Patent Description:
Heretofore, as a wiring board, for example, a ceramic wiring board has been known in which a wiring layer (conductor portion) is formed on a ceramic board. In addition, as this wiring layer, one has been known in which a metallized layer is formed on the ceramic board, a Ni plated layer is formed on the metallized layer by Ni plating and a Cu plated layer or an Au plated layer is formed on the Ni plated layer by Cu-plating or Au plating (see patent documents <NUM>-<NUM>).

Here, nickel (Ni) is a ferromagnetic body, and when momentarily exposed to a magnetic field due to use environment or a magnetic component to be mounted, nickel is permanently magnetized, and consequently, electrical characteristics (for example, high frequency characteristics) deteriorate.

As a measure for this, a technique has been known in which, as underlying plating for Au plating, copper (Cu) that is a non-magnetic body is used instead of nickel. Patent document <NUM> discloses a method for manufacturing a wiring board formed with a wiring layer made of tungsten and/or molybdenum and copper baked with a ceramic insulation base material so as to be integrated with the insulation base material. A palladium plating layer and a copper or gold plating layer are successively adhered on an exposed surface of the wiring layer. The palladium plating layer is adhered to the wiring layer by diffusion bonding. Patent document <NUM> discloses a method for manufacturing a wiring board having a wiring layer deposited to an insulation base and plating layers sequentially deposited on the exposed surface of the wiring layer. Patent document <NUM> discloses a method for manufacturing a ceramic wiring board in which a Cu-plating is applied on the surface of a wiring formed on a wiring board. The wiring is formed from mixed material with tungsten or molybdenum mixed with inorganic powder, the inorganic powder being removed by etching after the mixed material has been arranged on the board.

However, as mentioned above, when non-magnetic Cu plating is used instead of Ni plating, due to the insufficient adhesiveness between the metallized layer and the Cu plated layer, failure occurs.

Specifically, when various components are mounted to the wiring layer by solder, problems occur. For example, solder leaching (that is, a phenomenon in which copper is absorbed by solder) occurs, and at the time of wire bonding of, for example, an Au wire, peeling-off of plating occurs. Consequently, mountability becomes insufficient.

That is, when various components are mounted to the wiring layer by solder and the Au wire is bonded (that is, mounted) to the wiring layer by wiring bonding, they cannot be preferably mounted thereon in some case.

The present invention is provided in consideration of the above problems, and an object of the present invention is to provide a wiring board having a conductor portion on which mounting is suitably possible and a method for manufacturing the wiring board.

In the present first aspect, since the Cu plated layer as a conductive layer is formed by plating on the surface of the lower Cu plated layer as a conductor base portion (that is, the exposed surface) and then the conductive layer is heated to be softened and melted (hereinafter, this treatment described as heat treatment), the conductive material of the softened or melted conductive layer enters into open pore portions that are recessed portions of the conductor base portion. In addition, at the time of this heat treatment, components of the conductor base portion and components of the conductive layer are mutually thermally diffused. Consequently, when solidified later, a remarkable effect can be obtained that the adhesiveness between the conductor base portion and the conductive layer is improved due to, for example, an anchoring effect and a mutual thermal diffusion effect, thereby being strongly bonded.

In addition, by the softening or melting, pores (voids) along the surface of the conductor base portion may be formed on the surface of the conductive layer after the heat treatment. However, in the present first aspect, since the surface layer is formed on the surface of the conductive layer by plating, it is possible to cover the open pore portions with the conductive layer and the surface layer sufficiently (that is, cover properties are improved).

Therefore, when various components are mounted on the surface of the conductor portion formed in this way (or mounted on the surface formed by further plating, for example, Au on the surface of the conductor portion) by, for example, solder, or when, for example, an Au wire is bonded thereon by wire bonding (that is, mounting), the mountability is improved.

Moreover, to form a non-magnetic conductor portion, when non-magnetic copper (Cu) is used instead of, for example, ferromagnetic nickel (Ni), for example, there is a problem that the adhesiveness between the conductor base portion formed by metallizing and the conductive layer made of copper is low. However, in the manufacturing method of the present first aspect, since the adhesiveness between the conductor base portion and the conductive layer is improved, there is an advantage that mountability is improved.

That is, in the present first aspect, when the non-magnetic conductor portion is formed, since the adhesiveness between the conductor base portion and the conductive layer is improved, a remarkable effect that the mountability is also improved can be obtained.

In addition, when the heat treatment of the conductive layer is performed, it can be heated at a temperature equal to or higher than <NUM>% of the melting point of the conductive material used for forming the conductive layer.

The method of the present invention includes forming a surface plated layer made of at least one of gold, silver and tin on a surface of the upper Cu plated layer by plating.

Then, since the surface plated layer is formed on the exposed surface by plating using gold, silver or tin, it is possible to suppress oxidation of the surface layer. Therefore, the mounting of various components and the wire bonding can be appropriately performed to the surface plated layer.

In addition, as a material of the surface plated layer, gold (Au) having high oxidation resistance and excellent mountability is preferable.

In addition and prior to the forming of the surface plated layer, the method of the present invention also includes forming a palladium plated layer made of palladium on the surface of the surface plated layer by plating.

When the above palladium plated layer is formed on the surface of the surface layer (that is, the exposed surface), in other words, formed between the surface layer and the surface plated layer, the surface plated layer can be thinned by that layer. For example, when gold is used as a material of the surface plated layer, there is an advantage that the usage of expensive gold can be reduced.

The conductor base portion is formed of a conductive material and includes particles with an open pore portion that is a recessed portion formed on the surface of the conductor base portion, a particle diameter in case of powder material, and a heating condition in metallization can be adjusted for extremely small unevenness (that is, open pore portions that are recessed portions) formed on the surface of the conductor base portion (that is, the exposed surface). For example, by enlarging the particle diameters of the particles, large open pore portions can be formed.

Consequently, when the conductive layer is formed on the conductor base portion, the adhesiveness by an anchoring effect can be improved.

The pre-treatment for removing particles of silica, for example, etching, allows to form the open pore portions on the surface of the conductor base portion, and moreover, it is possible to enlarge the open pore portions.

Consequently, when the conductive layer is formed on the conductor base portion, the adhesiveness by the anchoring effect is further improved.

As an example, an appropriate forming method for the conductor base portion is shown. For example, as is well known, metallization paste is applied on a green sheet and metallization is performed by baking simultaneously, and the metallized layer can be formed.

A further aspect of the present invention relates to the wiring board of claim <NUM>.

In the present eighth aspect, the conductor portion has a structure in which the metallized layer as a conductor base portion, the intermediate layer, the lower Cu plated layer as a conductive layer and the upper Cu plated layer are laminated (that is, a structure in which non-magnetic portions are laminated), and the intermediate layer includes the material of the conductor base portion and the material of the conductive layer due to, for example, thermal diffusion. Therefore, there is an effect that the adhesiveness between the conductor base portion and the conductive layer having the intermediate layer therebetween is high.

Therefore, when various components are mounted on the surface of the conductor portion (or mounted on the surface formed by further plating gold on the surface of the conductor portion) having such a configuration by solder, or when wire bonding is performed thereon, there is an advantage that the mountability is improved.

Moreover, when non-magnetic copper is used instead of, for example, ferromagnetic nickel to form the conductor portion that is a non-magnetic body, there is a problem that the adhesiveness between the conductor base portion formed by, for example, metallization and the conductive layer made of copper is low. However, since the adhesiveness between the conductor base portion and the conductive layer can be improved, the mountability can be improved.

That is, in the conductor portion that is a non-magnetic body, since the adhesiveness between the conductor base portion and the conductive layer is improved, a remarkable effect that the mountability is also improved can be obtained.

The upper Cu plated layer is provided with, on a surface thereof, a surface plated layer made of at least one of gold, silver and tin.

Then, since the surface plated layer made of at least one of gold, silver and tin is provided on the surface of the upper Cu plated layer, oxidation of the surface layer can be suppressed. Therefore the mounting of various components and the wire bonding can be preferably performed to the surface plated layer.

A palladium plated layer may be provided between the upper Cu plated layer and the surface plated layer and then, the surface plated layer can be thinned by that layer.

The metallized layer as a conductor base portion includes, on the surface thereof, an open pore portion that is a recessed portion.

Thus, when the conductive layer is formed on the conductor base portion, the adhesiveness by an anchoring effect is improved.

The lower Cu plated layer as a conductive material of the conductive layer exists in the open pore portion on the surface of the conductor base portion.

Thus, since the conductive material of the conductive layer exists in the open pore portion on the surface of the conductor base portion, when the conductive layer is formed on the conductor base portion, the adhesiveness by an anchoring effect is improved.

The conductor base portion is a metallized layer.

It is shown that a non-magnetic body is a diamagnetic body of which magnetic susceptibility is less than <NUM> or a paramagnetic body of which magnetic susceptibility is less than <NUM> × <NUM>-<NUM>.

As the conductor portion, a non-magnetic wiring layer can be cited in which a plurality of layers having conductivity are formed on the surface of a metallized layer. That is, it is, for example, a non-magnetic wiring layer formed on the surface of a ceramic board, and an electric wiring for transmitting electric signals (in particular, high speed signals) can be cited. In addition, a non-magnetic laminated body can be cited in which a plurality of layers having conductivity are formed on the surface of a metal plate which is used for a heat sink.

As the conductor base portion, a non-magnetic metallized layer or metal plate can be cited.

As the conductive material used for the conductor base portion, for example, non-magnetic W, Mo, CuW or CuMo can be cited.

As the plating, electrolytic plating or electroless plating can be cited.

The metallization is one in which the surface of ceramic or non-metal material is sintered to be metallized by baking, and the metallized layer formed by the metallization is a metallized layer.

Next, an embodiment of a wiring board and a method for manufacturing the wiring board in the present invention will be explained.

In the present first embodiment, as an example, a ceramic wiring board in which a conductor portion that is a wiring layer is formed on a ceramic board and a method for manufacturing the ceramic wiring board will be explained.

First, the configuration of the ceramic wiring board in the present first embodiment will be explained.

As schematically shown in <FIG>, an ceramic wiring board <NUM> of the present first embodiment is a non-magnetic wiring board for mounting various semiconductor elements and crystal, and, for example, it is used as a wiring board of a ceramic package (not shown in the drawings).

The ceramic wiring board <NUM> is provided with a ceramic board <NUM> and a conductor portion <NUM> as a wiring layer provided on the surface of the ceramic board <NUM>.

Among these, the ceramic board <NUM> is a sintered body made of, for example, alumina (alumina sintered body) that is a non-magnetic body, and the conductor portion <NUM> is formed of a plurality of the after-mentioned non-magnetic layers having conductivity.

Specifically, the conductor portion <NUM> is provided with, on the surface of the ceramic board <NUM>, a non-magnetic metallized layer (that is, a conductor base portion) <NUM>. For example, this metallized layer <NUM> is a sintered body made of tungsten (W) and/or molybdenum (Mo) as a main component and ceramic material, such as alumina (Al<NUM>O<NUM>) and silica (SiO<NUM>), and it is a layer having well-known conductively.

As this metallized layer <NUM>, for example, one can be cited which contains <NUM> weight % of tungsten (W), <NUM> weight % of alumina (Al<NUM>O<NUM>) and minute amounts of silica (SiO<NUM>), and whose thickness is, for example, about <NUM>. Although silica is contained within a range of <NUM> weight % or less, in case of, for example, less than <NUM> weight %, components other than silica are contained, or components of tungsten or alumina are properly adjusted. In addition, the amount of this silica component is not limited to the above-mentioned weight ratio, and the silica component only needs to exist in the metallized layer <NUM>.

As schematically shown in <FIG> so as to be enlarged, particles (for example, crystal particles) such as tungsten and alumina composing the metallized layer <NUM> are exposed on the surface of the metallized layer <NUM> (that is, the surface on a side (upper side of <FIG>) in which the after-mentioned other layers are laminated and which is opposite to a ceramic board <NUM> side), and a plurality of open pore portions <NUM> are formed on the surface of the metallized layer <NUM>. In addition, the open pore portions <NUM> are portions opened outward in the surface, in extremely small cavities existing inside the metallized layer <NUM> formed by sintering the particles such as tungsten and alumina. That is, the open pore portions <NUM> are recessed portions of extremely small recessed and projecting portions formed along the surface in which the particles composing the metallized layer <NUM> are exposed.

Here, by these open pore portions <NUM>, the surface roughness (here, the arithmetic average roughness Ra) of the metallized layer <NUM> is within a range of, for example, <NUM>-<NUM>.

In addition, an intermediate layer <NUM> is formed along the surface of the metallized layer <NUM> (that is, along the surface formed with the open pore portions <NUM>). This intermediate layer <NUM> is a layer in which the components of layers on the both sides (upper and lower of <FIG>) in the thickness direction thereof are contained, that is, a layer in which the components of the metallized layer <NUM> on the lower side of <FIG> and the after-mentioned lower Cu plated layer (that is, a conductive layer) <NUM> on the upper side of <FIG> are contained. That is, the intermediate layer <NUM> is a layer made of, for example, tungsten, ceramic material and copper (Cu).

Returning to <FIG>, the surface of the intermediate layer <NUM> (that is, the surface on the laminated side) is formed with the lower Cu plated layer <NUM> which is made of copper and has a thickness within a range of, for example, <NUM>-<NUM> (for example, the thickness is <NUM>), so as to cover the whole surface of the intermediate layer <NUM>.

This lower Cu plated layer <NUM> is a layer which is fused to the metallized layer <NUM> by softening or melting the layer plated with copper by the after-mentioned heat treatment and then solidifying it (that is, a Cu fused layer).

In addition, the surface of the lower Cu plated layer <NUM> (that is, the surface on the laminated side) is formed with an upper Cu plated layer (that is, a surface layer) <NUM> which is made of copper and has a thickness within a range of, for example, <NUM>-<NUM> (for example, the thickness is <NUM>), so as to cover the whole surface of the lower Cu plated layer <NUM>.

Moreover, the surface of the upper Cu plated layer <NUM> (that is, the surface on the laminated side) is formed with an Au plated layer (that is, a surface plated layer) <NUM> which is made of gold (Au) and has a thickness within a range of, for example, <NUM>-<NUM> (for example, the thickness is <NUM>), so as to cover the whole surface of the upper Cu plated layer <NUM>.

Furthermore, the ceramic board <NUM> is a non-magnetic body, and since each of the layers <NUM>, <NUM>,<NUM>, <NUM> and <NUM> forming the conductor portion <NUM> is a non-magnetic body, the conductor portion <NUM> is also a non-magnetic body, and the ceramic wiring board <NUM> is therefore a non-magnetic body.

Next, a method for manufacturing the ceramic wiring board <NUM> of the present first embodiment will be explained.

As a method for forming this metallized layer <NUM>, first, well-known metallized paste is prepared by adding predetermined vehicle and the like to a solid component composed of conductive material consisting of at least one of tungsten and molybdenum (for example, tungsten) and of ceramic material composed of alumina and silica.

In addition, as a ratio of the solid component, the same ratio as the conventional ratio can be adopted so as to become the composition of the above-mentioned metallized layer <NUM>. Next, the metallized paste is applied to the surface of the ceramic board <NUM>. After that, by baking it, for example, at a temperature of <NUM>, the metallized layer <NUM> is formed.

As schematically shown in <FIG>, the metallized layer <NUM> is composed of various kinds of particles (for example, crystal particles) and the like composing the metallized layer <NUM>. Specifically, the metallized layer <NUM> is mainly composed of tungsten particles (TR), alumina particles (AR) and silica particles (SR). In addition, each of the particles exists in a state of a single body or an aggregate by being aggregated, and is exposed on the surface of the metallized layer <NUM> in that state.

Consequently, the open pore portions <NUM> along the shape of the particle single-body or the aggregate of the particles are formed on the surface of the metallized layer <NUM>. In addition, in this stage, the inner diameter of each of the open pore portions <NUM> is equal to <NUM> or greater.

Next, as plating pretreatment, washing is performed to the surface of the metallized layer <NUM>. The silica particles (SR) as a glass component are exposed on a part of the surface of the metallized layer <NUM>, and by the washing, they are removed. As the plating pretreatment, for example, the silica particles (SR) may be removed by etching using hydrofluoric acid.

Consequently, as shown in <FIG>, the open pore portions <NUM> on the surface of the metallized layer <NUM> become open pore portions <NUM> that are largely recessed portions where the silica particles (SR) have been removed. That is, by removing the silica particles (SR), large open pore portions <NUM> each having the maximum inner diameter of approximately <NUM> can be formed. By the plating pretreatment, the silica particles (SR) are removed from the surface of the metallized layer <NUM>, and new open pore portions <NUM> may be formed.

In addition, in <FIG>, in the open pore portions <NUM>, one whose inner diameter becomes large by removing the silica particles (SR) is shown by a reference sign "9a". In addition, the surface of the metallized layer <NUM> before the etching is photographed by using a scanning electron microscope (SEM) at a magnification of x3000. As shown in <FIG> showing the SEM photograph, it can be understood that there are a plurality of pores (voids), that is, a plurality of the open pore portions <NUM> are formed on the surface of the metallized layer <NUM>.

(<NUM>) Next, as shown in <FIG>, an initial Cu plated layer <NUM> which becomes the lower Cu plated layer (that is, the Cu fused layer) <NUM> by performing the heat treatment later is formed on the surface of the metallized layer <NUM>.

Specifically, for example, by well-known electrolytic plating or electroless plating (that is, Cu plating), the initial Cu plated layer <NUM> with a thickness of, for example, <NUM> is formed on the surface of the metallized layer <NUM>.

(<NUM>) Next, as shown in <FIG>, after the initial Cu plated layer <NUM> is heated to be softened or melted (that is, after the heat treatment), it is cooled to be solidified, and the lower Cu plated layer <NUM> is formed.

Specifically, the initial Cu plated layer <NUM> is heated to a high temperature (for example, <NUM>) equal to or greater than a temperature at which copper is softened or melted to soften or melt the initial Cu plated layer <NUM> (that is, the heat treatment is performed). With this, as shown in <FIG>, the softened or melted copper enters (penetrates) into the open pore portions <NUM> on the surface of the metallized layer <NUM>.

After that, the initial Cu plated layer <NUM> is cooled to room temperature to be solidified, and then becoming the lower Cu plated layer <NUM>.

In addition, although the softened or melted initial Cu plated layer <NUM> enters into the open pore portions <NUM>, in open pore portions <NUM> each having a diameter larger than the thickness of the initial Cu plated layer <NUM> (for example, <NUM>), there is possibility that copper is not sufficiently filled, and recessed portions due to the open pore portions <NUM> remain on the surface of the lower Cu plated layer <NUM>.

In addition, by the above-mentioned heat treatment, the intermediate layer <NUM> (see <FIG>, <FIG>) is formed at the interface between the metallized layer <NUM> and the lower Cu plated layer <NUM> by mutually diffusing the components of each of the metallized layer <NUM> and the lower Cu plated layer <NUM>.

(<NUM>) Next, as shown in <FIG>, the upper Cu plated layer <NUM> is formed on the surface of the lower Cu plated layer <NUM>.

Specifically, for example, by well-known electrolytic plating or electroless plating (that is, Cu plating), the upper Cu plated layer <NUM> with a thickness of, for example, <NUM> is formed on the surface of the lower Cu plated layer <NUM>.

In addition, when the lower Cu plated layer <NUM> is formed by solidifying the initial Cu plated layer <NUM> after being softened or melted, although recessed portions (not shown in the drawings) such as pores (voids) along the surface of the metallized layer <NUM> may be formed on the surface of the lower Cu plated layer <NUM>, these recessed portions are filled with copper at the time of the formation of the upper Cu plated layer <NUM>, and consequently, the surface of the upper Cu plated layer <NUM> becomes smooth.

(<NUM>) Next, as shown in <FIG>, the Au plated layer <NUM> is formed on the surface of the upper Cu plated layer <NUM>.

Specifically, for example, by well-known electrolytic plating or electroless plating (that is, Au plating), the Au plated layer <NUM> with a thickness of, for example, <NUM> is formed on the surface of the upper Cu plated layer <NUM>.

In this way, the ceramic wiring board <NUM> is manufactured.

Here, as evaluation, solderability evaluation and wire bondability evaluation will be explained.

As Examples <NUM> and <NUM> within the scope of the present invention, samples, each of which was formed with the conductor portion <NUM> on the ceramic board <NUM>, were prepared similar to the above-mentioned embodiment. In addition, in each of these samples, the initial Cu plated layer <NUM> with a thickness of <NUM> is formed on the metallized layer <NUM>, the upper Cu plated layer <NUM> with a thickness of <NUM> is formed on the lower Cu plated layer <NUM> formed by performing the heat treatment of the present invention, and the Au plated layer <NUM> with a thickness of <NUM> is formed on that upper Cu plated layer <NUM>.

In addition, aside from these, as Comparative Examples <NUM> and <NUM> outside the scope of the present invention, samples were prepared. In each of the samples, as shown in <FIG>, the upper Cu plated layer <NUM> with a thickness of <NUM> is formed on the metallized layer <NUM> (without performing the heat treatment of the present invention) and the Au plated layer <NUM> with a thickness of <NUM> is formed on the upper Cu plated layer <NUM>.

After that, flux was applied to the conductor portion <NUM> of each of the samples, and each of the samples was dipped in a Pb-free solder (SAC305) tank for <NUM> seconds at <NUM>, following which a state of solder (that is, solderability) such as solder wettability was observed.

Here, when the solderability was evaluated, both of a solderability of each of the samples at room temperature (<NUM>) (room temperature in Table <NUM>) and a solderability of each of the samples after being heated for <NUM> minutes at <NUM> (intermediate temperature in Table <NUM>) were observed. In addition, the reason why each of the samples was heated at <NUM> is that a temperature condition to be actually used is considered.

The result is shown in the following Table <NUM>. In addition, "OK" in Table <NUM> indicates a desirable state in which solder is wetted and spread over the entire surface of the conductor portion <NUM> and thereby failure such as solder non-wetting and solder leaching does not occur. On the other hand, "NG" in Table <NUM> indicates an undesirable state in which the solder leaching occurs.

As is clear from this Table <NUM>, Examples <NUM> and <NUM> within the scope of the present invention are preferable because they are superior in the solderability. In contrast to these, Comparative Examples <NUM> and <NUM> of the present invention are not preferable because they are poor in the solderability.

As Examples <NUM> and <NUM> within the scope of the present invention, samples, each of which was formed with the conductor portion <NUM> on the ceramic board <NUM>, were prepared similar to Examples <NUM> and <NUM>.

In addition, samples of Comparative Examples <NUM> and <NUM> outside the scope of the present invention were prepared to be the same as those of Comparative Examples <NUM> and <NUM>.

Then, an Au wire with a diameter of <NUM> was bonded to the conductor portion <NUM> of each of the samples. After that, the ceramic board <NUM> was fixed and a tensile test (MIL-STD-<NUM>) in which the Au wire was pulled by applying a load thereto was carried out, and then a state of destruction was examined (that is, the wire bondability was examined).

In addition, in case where the wire bondability was evaluated, similar to the evaluation of the solderability, both of a wire bondability of each of the samples at room temperature (<NUM>) (room temperature in Table <NUM>) and a bondability of each of the samples after being heated for <NUM> minutes at <NUM>° C (intermediate temperature in Table <NUM>) were observed.

The result is shown in the following Table <NUM>. In addition, "OK" in Table <NUM> indicates a desirable state in which failure such as plating peeling at the time of the pulling of the Au wire does not occur and the cut of the wire is wire neck cut. On the other hand, "NG" in Table <NUM> indicates an undesirable state in which plating peeling occurs.

As is clear from this Table <NUM>, Examples <NUM> and <NUM> within the scope of the present invention are preferable because they are superior in the wire bondability. In contrast to these, Comparative Examples <NUM> and <NUM> of the present invention are not preferable because they are poor in the wire bondability.

Next, effects of the present first embodiment will be explained.

In the present first embodiment, since the initial Cu plated layer <NUM> is formed by plating so as to cover the surface of the metallized layer <NUM> and then the Cu plated layer <NUM> is heated to be softened or melted, the copper of the softened or melted initial Cu plated layer <NUM> enters into the open pore portions <NUM> of the metallized layer <NUM>. In addition, during the heating, components of the metallized layer <NUM> and components of the initial Cu plated layer <NUM> are mutually thermally diffused.

Consequently, when solidified later (that is, when the initial Cu plated layer <NUM> becomes the lower Cu plated layer <NUM>), due to, for example, an anchoring effect and a mutual thermal diffusion effect, a remarkable effect can be obtained that the adhesiveness between the metallized layer <NUM> and the lower Cu plated layer <NUM> is improved and thereby they are strongly joined.

In addition, at the time of the softening or melting, pores (voids) along the surface of the metallized layer <NUM> may be formed on the surface of the lower Cu plated layer <NUM> after the heat treatment. However, in the present first embodiment, since the upper Cu plated layer <NUM> is formed by plating so as to cover the surface of the lower Cu plated layer <NUM>, covering properties are improved. Moreover, the Au plated layer <NUM> is formed so as to cover the surface of the upper Cu plated layer <NUM>.

Consequently, in case where by, for example, solder, various components are mounted on the surface of the conductor portion <NUM> formed in this way, or in case where by wire bonding, an Au wire is bonded (that is, mounted) on the surface thereof, there is an advantage that mounting properties are improved.

Moreover, to form the conductor portion <NUM> that is a non-magnetic body, in case where, for example, non-magnetic copper is used instead of ferromagnetic nickel, for example, there is a problem that the adhesiveness between the metallized layer <NUM> and the initial Cu plated layer <NUM> is low. However, in the present first embodiment, since the adhesiveness between the metallized layer <NUM> and the lower Cu plated layer <NUM> (after the heat treatment of the initial Cu plated layer <NUM>) is improved, mounting properties are also improved.

That is, in the present first embodiment, in case where the conductor portion <NUM> that is a non-magnetic body is formed, since the adhesiveness between the metallized layer <NUM> and the lower Cu plated layer <NUM> is high, a remarkable effect that mounting properties are also high can be obtained.

In addition, in the present first embodiment, since, before forming the initial Cu plated layer <NUM>, by, for example, etching, the treatment for removing particles such as silica is performed in the open pore portions <NUM> on the surface of the metallized layer <NUM>, the open pore portions <NUM> can be enlarged (specifically, see the open pore portions 9a whose inner diameters become large in <FIG>). Moreover, by removing particles such as silica, open pore portions <NUM> can be newly formed.

Consequently, in case where the lower Cu plated layer <NUM> is formed on the metallized layer <NUM>, the adhesiveness can be improved by an anchoring effect.

Here, the correspondence relation of the wording between the present first embodiment and the scope of claims will be explained.

The conductor portion <NUM>, the ceramic wiring board <NUM>, the metallized layer <NUM>, the lower Cu plated layer <NUM>, the upper Cu plated layer <NUM>, the Au plated layer <NUM>, the open pore portions <NUM> and the intermediate layer <NUM> in the present first embodiment are respectively correspond to an example of each of a conductor portion, a wiring board, a conductor base portion, a conductive layer, a surface layer, a surface plated layer, open pore portions and an intermediate layer in the present invention.

Next, although a second embodiment will be explained, the explanation of the same contents as the first embodiment will be omitted.

In addition, the same configuration as the first embodiment will be explained with the same number.

As shown in <FIG>, in the same way as the first embodiment, a ceramic wiring board <NUM> of the present second embodiment is one in which a conductor portion <NUM> that is a wiring layer is formed on the surface of a ceramic board <NUM>.

In this wring board, in the same way as the first embodiment, a lower Cu plated layer <NUM> is formed on the surface of the metallized layer <NUM> through an intermediate layer <NUM>, and an upper Cu plated layer <NUM> is formed on the surface of the lower Cu plated layer <NUM>.

In particular, in the present second embodiment, a Pd plated layer <NUM> made of palladium (Pd) is formed on the surface of the upper Cu plated layer <NUM>, and an Au plated layer <NUM> is formed on the surface of the Pd plated layer <NUM>.

This Pd plated layer <NUM> is formed of electrolytic plating or electroless plating, and its thickness is, for example, <NUM>-<NUM>. In addition, if the thickness of the Pd plated layer <NUM> exceeds <NUM>, there is possibility that solder connectivity deteriorates. It is therefore preferable that the thickness is <NUM> or less.

In the present second embodiment, the same effect as the first embodiment can be obtained, and since the Pd plated layer <NUM> is formed as a base of the Au plated layer <NUM>, there is an advantage that the usage of expensive gold can be reduced.

Next, although a third embodiment will be explained, the explanation of the same contents as the first embodiment will be omitted.

As shown in <FIG>, a non-magnetic wiring board <NUM> in the present third embodiment is one in which a non-magnetic ceramic member <NUM> having a frame shape and made of alumina, and the like are joined on a non-magnetic metal plate <NUM> as a heat sink that is made of, for example, alloy (CuW) of copper and tungsten or alloy (CuMo) of copper and molybdenum.

A non-magnetic coating layer <NUM> is formed on the surface of the metal plate <NUM>. In the same way as the first embodiment, this coating layer <NUM> is equipped with, from a metal plate <NUM> side, a lower Cu plated layer <NUM> (formed by heat treatment of an initial plated layer <NUM>), an upper Cu plated layer <NUM> and an Au plated layer <NUM>.

In addition, a conductor portion <NUM> is formed of the metal plate (that is, a conductor base portion) <NUM> and the coating layer <NUM>.

Moreover, for example, an electronic component <NUM> such as IC and the like is bonded on the surface of the coating layer <NUM> by die bonding with an adhesive layer <NUM>.

In addition, the ceramic member <NUM> is provided with an electrode <NUM>, and it is electrically connected to the electronic component by an Au wire <NUM>.

In the present third embodiment, the same effect as the first embodiment can be obtained.

Claim 1:
A method for manufacturing a wiring board (<NUM>) formed with a non-magnetic conductor portion (<NUM>) having conductivity, the method comprising:
forming a metallized layer (<NUM>) on a surface of a ceramic board (<NUM>), the metallized layer (<NUM>) consisting of at least one of tungsten and molybdenum and a ceramic material composed of alumina and silica;
performing a pre-treatment for removing the silica particles, which are exposed on a part of the surface of the metallized layer (<NUM>), forming open pore portions (<NUM>);
forming an initial Cu plated layer (<NUM>) on the surface of the metallized layer (<NUM>);
performing heating the initial Cu plated layer (<NUM>) to be softened or melted and then cooled to be solidified to form a lower Cu plated layer (<NUM>);
wherein the softened or melted copper of the initial Cu plated layer (<NUM>) enters into the open pore portions (<NUM>) on the surface of the metallized layer (<NUM>) and the lower Cu plated layer (<NUM>) is formed from the initial Cu plated layer (<NUM>); and
forming an upper Cu plated layer (<NUM>) on the surface of the lower Cu plated layer (<NUM>) by plating.