Patent Abstract:
Priorly, semiconductor devices wherein a flexible sheet with a conductive pattern was employed as a supporting substrate, a semiconductor element was mounted thereon, and the ensemble was molded have been developed. In this case, problems occur that a multilayer wiring structure cannot be formed and warping of the insulating resin sheet in the manufacturing process is prominent. In order to solve these problems, a laminated plate  10  formed by laminating a first conductive film  11  and a second conductive film  12  is covered with a photoresist layer PR having opening portions  13  with inclined surfaces  13 S, a conductive wiring layer  14  is formed in the opening portions by electrolytic plating to form inverted inclined surfaces  14 R, and then, when covering the same with the sealing resin layer  21 , an anchoring effect is produced by making the sealing resin layer  21  bite into the inverted inclined surfaces  14 R so as to strengthen bonding of the sealing resin layer  21  with the conductive wiring layer  14.

Full Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a method for manufacturing circuit devices, and particularly, to a method for manufacturing a low-profile circuit device using a conductive wiring layer with an anchoring effect whose circumference has an inverted inclined surface. 
   2. Description of the Related Art 
   In recent years, IC packages have increasingly been used in portable equipment and small-sized high-density mounting equipment, and conventional IC packages and mounting concepts have undergone drastic changes. This has been mentioned in, for example, Japanese Unexamined Patent Publication No. 2000-133678, which is a technique related to a semiconductor device employing a polyimide resin sheet of a flexible sheet as an example of its insulating resin sheet. 
   In FIG.  10  through  FIG. 12 , a flexible sheet  50  is employed as an interposer substrate. Herein, drawings shown in the upper part of the respective drawings are plan views, drawings shown in the lower part are sectional views along a line A—A. 
   First, on the flexible sheet  50  shown in  FIG. 10 , a copper foil pattern  51  is prepared by being adhered via an adhesive. This copper foil pattern  51  is different in its pattern depending on whether a semiconductor element to be mounted is a transistor or an IC, and in general, bonding pads  51 A and an island  51 B are formed. In addition, a symbol  52  shows an opening portion to lead out an electrode from the rear surface of the flexible sheet  50 , and the copper foil pattern  51  is exposed therethrough. 
   Next, this flexible sheet  50  is transferred to a die bonder, and as shown in  FIG. 11 , semiconductor elements  53  are mounted. Thereafter, this flexible sheet  50  is transferred to a wire die bonder, and the bonding pads  51 A and pads of the semiconductor elements  53  are electrically connected by metal wires  54 . 
   Lastly, as in  FIG. 12A , a sealing resin  55  is provided on the front surface of the flexible sheet  50  for sealing. Herein, transfer molding is performed so as to cover the bonding pads  51 A, island  51 B, semiconductor element  53 , and metal wires  54 . 
   Thereafter, as shown in  FIG. 12B , connecting means  56  such as solder or solder balls are provided, and as a result of passing through a solder reflow furnace, spherical solder  56  fusion-bonded with the bonding pads  51 A via the opening portions  52  are formed. In addition, since the semiconductor elements  53  are formed in a matrix shape on the flexible sheet  50 , dicing is performed as in  FIG. 12  to separate the semiconductor elements individually. 
   In addition, in the sectional view shown in  FIG. 12C ,  51 A and  51 D are formed as electrodes on both surfaces of the flexible sheet  50 . In general, this flexible sheet  50  is supplied after patterning of both surfaces by a manufacturer. 
   A semiconductor device using the above-described flexible sheet  50  uses no widely-known metal frame and, therefore, has an advantage such that an extremely small-sized low-profile package structure can be realized, however, substantially, wiring is carried out by only one-layer copper pattern  51  provided on the front surface of the flexible sheet  50 . Therein exists a problem such that, since the flexible sheet is flexible, distortion occurs before and after a pattern formation of a conductive film, and this is not suitable for a multilayer wiring structure since displacement between laminated layers is great. 
   In order to improve supporting strength to suppress the sheet distortion, it is necessary to sufficiently thicken the flexible sheet  50  to approximately 200 μm, and this goes against a reduction in thickness. 
   Furthermore, in terms of a manufacturing method, in the aforementioned manufacturing devices, for example, in the die bonder, wire bonder, transfer molding device, reflow furnace, etc., the flexible sheet  50  is transferred and attached to a part called a stage or a table. 
   However, when the thickness of an insulating resin to serve as a base of the flexible sheet  50  is reduced to approximately 50 μm, if the thickness of the copper foil pattern  51  formed on the front surface is also thin such as 9-35 μm, transferring characteristics are considerably inferior due to warping as shown in  FIG. 13 , and attaching characteristics to the aforementioned stage or table are inferior, therein exists a drawback. This is considered to be warping owing to that the insulating resin itself is considerably thin and warping owing to a difference in the thermal expansion coefficient between the copper foil pattern  51  and insulating resin. 
   In addition, since the part of the opening portions  52  is pressured from the upside during molding, a force to warp the circumferences of the bonding pads  51 A upward can act to deteriorate the bonding pads  51 A in adhesive properties. 
   In addition, if the resin material itself to form a flexible sheet  50  lacks flexibility or if a filler is mixed to enhance thermal conductivity, the flexible sheet  50  becomes rigid. In this condition, when bonding is performed by a wire bonder, the bonding part can crack. In addition, during transfer molding, the part where the metal mold is brought into contact can crack. This appears more prominently if warping exists as shown in FIG.  13 . 
   Although the flexible sheet  50  described above can be a flexible sheet on whose rear surface no electrode is formed, an electrode  51 D can be formed, as shown in  FIG. 12C , on the rear surface of the flexible sheet  50 , as well. In this case, since the electrode  51 D is brought into contact with the manufacturing devices or is brought into contact with the transferring surfaces of transferring means between the manufacturing devices, there exists a problem such that damage occurs to the rear surface of the electrode  51 D. Since the electrode is formed with this damage included, there also exist problems, such that the electrode  51 D itself cracks afterward by a heat application and solder wettability declines in a solder connection to a motherboard. 
   In addition, during transfer molding, a problem also occurs such that a sufficient sealing structure cannot be realized because of weak adhesive properties between the flexible sheet  50 , copper foil pattern  51  and the insulating resin. 
   SUMMARY OF THE INVENTION 
   First, the preferred embodiments include that a method for manufacturing circuit devices comprises: a step for preparing a substrate by laminating a first conductive film and a second conductive film to cover a principle surface of the first conductive film; a step for covering the second conductive film with a photoresist layer in a desirable pattern and having an inclined surface at opening portions; a step for selectively forming a conductive wiring layer at the opening portions of the photoresist layer and providing an inverted inclined surface around the conductive wiring layer; a step for removing the second conductive film by use of the conductive wiring layer as a mask; a step for fixedly fitting semiconductor elements on the first conductive film and electrically connecting electrodes of the semiconductor elements with predetermined parts of the conductive wiring layer; a step for covering the semiconductor elements with a sealing resin layer and making the sealing resin layer produce an anchoring effect at the inverted inclined surface of the conductive wiring layer; and a step for removing the first conductive film to expose the second conductive film positioned on the rear surface of the sealing resin layer and the conductive wiring layer. In particular, the preferred embodiments include that by forming inverted inclined surfaces around the conductive wiring layer by making use of inclined surfaces of the opening portions of the photoresist layer, an anchoring effect of the sealing resin layer is provided. 
   Second, the preferred embodiments include that the second conductive film is formed by silver electroplating. 
   Third, the preferred embodiments include that the photoresist layer is heat-treated after development so as to form an inclined surface at the opening portions. 
   Fourth, the preferred embodiments include that, as the photoresist layer, a positive photoresist layer is used, and an inclined surface is formed by use of inferior resolution during development. 
   Fifth, the preferred embodiments include that the conductive wiring layer is formed at the opening portion by copper electroplating while using the first conductive film as an electrode. 
   Sixth, the preferred embodiments include that an etching solution for the second conductive film is an iodine-based solution. 
   Seventh, the preferred embodiments include that the second conductive film and the sealing resin layer remaining when the first conductive film is etched are used as an etching stopper. 
   Eighth, the preferred embodiments include that a solution containing ferric chloride or cupric chloride is used as a solution to perform the etching. 
   Ninth, the preferred embodiments include that external electrodes are formed by adhering a brazing filler material to the remaining second conductive film. 
   According to the preferred embodiments, in the step for forming a conductive wiring layer, by forming inverted inclined surfaces on the conductive wiring layer by making use of inclined surfaces of a photoresist layer, an anchoring effect between the conductive wiring layer and sealing resin layer can be strengthened, therefore, an advantage is provided such that biting between the sealing resin layer and insulating wiring layer is strengthened to realize a satisfactory sealing condition. 
   In addition, anchor portions can be formed in self-alignment by the second conductive film depressed around the second conductive film by overetching the second conductive film by use of the conductive wiring layer as a mask, and these anchor portions are filled when the semiconductor elements are covered with the sealing resin layer later, therefore, an advantage is provided such that biting between the sealing resin layer and conductive pattern layer can be further strengthened. 
   Furthermore, when the first conductive film is entirely removed, the second conductive film functions as a barrier layer to etching with the sealing resin layer, therefore, an advantage is provided such that removal of the first conductive film without a mask can be made possible. 
   Furthermore, since the second conductive film forms a flat rear surface along with the sealing resin layer, either the land grid array structure or ball grid array structure can be employed, therefore, an advantage is provided such that the remaining third conductive film itself can construct the whole or part of the external electrodes. 

   
     DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 2  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 3  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 4  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 5  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 6  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 7  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 8  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 9  is a sectional view for explaining a method for manufacturing circuit devices of the preferred embodiments; 
       FIG. 10  is a view for explaining a conventional method for manufacturing semiconductor devices; 
       FIG. 11  is a view for explaining a conventional method for manufacturing semiconductor devices; 
       FIG. 12  is a view for explaining a conventional method for manufacturing semiconductor devices; 
       FIG. 13  is a view for explaining a conventional flexible sheet. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   A method for manufacturing circuit devices of the preferred embodiments will be described in detail with reference to FIG.  1  through FIG.  9 . 
   A method for manufacturing circuit devices comprises: a step for preparing a substrate  10  by laminating a first conductive film  11  and a second conductive film  12  to cover a principle surface of the first conductive film  11 ; a step for covering the second conductive film  12  with a photoresist layer PR in a desirable pattern and having an inclined surface  13 S at opening portions  13 ; a step for selectively forming a conductive wiring layer  14  at the opening portions  13  of the photoresist layer PR and providing an inverted inclined surface  14 R around the conductive wiring layer  14 ; a step for removing the second conductive film  12  by use of the conductive wiring layer  14  as a mask; a step for fixedly fitting semiconductor elements  17  on the first conductive film  11  and electrically connecting electrodes of the semiconductor elements  17  with predetermined parts of the conductive wiring layer  14 ; a step for covering the semiconductor elements  17  with a sealing resin layer  21  and making the sealing resin layer  21  produce an anchoring effect at the inverted inclined surface  14 R of the conductive wiring layer  14 ; and a step for removing the first conductive film  11  to expose the second conductive film  12  positioned on the rear surface of the sealing resin layer  21  and the conductive wiring layer  14 . Such respective steps will be described in the following. 
   The first step of the preferred embodiments can be, as shown in  FIG. 1 , for preparing a substrate  10  by laminating a first conductive film  11  and a second conductive film  12  to cover a principle surface of the first conductive film  11 . 
   On the front surface of the laminated plate  10 , the first conductive film  11  is formed substantially throughout the whole area, and on the front surface thereof, the second conductive film  12  is formed. The first conductive film  11  is, preferably, made of Cu as a main material or is made of a widely-known lead frame material. The first conductive film  11  and second conductive film  12  can be formed by a plating method, an evaporation method, or a sputtering method, or a metal foil formed by a rolling method or a plating method can be adhered to the same. Moreover, as the first conductive film  11 , Al, Fe, Fe—Ni, a widely-known lead frame material and the like can be employed. 
   As the material of the second conductive film  12 , a material is employed which is not etched by an etchant used when the first conductive film  11  is removed. In addition, since external electrodes  24  of solder or the like are formed on the rear surface of the second conductive film  12 , adhesion of the external electrodes  24  is also considered. Concretely, a conductive material composed of gold, silver, and palladium can be employed as a material of the second conductive film  12 . 
   The first conductive film  11  is formed thick in thickness to mechanically support the ensemble, and the thickness is approximately 35-150 μm. The second conductive film  12  functions as a barrier layer when the first conductive film  11  is etched, and is formed with a thickness of approximately 2-20 μm. Accordingly, by forming the first conductive film  11  thick, flatness of the laminated plate  10  can be maintained, whereby, workability in the following steps can be improved. 
   Furthermore, the first conductive film  11  is damaged through various steps. However, the first conductive film  11  is to be removed in a later step, so that damage is prevented from remaining in a circuit device of a finished product. In addition, since the sealing resin can be hardened while flatness is maintained, the rear surface of a package can also be flattened, and the external electrodes formed on the rear surface of the laminated plate  10  can also be arranged flat. Therefore, electrodes on a mounting substrate can be brought into contact with the electrodes on the rear surface of the laminated plate  10 , whereby a soldering failure can be prevented. 
   Next, a concrete manufacturing method for the aforementioned laminated plate  10  will be described. A laminated plate  10  can be manufactured by lamination, electroplating or rolling . When a laminated plate  10  is manufactured by electroplating, first, a first conductive film  11  is prepared. Then, electrodes are provided on the rear surface of the first conductive film  11  , and a second conductive film  12  is laminated by an electrolytic plating method. When a laminated plate is manufactured by rolling, a first conductive film  11  and a second conductive film  12  which have been prepared in a plate shape are joined under pressure by a roll or the like. 
   The second step of the preferred embodiments can be, as shown in  FIG. 2 , for covering the second conductive film  12  with a photoresist layer PR in a desirable pattern and having an inclined surface  13 S at opening portions  13 . 
   In this step, as shown in  FIG. 1 , exposure and development are carried out to form opening portions  13  into a desirable pattern shape after the second conductive layer  12  is covered with a photoresist layer PR, whereby the photoresist layer PR at parts corresponding to the opening portions  13  are removed with a developer. 
   Next, as shown in  FIG. 2 , an inclined surface  13 S is formed at the opening portions  13  of the photoresist layer PR. According to a first method, the photoresist layer PR after development is heat-treated to become 120-180° C. so as to form upwardly inclined surfaces  13 S. According to the second method, by using a positive photoresist material as a photoresist layer PR, inclined surfaces  13 S are formed, which are upwardly expanded and inclined, as a result of development of an inferior resolution. 
   The third step of the preferred embodiments can be, as shown in FIG.  3  and  FIG. 4 , for selectively forming a conductive wiring layer  14  at the opening portions  13  of the photoresist layer PR and providing an inverted inclined surface  14 R around the conductive wiring layer  14 . 
   While using the first conductive film  11  as a common electrode, a conductive wiring layer  14  is formed by selectively electroplating the opening portions  13  of the photoresist layer PR with copper. At this time, the photoresist layer PR functions as a mask, whereby a conductive wiring layer  14  is formed in a desirable pattern on the second conductive film  12  where the opening portions  13  are exposed. This conductive wiring layer  14  is formed with a thickness of approximately 20 μm so as to fill up the opening portions  13  of the photoresist layer PR, and at the circumference of the conductive wiring layer  14  to be brought into contact with the photoresist layer PR, an inverted inclined surface  14 R is formed with an inverted inclination to the inclined surface  13 S. In addition, for the conductive wiring layer  14 , Cu has been herein employed, however, Au, Ag, Pd and the like can be employed. 
   Furthermore, as shown in  FIG. 4 , pads  15 A composed of the third conductive film  15  are selectively formed on the conductive wiring layer  14 . The conductive wiring layer  14  excluding regions to form pads is covered with the photoresist layer PR, a nickel base plating is applied, and then electrolytic plating is performed with gold or silver to form pads  15 A. Furthermore, at this time, the rear surface of the first conductive film  11  is covered with a photoresist layer PR or an overcoat resin to prevent pads from being formed. 
   The fourth step of the preferred embodiments can be, as shown in  FIG. 5 , for removing the second conductive film  12  by use of the conductive wiring layer  14  as a mask. 
   In this step, the photoresist layer PR is removed, and the second conductive film  12  is selectively removed by etching by use of the conductive wiring layer  14  as a maskEtchant used in this step is an etchant which etches the second conductive film  12  and does not etch the conductive wiring layer  14 . That is, in a case where the conductive wiring layer  14  is formed of a material mainly of Cu and the second conductive film  12  is silver, only the second conductive film  12  can be removed by using an iodine-based etchant. In a case where the pads  15 A are formed of silver, since pads  15 A can be removed by this etching, it is necessary to cover pads  15 A with a photoresist layer (unillustrated) for protection. 
   The second conductive film  12  herein remaining is to be used as external electrodes  24 . 
   The fifth step of the preferred embodiments can be, as shown in  FIG. 6 , for fixedly fitting semiconductor elements  17  on the first conductive film  11  and electrically connecting electrodes of the semiconductor elements  17  with predetermined parts of the conductive wiring layer  14 . 
   The semiconductor elements  17  are, in the state of bare chips, die-bonded onto the first conductive film  11  with insulating adhesive resin  18 . 
   In addition, the respective electrode pads of the semiconductor element  17  are connected to the pads  15 A provided at predetermined positions of the surrounding conductive wiring layer  14  via bonding wires  19 . The semiconductor element  17  can be mounted face-down. In this case, solder balls or bumps are provided on the front surfaces of the respective electrode pads of the semiconductor element  17 , while on the front surface of the laminated plate  10 , electrodes similar to the bonding pads of the conductive wiring layer  14  are provided at parts corresponding to the solder ball positions. 
   Now, an advantage of using the laminated plate  10  in wire bonding will be described. In general, when wire bonding is carried out with Au wires, this is heated to become 200° C.-300° C. At this time, if the first conductive film  11  is thin, the laminated plate  10  warps, and in this condition, if the laminated plate  10  is pressurized via a bonding head, there is a possibility that damage occurs to the laminated plate  10 . However, these problems can be solved by forming the first conductive film  11  itself thick. 
   The sixth step of the preferred embodiments can be, as shown in  FIG. 7 , for covering the semiconductor elements  17  with a sealing resin layer  21  and making the sealing resin layer  21  produce an anchoring effect at the inverted inclined surface  14 R of the conductive wiring layer  14 . 
   The laminated plate  10  is set in a molding device for resin molding. As a molding method, transfer molding, injection molding, coating, dipping and the like can be carried out. However, considering productivity, transfer molding and injection molding can be suitable. 
   In this step, when performing molding with the sealing resin layer  21 , the sealing resin layer  21  is filled into the inverted inclined surface  14 R of the conductive wiring layer  14  formed on the front surface of the first conductive film  11 , therein exists an advantage such that bonding between the sealing resin layer  21  and conductive wiring layer  14  is strengthened by an anchoring effect. 
   In addition, in this step, it is necessary that the laminated plate  10  is brought into contact flat against a lower metal mold of a mold cavity, and the thick, first conductive film  11  performs this function. Moreover, even after removal from the mold cavity, flatness of the package is maintained by the first conductive film  11  until contraction of the sealing resin layer  21  is completely finished. Namely, a role is played of mechanically supporting the laminated plate  10  until this step is assumed by the first conductive film  11 . 
   The seventh step of the preferred embodiments can be, as shown in  FIG. 8 , for removing the first conductive film  11  to expose the second conductive film  12  positioned on the rear surface of the sealing resin layer  21  and the conductive wiring layer  14 . 
   In this step, the first conductive film  11  is etched without masking so that the whole surface is removed. In this etching, chemical etching by use of ferric chloride or cupric chloride is sufficient, and the first conductive film  11  is entirely removed. By entirely removing the first conductive film  11 , the remaining second conductive film  12  is exposed through the sealing resin layer  21 . As described above, since the second conductive film  12  is formed of a material which is not etched by a solution to etch the first conductive film  11 , the second conductive film  12  is not etched in this step. 
   This step includes that when the first conductive layer  11  is removed by etching, the sealing resin layer  21  and the second conductive film  12  functions as a barrier layer even without using a mask, therefore, a rear surface composed of the sealing resin layer  21  and second conductive film  12  is formed flat. Since the first conductive film  11  is entirely removed by etching, the second conductive film  12  also comes into contact with the etchant in the final stage of etching. As described above, the second conductive film  12  is formed of a material which is not etched by ferric chloride or cupric chloride to etch the first conductive film  11  made of Cu. Accordingly, since etching stops at the lower surface of the second conductive film, the second conductive film  12  functions as an etching barrier layer. Moreover, in and after this step, the ensemble is mechanically supported by the sealing resin layer  21 . 
   The last step of the preferred embodiments can be, as shown in  FIG. 9 , for forming a land grid array structure or a ball grid array structure. 
   For a land grid array structure, in the previous step where the first conductive film  11  has been entirely removed, the second conductive film  12  excluding parts to become external electrodes  24  is covered with an overcoat resin  23 , and the sealing resin layer  21  and overcoat resin  23  are diced to separate these into individual circuit devices. 
   For a ball grid array structure, the second conductive film  12  is, for the most part, covered with an overcoat resin  23  by screen-printing with an epoxy resin dissolved in a solvent while exposing parts to form external electrodes  24 . Next, by screen printing with a solder cream and a solder reflow, protruded external electrodes  24 B are formed in these exposed parts. Subsequently, since a large number of circuit devices are formed on the laminated plate  10  in a matrix shape, these are separated into individual circuit devices by dicing the sealing resin layer  21  and overcoat resin  23 . 
   In this step, since the circuit devices can be separated into individual circuit devices by dicing the sealing resin layer  21  and overcoat resin  23 , frictional wear of a dicer to perform dicing can be reduced.

Technology Classification (CPC): 8