contact layer  41 A are adjusted to 70-90 ppm/° C. and about 2000 MPa respectively to thereby adjust the thermal expansion coefficient and Young&#39;s modulus of the insulating layer  40  to 17.0 ppm/° C. and about 29000 MPa respectively. On the other hand, the thermal expansion coefficient and Young&#39;s modulus of the insulating layer containing no reinforcing material are adjusted to 39 ppm/° C. and about 5000 MPa respectively, and the thermal expansion coefficient and Young&#39;s modulus of the solder resist layer SR are adjusted to 40 ppm/° C. and about 3800 MPa respectively. 
     The planer shape of the wiring board is provided as a rectangular shape of 45 mm×45 mm. Specifically, as shown in  FIG. 12B , the layer thicknesses of the wiring layers C 1  to C 7  are set to be 15 μm, the layer thickness of the insulating layer A 1  is set to be 15 μm, the layer thicknesses of the insulating layers A 2 , A 3 , A 5  and A 6  containing no reinforcing material are set to be 30 μm, the layer thickness of the reinforcing material-containing wiring layer A 4  is set to be 40 μm, and the layer thickness of the solder resist layer SR is set to be 15 μm. Here, the layer thickness (40 μm) of the insulating layer A 4  which is the insulating layer  40  is the sum of the thickness (38 μm) of the insulating layer  40 A and the thickness (2 μm) of the contact layer  41 A. The Cu areas of the wiring layers C 1  to C 7  are adjusted so that the remaining copper ratios of the wiring layers C 1  to C 7  are 1.5%, 66.8%, 88.6%, 62.3%, 82.5%, 76.1% and 82.2% respectively. Here, the remaining copper ratio is a ratio of the area of a copper layer for forming a wiring layer to the area on an insulating layer. 
     Incidentally, the aforementioned simulation condition is also applied to other Examples 2 and 3 and Comparative Examples 1 to 4. 
     Example 2 
     As shown in  FIG. 13A , the wiring board according to Example 2 is formed so that the insulating layers A 3  and A 5  are provided as the insulating layers  40  in addition to the insulating layer A 4  provided as the insulating layer  40 . 
     Example 3 
     As shown in  FIG. 13B , the wiring board according to Example 3 is formed so that all the insulating layers A 1  to A 6  are provided as the insulating layers  40 . 
     Comparative Example 1 
     As shown in  FIG. 13C , the wiring board according to Comparative Example 1 is formed so that the contact layer  41 A is removed from the insulating layer A 4  of the wiring board according to Example 1 and the insulating layer  40  of the wiring board according to Example 1 is replaced by the reinforcing material-containing insulating layer  40 A singly. 
     Comparative Example 2 
     As shown in  FIG. 13D , the wiring board according to Comparative Example 2 is formed so that the contact layers  41 A are removed from the insulating layers A 3  to A 5  of the wiring board according to Example 2 and the insulating layers  40  of the wiring board according to Example 2 are replaced by the reinforcing material-containing insulating layers  40 A singly and respectively. 
     Comparative Example 3 
     As shown in  FIG. 13E , the wiring board according to Comparative Example 3 is formed so that the contact layers  41 A are removed from the insulating layers A 1  to A 6  of the wiring board according to Example 3 and the insulating layers  40  of the wiring board according to Example 3 are replaced by the reinforcing material-containing insulating layers  40 A singly and respectively. 
     Comparative Example 4 
     As shown in  FIG. 13F , the wiring board according to Comparative Example 4 is formed so that all the insulating layers A 1  to A 6  are provided as insulating layers containing no reinforcing material. In this case, the thickness of the insulating layer A 1  is set to be 15 μm, and the thicknesses of the other insulating layers A 2  to A 6  are set to be 30 μm. 
     (Measuring Method) 
     Warping is measured when the temperature is reduced to 25 degrees after stress is released in the condition that the wiring board according to each example is put under an environment of 190 degrees. As shown in  FIG. 12C , warping is measured as a difference in height between respective end portions in a half diagonal length of the wiring board, that is, between a board center portion B 1  and a corner portion B 2 . Incidentally, simulation results are shown in Table 1 while the amount of warping in the case where the chip mounting surface is convexly warped is regarded as plus and the amount of warping in the case where the chip mounting surface is concavely warped is regarded as minus. 
                                                       TABLE 1                       Position of   Position of   Amount of           Insulating   Insulating   Warping           Layer 40   Layer 40A   [μm]                                    Example 1   A4   —   −643       Example 2   A3 to A5   —   −561       Example 3   A1 to A6   —   −89       Comparative Example 1   —   A4   −640       Comparative Example 2   —   A3 to A5   −552       Comparative Example 3   —   A1 to A6   −36       Comparative Example 4   None   None   −671                    
(Simulation Results)
 
     As shown in Table 1, first, in the wiring board according to Comparative Example 4 in which all the insulating layers A 1  to A 6  are insulating layers containing no reinforcing material, the amount of warping is −671 μm. On the contrary, in the wiring boards according to Examples 1 to 3 in which at least one of the insulating layers A 1  to A 6  is provided as the insulating layer  40  (composed of a reinforcing material-containing insulating layer  40 A and a contact layer  41 A), the amounts of warping are −643 μm, −561 μm and −89 μm, respectively. It is found that the amount of warping in each of Examples 1 to 3 is smaller than the amount of warping in Comparative Example 4. As described above, there is the possibility that the provision of the contact layer  41 A having a high thermal expansion coefficient will exert a bad influence on the warping improvement effect. It is however obvious from the simulation results that warping of the wiring board can be improved sufficiently even when the contact layer  41 A is provided. In comparison between Example 1 and Comparative Example 1 and between Example 2 and Comparative Example 2, the amounts of warping in Examples 1 and 2 are substantially equal to the amounts of warping in the case where there is no contact layer  41 A (Comparative Examples 1 and 2). From this fact, it is found that the contact layer  41 A does not exert a bad influence on improvement in warping of the wiring board due to the insulating layer  40 A even when the contact layer  41 A having a thermal expansion coefficient largely different from the thermal expansion coefficient of the wiring layer is added. This reason is considered. In Examples 1 and 2, the thickness of the contact layer  41 A is adjusted to about 5.3% of the thickness of the insulating layer  40 A, and the Young&#39;s modulus of the contact layer  41 A is adjusted to about 6.7% of the Young&#39;s modulus of the insulating layer  40 A. In this manner, the contact layer  41 A is sufficiently thinner than the insulating layer  40 A and the Young&#39;s modulus of the contact layer  41 A is smaller than that of the insulating layer  40 A. Accordingly, it is thought of that a function of weakening the warping improvement effect due to the reinforcing material-containing insulating layer  40 A is so small that the contact layer  41 A does not exert a bad influence on the warping improvement. 
     In Example 3 in which all the insulating layers A 1  to A 6  are provided as the insulating layers  40  (each composed of a reinforcing material-containing insulating layer  40 A and a contact layer  41 A), it is found that a high warping improvement effect is obtained because the amount of warping is −89 μm. However, in comparison between Example 3 and Comparative Example 3, the absolute value of the amount of warping in Example 3 is 50 μm or more larger than that in Comparative Example 3. It is thought of that this is because the influence of the thermal expansion coefficient (or Young&#39;s modulus) of the contact layer  41  on the amount of warping increases as the absolute value of the amount of warping decreases. In accordance with this, it is thought of that the difference in the amount of warping increases in accordance with the presence/absence of the contact layer  41 A. However, the difference in the amount of warping is a difference generated when the absolute value of the amount of warping becomes sufficiently small. Accordingly, as is obvious from the simulation results, it can be said that the warping improvement effect due to the insulating layer  40  having the contact layer  41 A is obtained sufficiently even when the difference in the amount of warping between Example 3 and Comparative Example 3 increases. 
     Second Embodiment 
     A second embodiment will be described below with reference to  FIGS. 14 ,  15 A- 15 C and  16 A- 16 C. 
     The first embodiment has been described about a wiring board formed by alternately laminating wiring layers and insulating layers from the chip mounting surface side. On the contrary, this embodiment will be described about a wiring board formed by alternately laminating wiring layers and insulating layers from the external connection terminal surface side. Although the first embodiment is configured so that an insulating layer having a reinforcing material-containing insulating layer and a contact layer is provided near the center in the direction of lamination, this embodiment is configured so that an insulating layer having a reinforcing material-containing insulating layer and a contact layer is provided as the outermost layer on the external connection terminal surface side. 
     As shown in  FIG. 14 , a wiring board  3  has a structure in which a first wiring layer  111 , a first insulating layer  120 , a second wiring layer  122 , a second insulating layer  130 , a third wiring layer  131 , a third insulating layer  140 , a fourth wiring layer  141 , a fourth insulating layer  150 , a fifth wiring layer  151 , a fifth insulating layer  160  and a sixth wiring layer  161  are formed successively. In this manner, the wiring board  3  according to this embodiment has the form of a “coreless board” containing no support based material, similarly to the wiring board  1  according to the first embodiment. 
     Incidentally, metal such as copper or copper alloy can be used as each of the materials of the first to sixth wiring layers  122 ,  131 ,  141 ,  151  and  161 . 
     In the wiring board  3 , the first wiring layer  111  is formed as the lowermost layer in  FIG. 14 . The first wiring layer  111  has a first conductive layer  112 , and a second conductive layer  113 . For example, a conductive layer in which an Au film, a Pd film and an Ni film are formed successively in this order so that the Au film is exposed out of the wiring board  3  can be used as the first conductive layer  112 . For example, a conductive layer containing a Cu layer or the like can be used as the second conductive layer  113 . 
     Parts of the first wiring layer  111 , that is, a first principal surface  112 A (a lower surface in the drawing) of the first conductive layer  112  are exposed out of the first insulating layer  20  and serve as external connection pads  111 P to which external connection terminals such as solder balls, lead pins, etc. used when the wiring board  3  is mounted in a mother board or the like are connected. That is, in this embodiment, a surface where the external connection pads  111 P are formed is provided as an external connection terminal surface. In addition, in this embodiment, the first principal surface  112 A of the first conductive layer  112  is on the same plane with the first principal surface (lower surface in the drawing) of the first insulating layer  120 . Incidentally, the first wiring layer  111  per se exposed out of the first insulating layer  120  may be used as external connection terminals. 
     For example, the planer shape of the first wiring layer  111  exposed out of the first insulating layer  120  is circular. For example, the diameter of each circle can be set to be in a range of about 200 μm to about 1000 μm. For example, the pitch of the first wiring layer  111  exposed out of the first insulating layer  120  can be set to be in a range of about 500 μm to about 1200 μm. For example, the thickness of the first wiring layer  111  can be set to be in a range of about 10 μm to about 20 μm. 
     The first insulating layer  120  has an insulating layer  120 A, and a contact layer  121 A. The insulating layer  120 A is formed so that the second principal surface (upper surface in the drawing) and side surfaces of the first wiring layer  111  are covered with the insulating layer  120 A but the first principal surface  112 A of the first wiring layer  111  is exposed. The insulating layer  120 A is an insulating layer which has the same composition as the insulating layer  40 A in the first embodiment, i.e. a reinforcing material-containing insulating layer. An epoxy-based insulating resin having thermosetting characteristic can be used as the material of the insulating layer  120 A. Incidentally, the insulating resin is not limited to the resin having thermosetting characteristic but an insulating resin having photosensitivity can be used. For example, the thickness of the insulating layer  120 A can be set to be in a range of about 30 μm to about 60 μm. 
     The contact layer  121 A is formed on the insulating layer  120 A so that the upper surface of the insulating layer  120 A is covered with the contact layer  121 A. The contact layer  121 A is an insulating layer which has the same composition as the contact layer  41 A in the first embodiment, i.e. an insulating layer which has a surface smoother (lower roughness) than the insulating layer  120 A and which is higher in adhesion to a metal film (e.g. electroless plating) than the insulating layer  120 A. For example, an insulating resin containing 30 vol % or more of an epoxy resin, and 1 to 50 vol % of an inorganic filler can be used as the material of the contact layer  121 A. 
     For example, the surface roughness of the contact layer  121 A is set to be in a range of 50 to 350 nm in terms of surface roughness Ra value. For example, the thickness of the contact layer  121  can be set to be in a range of about 0.5 μm to about 5 μm. 
     The second wiring layer  122  is formed on the first insulating layer  120 . The second wiring layer  122  has via-wirings  122   a  packed in via-holes VH 11  which are formed through the insulating layer  120 A and the contact layer  121 A to expose the upper surface of the first wiring layer  111 , and wiring patterns  122   b  formed on the contact layer  121 A. The via-wirings  122   a  are electrically connected to the first wiring layer  111  exposed in the bottoms of the via-holes VH 11 . Incidentally, each of the via-holes VH 11  and the via-wirings  122   a  is tapered to have a shape having its diameter increasing as the position goes from the lower side (external connection terminal surface side) to the upper side (sixth wiring layer  161  side) in  FIG. 14 . For example, the thickness of the wiring patterns  122   b  of the second wiring layer  122  can be set to be in a range of about 20 μm to about 35 μm. 
     The third to sixth wiring layers  131 ,  141 ,  151  and  161  are formed with interposition of the second to fifth insulating layers  130 ,  140 ,  150  and  160  and interlayer-connected through via-wirings  131   a ,  141   a ,  151   a  and  161   a  packed in via-holes VH 12 , VH 13 , VH 14  and VH 15  formed in the insulating layers  130 ,  140 ,  150  and  160  respectively. 
     Incidentally, an epoxy-based insulating resin having thermosetting characteristic can be used as each of the materials of the second to fifth insulating layers  130 ,  140 ,  150  and  160 . Incidentally, the insulating resin is not limited to the resin having thermosetting characteristic but an insulating resin having photosensitivity can be used. For example, the thicknesses of the second to fifth insulating layers  130 ,  140 ,  150  and  160  can be set to be in a range of about 15 μm to about 35 μm. 
     The third wiring layer  131  has via-wirings  131   a  electrically connected to the wiring patterns  122   b  of the second wiring layer  122 , and wiring patterns  131   b  electrically connected to the via-wirings  131   a . The fourth wiring layer  141  has via-wirings  141   a  electrically connected to the wiring patterns  131   b , and wiring patterns  141   b  electrically connected to the via-wirings  141   a . The fifth wiring layer  151  has via-wirings  151   a  electrically connected to the wiring patterns  141   b , and wiring patterns  151   b  electrically connected to the via-wirings  151   a . The sixth wiring layer  161  has via-wirings  161   a  electrically connected to the wiring patterns  151   b , and wiring patterns  161   b  electrically connected to the via-wirings  161   a . Each of the via wirings  131   a ,  141   a ,  151   a  and  161   a  of the third to sixth wiring layers  131 ,  141 ,  151  and  161  is tapered to have a shape having its diameter increasing as the position goes from the lower side (external connection pad  111 P side) to the upper side (wiring pattern  161   b  side) in  FIG. 14 . Specifically, each of the via-wirings  131   a ,  141   a ,  151   a  and  161   a  is shaped like a frustum of a circular cone so that the diameter of an end surface on the external connection pad  111 P side is smaller than the diameter of an end surface on the wiring pattern  161   b  side. 
     A solder resist layer  162  is formed on the fifth insulating layer  160 . For example, an epoxy-based insulating resin can be used as the material of the solder resist layer  162 . For example, the thickness of the solder resist layer  162  can be set to be in a range of about 15 μm to about 35 μm. 
     Opening portions  162 X for exposing parts of the wiring patterns  161   b  as electrode pads  161 P are formed in the solder resist layer  162 . The electrode pads  161 P are configured so that, for example, a semiconductor chip or the like can be electrically connected to the electrode pads  161 P. That is, in this embodiment, a surface where the electrode pads  161 P are formed is provided as a chip mounting surface. Incidentally, if necessary, a metal layer may be formed on each of the wiring patterns  161   b  of the sixth wiring layer  161  exposed out of the opening portions  162 X so that a semiconductor chip can be connected to the metal layer. An Au layer, an Ni/Au layer (a metal layer formed in such a manner that an Ni layer and an Au layer are formed in this order), an Ni/Pd/Au layer (a metal layer formed in such a manner that an Ni layer, a Pd layer and an Au layer are formed in this order), etc. can be listed as examples of the metal layer. 
     The planer shape of each of the opening portions  162 X (electrode pads  161 P) of the solder resist layer  162  is, for example, circular. For example, the diameter of each circle can be set to be in a range of about 40 μm to about 120 μm. For example, the pitch of the electrode pads  161 P can be set to be in a range of about 100 μm to about 200 μm. 
     Method of Manufacturing Wiring Board According to Second Embodiment 
     A method of manufacturing the wiring board  3  will be described below. 
     First, for production of the wiring board  3 , a support board  180  is prepared as shown in  FIG. 15A . For example, a metal plate or metal foil can be used as the support board  180 . In this embodiment, for example, copper foil is used as the support board  180 . For example, the thickness of the support board  180  is in a range of 35 μm to 100 μm. Successively, a resist layer  181  having opening portions  181 X corresponding to the shape of the first wiring layer  111  is formed on one surface (upper surface in the drawing) of the support board  180 . Then, while the resist layer  181  is used as a plating mask, electrolytic plating using the support board  180  as a plating power feeding layer is applied to the upper surface of the support board  180 . Specifically, an electrolytic plating method is applied to the upper surface of the support board  180  exposed out of the opening portions  181 X of the resist layer  181  to thereby laminate the first conductive layer  112  and the second conductive layer  113  successively in the opening portions  181 X to form the first wiring layer  111 . For example, when the first conductive layer  112  has a structure in which an Au film, a Pd film and an Ni film are formed successively in this order, and the second conductive layer  113  is a Cu layer, an Au film, a Pd film and an Ni film are first formed in this order by an electrolytic plating method using the support board  180  as a plating power feeding layer to thereby form the first conductive layer  112 . A Cu layer is then formed on the first conductive layer  112  by an electrolytic plating method using the support board  180  as a plating power feeding layer to thereby form the second conductive layer  113 . 
     Then, in the step shown in  FIG. 15B , the resist layer  181  shown in  FIG. 15A  is removed. On the other hand, an insulating layer  120 B serving as an insulating layer  120 A (see  FIG. 14 ) is prepared, that is, a reinforcing material-containing insulating layer  120 B made of woven or unwoven fabric of glass, aramid or LCP (Liquid Crystal Polymer) fiber impregnated with an unhardened thermosetting resin (such as an epoxy-based resin or a polyimide-based resin) is prepared. A B-stage layer is used as the insulating layer  120 B. For example, the thickness of the insulating layer  120 B can be set to be in a range of 30 μm to 80 μm. 
     In the step shown in  FIG. 15B , a structure  182 A in which an insulating layer  121 B serving as a contact layer  121 A (see  FIG. 14 ) is bonded to a carrier  182  is prepared. For example, an insulating resin containing 30 vol % or more of an unhardened epoxy resin, and 1 to 50 vol % of an inorganic filler can be used as the material of the insulating layer  121 B. A semi-hardened state layer is used as the insulating layer  121 B. For example, the thickness of the insulating layer  121 B can be set to be in a range of about 1 μm to about 6 μm. For example, copper foil can be used as the carrier  182  for carrying the insulating layer  121 B. For example, the thickness of the carrier  182  can be set to be in a range of about 2 μm to about 18 μm. 
     In the step shown in  FIG. 15B , the insulating layer  120 B and the structure  182 A are disposed sequentially from bottom on the upper surface side of the structure in which the first wiring layer  111  is formed on the upper surface of the support board  180 . On this occasion, the structure  182 A is disposed in a state where the insulating layer  121 B faces downward so that the insulating layer  121 B becomes opposite to the insulating layer  120 B. Then, the structure in which the first wiring layer  111  is formed on the upper surface of the support board  180 , the insulating layer  120 B and the structure  182 A are pressed while heated at a temperature of about 190° C. to about 250° C. in a vacuum atmosphere from both sides. Consequently, as shown in  FIG. 15C , the insulating layers  120 B and  121 B are hardened so that the insulating layer  120 A and the contact layer  121 A are formed on the support board  180  and the first wiring layer  111 . Moreover, as the insulating layers  120 B and  121 B are hardened, the support board  180  and the first wiring layer  111  are bonded to the insulating layer  120 A while the insulating layer  120 A is bonded to the contact layer  121 A. 
     Successively, in the step shown in  FIG. 15C , the carrier  182  (copper foil) shown in  FIG. 15B  is selectively removed from the contact layer  121 A by etching. 
     Then, in the step shown in  FIG. 16A , via-holes VH 11  are formed in predetermined places of the insulating layer  120 A and the contact layer  121 A so that the upper surface of the first wiring layer  111  is exposed. For example, the via-holes VH 11  can be formed by a laser machining method using a carbon dioxide laser, a UV-YAG laser or the like. 
     When the via-holes VH 11  are formed by a laser machining method, desmear processing is then performed to remove a resin residue of the insulating layer  120 A and the contact layer  121 A deposited on the upper surface of the first wiring layer  111  exposed in the bottoms of the via-holes VH 11 . For example, this desmear processing can be performed by a permanganate method or the like. Incidentally, the roughness of the upper surface of the contact layer  121 A after the desmear processing is kept at a low value of about 50-350 nm in terms of surface roughness Ra value. 
     Then, in the step shown in  FIG. 16B , a second wiring layer  122  is formed on the first insulating layer  120 . The second wiring layer  122  can be formed by a semi-additive method in the same manner as in the steps described with reference to  FIGS. 6A to 7A . 
     That is, a seed layer (not shown) of copper or the like is formed on the upper surface of the first wiring layer  111  exposed in the bottoms of the via-holes VH 11 , the inner wall surfaces of the via-holes VH 11  and the upper surface of the contact layer  121 A by an electroless plating method or a sputtering method. On this occasion, the seed layer is formed on the upper surface (low roughness surface) of the contact layer  121 A so that the seed layer adheres to the contact layer  121 A with a high adhesion strength. Then, a resist layer (not shown) having opening portions corresponding to the shape of the second wiring layer  122  is formed on the seed layer. Successively, a wiring layer (not shown) of copper or the like is formed in the opening portions of the resist layer by an electrolytic plating method using the seed layer as a power feeding layer. Then, after the resist layer is removed, parts of the seed layer not covered with the wiring layer are removed by etching using the wiring layer as a mask. Consequently, the second wiring layer  122  having via-wirings  122   a  packed in the via-holes VH 11 , and wiring patterns  122   b  formed on the contact layer  121 A is formed on the first insulating layer  120 . 
     Then, in the step shown in  FIG. 16C , the steps shown in  FIGS. 3D to 4A  are repeated again so that insulating layers and wiring layers are formed alternately. That is, as shown in  FIG. 16C , the second insulating layer  130  is formed on the contact layer  121 A and the second wiring layer  122 , and the third wiring layer  131  is formed on the second insulating layer  130 . Similarly, the third insulating layer  140 , the fourth wiring layer  141 , the fourth insulating layer  150 , the fifth wiring layer  151 , the fifth insulating layer  160  and the sixth wiring layer  161  are formed in this order by lamination. 
     Then, in the step shown in  FIG. 16C , a solder resist layer  162  having opening portions  162 X for exposing electrode pads  161 P determined in required places of the sixth wiring layer  161  is formed on the fifth insulating layer  160  and the sixth wiring layer  161 . Consequently, parts of the sixth wiring layer  161  are exposed as electrode pads  161 P out of the opening portions  162 X of the solder resist layer  162 . Then, the support board  180  is removed so that the wiring board  3  shown in  FIG. 14  can be produced. 
     According to the aforementioned embodiment, the following effects can be obtained in addition to the effects (1) to (4) of the first embodiment. 
     (1) Only one interlayer insulating layer which is the outermost layer on the external connection pad  111 P side is provided as the insulating layer  120  having a reinforcing material-containing insulating layer  120 A and a contact layer  121 A. This reason will be described below. 
     First, it is general that the wiring layer (the first wiring layer  111  in this case) used as external connection pads  111 P has a high remaining copper ratio whereas the wiring layer (the sixth wiring layer  161  in this case) used as electrode pads  161 P has a low remaining copper ratio. Although the ratio is referred to as the remaining copper ratio in this embodiment on the assumption that the metal layer is made of copper, the metal layer may be made of another metal than copper. 
     Warping occurs in the wiring board  3  easily in accordance with the difference in remaining copper ratio as described above. Specifically, under an environment of normal temperature lower than the glass transition temperature Tg of an interlayer insulating layer, a layer having a low remaining copper ratio, that is, a layer containing a large amount of an insulating resin is so shrinkable that the electrode pad  161 P side (chip mounting surface side) has a tendency toward warping concavely. On the other hand, under an environment of high temperature higher than the glass transition temperature Tg of the interlayer insulating layer, a layer having a low remaining copper ratio is warped toward a layer having a high remaining copper ratio, that is, the external connection pad  111 P side (external connection terminal surface side) has a tendency toward warping concavely. 
     On the contrary, this embodiment is configured so that a reinforcing material-containing insulating layer  120 A is provided in the interlayer insulating layer (the first insulating layer  120  in this case) which is the outermost layer on the external connection pad  111 P side, that is, the first insulating layer  120  easily warped. Thus, the rigidity of the first insulating layer  120  can be improved so that warping of the wiring board  3  can be reduced effectively. That is, for example, when the wiring board  3  is warped under a high temperature environment, improvement in the rigidity of the insulating layer  120  as an external connection terminal surface-side outermost layer concavely warped can work effectively against stress warping the wiring board  3  to provide a large effect of reducing warping of the wiring board  3 . 
     Moreover, even when the temperature of the wiring board  3  becomes higher than the glass transition temperature Tg of the other insulating layers  130 ,  140 ,  150  and  160  than the insulating layer  120 A, the rigidity of the reinforcing material contained in the insulating layer  120 A can suppress occurrence of warping to stabilize the behavior under a high temperature environment because the glass transition temperature Tg of the insulating layer  120 A is higher than the glass transition temperature Tg of the other insulating layers  130 ,  140 ,  150  and  160 . 
     (2) The reinforcing material-containing insulating layer  120 A becomes thicker than the other insulating layers (e.g. the second insulating layer  130 ) containing no reinforcing material. Accordingly, the via-holes VH 11  formed in the first insulating layer  120  become deeper than the via-holes VH 15  formed in the fifth insulating layer  160 , and the diameter at an opening end (the diameter on the solder resist layer  162  side) becomes large. That is, the via-holes VH 11  become larger in volume than the via-holes VH 15 . However, the large volumes of the via-holes VH 11  do not bring any trouble because the via-holes VH 11  are provided on the external connection terminal surface side and a design rule on the external connection terminal surface side is looser than that on the chip mounting surface side so that the pitch of the external connection pads  111 P can be made wider than that of the electrode pads  161 P. That is, even when the reinforcing material-containing insulating layer  120 A is provided in the insulating layer  120  which serves as an outermost layer on the external connection pad  111 P side as described above, required via-holes VH 11  and wiring layers  111 ,  122 , etc. can be formed without loosening the design rule. 
     Incidentally, the respective embodiments can be carried out based on the following forms which have been changed properly. 
     Modification of Second Embodiment 
     The second embodiment is configured so that an insulating layer  120  having a reinforcing material-containing insulating layer  120 A and a contact layer  121 A low in roughness and improved in adhesion to electroless plating is provided as the outermost interlayer insulating layer on the external connection terminal surface side. The invention is not limited thereto as long as at least one of built-up interlayer insulating layers in the wiring board is the insulating layer  120  having the insulating layer  120 A and the contact layer  121 A. Accordingly, the position where each insulating layer  120  is formed and the number of such insulating layers  120  are not particularly limited. 
     For example, as shown in  FIG. 17 , the interlayer insulating layer near the center in the direction of lamination may be replaced by the insulating layer  120  having the reinforcing material-containing insulating layer  120 A and the contact layer  121 A. That is, in a wiring board  3 A, the third insulating layer  140  in the wiring board  3  shown in  FIG. 14  is replaced by the insulating layer  120 , and the insulating layer  120  in the wiring board  3  is replaced by an insulating layer  123  containing no reinforcing material. In the wiring board  3 A, a wiring layer  142  formed on the insulating layer  120  has via-wirings  142   a  packed in via-holes VH 16  formed through the reinforcing material-containing insulating layer  120 A and the contact layer  121 A to expose the upper surface of the wiring layer  131 , and wiring patterns  142   b  formed on the contact layer  121 A. By such a structure, the same effect as in the first embodiment can be obtained. 
     (Other Modifications) 
     Although the respective embodiments have been described in an example in which one wiring board  1  or  3  is produced on a support board  80  or  180 , a process of manufacturing a member to be formed as a plurality of wiring boards  1  or  3  on a support board  80  or  180  and dividing the member to obtain the plurality of wiring boards  1  or  3  individually may be used. 
     In the respective embodiments, a reinforcing material-containing insulating resin is used as the material of the insulating layer  40 A or  120 A. The invention is not limited thereto. For example, an epoxy-based insulating resin containing about 20% to about 70% of a filler such as silica (SiO 2 ) may be used as the material of the insulating layer  40 A or  120 A. In this case, the filler content can be adjusted so that the thermal expansion coefficient of the insulating layer  40 A or  120 A is adjusted to be close to the thermal expansion coefficient (e.g. about 17 ppm/° C.) of the wiring layer (for example, the thermal expansion coefficient decreases as the filler content increases). 
     In the respective embodiments, the insulating layer  41 B or  121 B to be formed as the contact layer  41 A or  121 A is bonded to the carrier  82  or  182  when the insulating layer  40 A or  120 A and the contact layer  41 A or  121 A are formed collectively. The invention is not limited thereto. For example, a structure in which an insulating layer  41 B and an insulating layer  40 B are provided on a carrier  82  may be prepared and the carrier  82  may be removed after the structure is formed on a wiring layer and an insulating layer as lower layers. Alternatively, a structure in which an insulating layer  41 B is provided on an insulating layer  40 B may be prepared and the structure may be formed on a wiring layer and an insulating layer as lower layers. 
     In the respective embodiments, wiring layers and insulating layers are mainly formed on one side (one surface) of a support board by a build-up method and the support board is finally removed to produce a coreless wiring board. The invention is not limited thereto. For example, wiring layers and insulating layers may be mainly formed on both sides (one surface and the other surface) of a support board by a build-up method and the support board may be finally removed to produce a plurality of coreless wiring boards. In this case, wiring layers and insulating layers are formed successively on each of one surface and the other surface of the support board from the chip mounting surface side in the same manner as in the process shown in  FIGS. 3A-3E ,  4 A- 4 B,  5 A- 5 C,  6 A- 6 C and  7 A- 7 B, and the support board is finally removed. Or wiring layers and insulating layers are formed successively on each of one surface and the other surface of the support board from the external connection terminal surface side in the same manner as in the process shown in  FIGS. 15A-15C  and  16 A- 16 C, and the support board is finally removed. 
     Although the respective embodiments have been described in the case where a semiconductor chip  70  is mounted on the wiring board  1 , the body to be mounted is not limited to the semiconductor chip  70 . For example, the invention can be also applied to a package (package on package) having a structure in which another wiring board is piled up on the wiring board  1 . 
     In the respective embodiments, the number of layers in the wiring board  1  or  3 , the layout of wirings or the form of mounting the semiconductor chip  70  (e.g. flip chip mounting, mounting due to wire bonding or combination thereof) can be modified or changed variously. 
     While the present invention has been shown and described with reference to certain exemplary embodiments thereof, other implementations are within the scope of the claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.