Patent Publication Number: US-2009236603-A1

Title: Process for forming a wiring film, a transistor, and an electronic device

Description:
This is a Continuation of International Application No. PCT/JP2007/74930 filed on Dec. 26, 2007, which claims priority of Japan Patent Document No. 2006-354858 filed on Dec. 28, 2006. The entire disclosures of the prior applications are incorporated by references herein in their entireties. 
    
    
     BACKGROUND 
     The present invention generally relates to the field of wiring film, and more particularly, the invention relates to a wiring film for transistors and a process for forming such a wiring film. 
     Heretofore, low-resistance materials (such as, Al, Cu, etc.) have been used in metallic wiring films for electric parts. For instance, in the case of the TFT (thin film transistor) liquid crystal displays, a demand for the reduction in the resistance of the wiring electrodes has been increasing with the enlargement of the panels, and the necessity for using Al and Cu as the low-resistance wirings has been growing. 
     When an Al wiring composed mainly of Al contacts an oxide (such as, SiO2, ITO (indium tin oxide) or the like), hillock can be formed with oxygen of the oxide. In addition, when the Al wiring is used as source and drain electrodes of a TFT, there are problems of diffusion into an underlying Si layer and a degradation in a contact resistance between a transparent electrode made of ITO. 
     On the other hand, as to the Cu wiring, Cu is a material having a lower resistance than that of Al. Although degradation in the contact resistance between Al and the ITO transparent electrode poses a problem, Cu exhibits an excellent contact resistance because Cu is more difficult to be oxidized than Al. 
     Therefore, a need to use Cu for low-resistance wiring films has been increasing. However, as compared to other wiring materials, there are problems in that Cu has poor adhesion to underlying materials (such as glass, Si or the like), and Cu diffuses into the Si layer when it is used as the source and drain electrodes. Thus, a barrier layer is required at an interface between the Cu wiring and other layers so as to enhance the adhesion and prevent the diffusion. 
     Regarding an underlying Cu seed layer made of a Cu plating, which is used in a semiconductor, a barrier layer is required to prevent the diffusion of TiN, TaN or the like from the same above-mentioned diffusion problem. 
     As to related patents on metallic wiring films composed mainly of Cu for electronic parts, a technique characterized by adding an element such as Mo or the like into Cu (JP-A 2005-158887) and a technique characterized by introducing nitrogen or oxygen during a film-forming process by sputtering pure Cu (JP-A 10-12151) are known. However, both of the above-mentioned conventional techniques have problems in reducing resistance, etc. 
     SUMMARY OF THE INVENTION 
     The present invention has been accomplished to solve the above-mentioned problems, and its object is to provide a low-resistance wiring film having high adhesion to the glass substrate and the silicon layer. 
     The present invention is directed to a wiring film-forming process for forming a wiring film on a surface of an object to form a film thereon to which a silicon or a silicon dioxide is exposed, the wiring film-forming process including the steps of: introducing an oxide gas and a sputtering gas into a vacuum atmosphere in which the object to form a film thereon is disposed, sputtering a first pure copper target in the vacuum atmosphere including oxygen, forming a barrier film on a surface of the object to form a film thereon, thereafter sputtering a second pure copper target in a state such that the introduction of oxygen gas into a vacuum atmosphere in which the object to form a film thereon is disposed is stopped, forming a low-resistance film on a surface of the barrier film, etching the barrier film and the low-resistance film, and thereby forming the wiring film. 
     The present invention is directed to a wiring film-forming process, wherein an identical target is used as the first and second pure targets, and the formation of the barrier film and the formation of the low-resistance film are performed inside the same vacuum chamber. 
     The present invention is directed to a wiring film-forming process, wherein the barrier film is formed by sputtering the first pure copper target, with an oxygen gas introduced such that a ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas in the vacuum atmosphere is at least 3.0%. 
     The present invention is directed to a wiring film-forming process, wherein after the low-resistance film is formed, the oxygen gas and the sputtering gas are introduced into the vacuum atmosphere in which the object to form a film thereon is disposed, an adhering film is formed on a surface of the low-resistance film by sputtering a third pure copper target in a vacuum atmosphere including oxygen, and thereafter the wiring film is formed by etching the barrier film, the low-resistance film and the adhering film. 
     The present invention is directed to a wiring film-forming process, wherein a same target is used as the first to third pure copper targets, and wherein the formation of the barrier film, the formation of the low-resistance film and the formation of the adhering film are performed inside a same vacuum chamber. 
     The present invention is directed to a wiring film-forming process, wherein discrete targets are used as the first to third pure copper targets, and wherein the formation of the barrier film, the formation of the low-resistance film and the formation of the adhering film are performed inside discrete vacuum chambers. 
     The present invention is directed to a wiring film-forming process, wherein an identical target is used as the first and third pure copper targets, another target, different from that used as the first and third pure copper targets, is used as the second pure copper target, the formation of the barrier film and the formation of the adhering film are performed in the same vacuum chamber, and the formation of the low-resistance film is performed in another vacuum chamber, which is different from the vacuum chamber used for the formation of the barrier film and the adhering film. 
     The present invention is directed to a transistor, comprising a gate electrode, and a drain semiconductor layer and a source semiconductor layer composed of semiconductors, respectively, wherein the drain semiconductor layer and the source semiconductor layer being configured to be cut off or electrically turned on therebetween by applying a voltage to the gate electrode, wherein a barrier film having copper as a main component and including oxygen is formed on at least one of the surfaces of the drain semiconductor layer and that of the source semiconductor layer, and a low-resistance film including copper as a main component and having a resistance lower than that of the barrier film is formed on a surface of the barrier film. 
     The present invention is directed to a transistor, wherein an adhering film, including copper as a main component and including oxygen, is formed on either one or both surfaces of the low-resistance film on the source semiconductor film and the low-resistance film on the drain semiconductor layer. 
     The present invention is directed to a transistor having a gate electrode, a drain semiconductor layer composed of a semiconductor, and a source semiconductor electrode composed of a semiconductor, the drain semiconductor layer and the source semiconductor layer being configured to be cut off or electrically turned on therebetween by applying a voltage to the gate electrode, and the gate electrode contacting a glass substrate, wherein the gate electrode has a barrier film formed on a surface of the glass substrate and a low-resistance film formed on a surface of the barrier film, wherein the barrier film has copper as a main component and includes oxygen, and wherein the low-resistance film has copper as a main component and has a resistance lower than that of the barrier film. 
     The present invention is directed to an electronic device having a transistor, the transistor having a gate electrode, a drain semiconductor layer and a source semiconductor layer composed of semiconductors, respectively, the drain semiconductor layer and the source semiconductor layer being configured to be cut off or electrically turned on therebetween by applying a voltage to the gate electrode, wherein a barrier film having copper as a main component and including oxygen is formed on at least one of the surfaces of the drain semiconductor layer and the source semiconductor layer, and a low-resistance film having copper as a main component and having a resistance lower than that of the barrier film is formed on a surface of the barrier film. 
     The present invention is directed to an electronic device comprising a transistor, the transistor having a gate electrode, a drain semiconductor layer composed of a semiconductor and a source semiconductor layer composed of a semiconductor, the drain semiconductor layer and the source semiconductor layer being configured to be cut off or electrically turned on therebetween by applying voltage to the gate electrode, and the gate electrode contacting a glass substrate, wherein the gate electrode has a barrier film formed on a surface of the glass substrate and a low-resistance film formed on a surface of the barrier film, wherein the barrier film has copper as a main component and includes oxygen, and wherein the low-resistance film has copper as a main component and has a resistance lower than that of the barrier film. 
     The present invention is directed to an electronic device having a glass substrate, a transparent pixel electrode arranged on the glass substrate, liquid crystals disposed on the pixel electrode, a transparent common electrode arranged on the liquid crystals, and a storage electrode tightly adhered to the glass substrate, wherein a storage capacity having the storage electrode as a one-side electrode is connected to a liquid crystal capacity formed between the pixel electrode and the storage electrode, and the orientation of the liquid crystals is controlled by charging and discharging the liquid crystal capacity, wherein the storage electrode has a barrier film formed on a surface of the glass substrate and a low-resistance film formed on a surface of the barrier film, wherein the barrier film has copper as a main component and includes oxygen, and wherein the low-resistance film has copper as a main component and has a resistance lower than that of the barrier film. 
     In the present invention, the term “main” in “main component” means that the element as this main component is contained at not less than 50 atomic %. Therefore, “copper as a main component” means “copper atoms are contained at not less than 50 atomic %”. 
     An element (for example, Mn, Mg or the like) other than Cu may however be mixed in the pure copper target used in the present invention as an impurity. The content of the impure element is less than 0.1 atomic %, and ordinarily less than 10 −4  atomic %. In the wiring film of the present invention formed by using such a pure copper target, the content of the impurity other than Cu and oxygen is less than 0.1 atomic %, and ordinarily less than 10 −4  atomic %. 
     The wiring film formed by the present invention has high adhesion to silicon and glass, and has low resistance. Since the patterning in forming the wiring film can be performed by patterning the barrier film and the low-resistance film with an identical etchant at a time, the production steps in forming the wiring film of the present invention are simple. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a sectional view for illustrating one embodiment of a sputtering apparatus to be used in the present invention. 
         FIGS. 2(   a ) to ( e ) are sectional views for illustrating one example of steps of forming the wiring film of the present invention. 
         FIG. 3  is a sectional view for illustrating one embodiment of the liquid crystal display device of the present invention. 
         FIG. 4  is a sectional view for illustrating one embodiment of the semiconductor device of the present invention. 
         FIGS. 5(   a ) and ( b ) are sectional views for illustrating another example of steps of forming the wiring film of the present invention. 
         FIG. 6  is a sectional view for illustrating a second embodiment of the sputtering apparatus. 
         FIG. 7  is a sectional view for illustrating a third embodiment of the sputtering apparatus. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In  FIG. 1 , a reference numeral  1  denotes a first embodiment of a sputtering apparatus to be used in the present invention. 
     This sputtering apparatus  1  has a vacuum chamber  2 ; and a pure copper target  11  is arranged inside the vacuum chamber  2 . The content of impurity elements other than copper in the pure copper target  11  is less than 0.1 atomic %. 
     In  FIG. 2(   a ), a reference numeral  21  denotes an object to form a film thereon; and a surface of a semiconductor area or a glass substrate is exposed at a surface thereof. 
     A vacuum evacuation system  9  and a gas introduction system  8  are connected to the vacuum chamber  2 ; the interior of the vacuum chamber  2  is evacuated to a vacuum state by the vacuum evacuation system  9 ; the object  21  to form a film thereon is carried therein in the state of an vacuum atmosphere; and the object is held by a substrate holder  7  arranged inside the vacuum chamber  2 . 
     A sputtering gas source and an oxygen gas source are connected to the gas introduction system  8  such that a sputtering gas and an oxygen gas may be introduced into the vacuum chamber  2 , while the flow rates are being controlled. 
     A sputtering electric power source  5  is connected to the pure copper target  11 . After the interior of the vacuum chamber  2  is evacuated to vacuum, the sputtering gas or both the sputtering gas and the oxygen gas are introduced from the gas introduction system  8 . When a voltage is applied to the pure copper target  11  by the sputtering electric power source  5 , a plasma of the introduced gas is formed near the surface of the pure copper target  11 . 
     When the pure copper target  11  is sputtered with the plasma, copper atoms or fine copper particles made of atom groups are emitted toward the object  21  to form a film thereon. When they reach a surface of the object  21  to form a film thereon, they react with oxygen, a barrier film  22  made of copper and copper oxide is formed on a surface of the object  21  to form a film thereon as shown in  FIG. 2(   b ). 
     The barrier film  22  is grown by sputtering the pure copper target  11 , while oxygen is being introduced. When the barrier film  22  is formed in a film thickness of 10 nm or more, the introduction of the oxygen gas is stopped. While the vacuum evacuation and the introduction of the sputtering gas are continued, a low-resistance film  23  of pure copper is formed on a surface of the barrier film  22  by sputtering the same pure copper target  11  with the sputtering gas ( FIG. 2(   c )). 
     When the low-resistance film  23  is formed in a predetermined film thickness, the object  21  to form a film thereon is carried out of the sputtering apparatus  1 . As shown in  FIG. 2(   c ), a laminated film  24  having the barrier film  22  and the low-resistance film  23  is formed on the surface of the object  21  to form a film thereon. The barrier film  22  tightly adheres to the surface of the semiconductor area or the glass substrate being exposed at the surface of the object  21  in order to form a film thereon; and the low-resistance film  23  is disposed on the surface of the barrier film. 
     Next, when a patterned resist film  26  is disposed on a surface of the laminated film  24  as shown in  FIG. 2(   d ) and the laminated film  24  exposed at bottom faces of the resist film  26  are subjected to an etching liquid or an etching gas of a weak acid or the like, a patterned wiring film  25  is formed as shown in  FIG. 2(   e ). 
     The sectional shape of this wiring film  25  is a trapezoidal shape with taper portions, in which the width of a bottom face side is longer than that of an upper portion. 
     Since the barrier film  22  and the low-resistance film  23  are made of copper or both copper and copper oxide, they can be etched with the etching liquid (or an etching gas) having the same composition, so that it is unnecessary to again arrange a new resist film in etching the barrier film  22 . 
     In the above embodiment, although the barrier film  22  and the low-resistance film  23  are formed inside the vacuum chamber  2  of the same sputtering apparatus  1 , the present invention is not limited thereto. As shown in  FIGS. 6 and 7 , discussed later, the barrier film  22  and the low-resistance film  23  may be formed by sputtering separate targets in different vacuum chambers. 
     However, if the barrier film  22  and the low-resistance film  23  are continuously formed inside the same sputtering apparatus  1 , the film quality is improved since neither the barrier film  22  nor the low-resistance film  23  is exposed to the atmosphere. 
     The above-mentioned object  21  to form a film thereon is a TFT substrate or a substrate to be used in a semiconductor device, as discussed later; and a glass substrate, silicon or the like is exposed at a part or an entire part of the surface thereof. 
     Adhesion of the barrier film  22  made of copper and copper oxide to the glass substrate or the semiconductor area is higher than adhesion of a thin film of pure copper to the glass substrate or the semiconductor area (silicon single crystal, polycrystal or the like). 
     In the present invention, the low-resistance film  23  is firmly connected onto the glass substrate or the semiconductor area by the barrier film  22 ; and it is thus hardly peeled. 
     The diffusion amount of copper into silicon oxide or the semiconductor area is larger when a thin film of pure copper (low-resistance film) is disposed on the barrier film  22  made of copper oxide and copper than the diffusion amount of copper into silicon oxide or the semiconductor area when a barrier film is formed of a high melting point metal (such as Ti, W or the like) and a thin film of pure copper is formed thereon, but smaller when the pure copper film is disposed in contact with the silicon oxide or the semiconductor area without the provision of the barrier film  22 . Therefore, the wiring film formed by the present invention can also be a low-resistance wiring film in the semiconductor device field. 
     In the case of a liquid crystal display device having a transparent electroconductive film of an oxide (such as, ITO, ZnO or the like), after the above-mentioned low-resistance film  23  of pure copper is formed, an adhering film  29  composed of copper oxide and copper is formed in a film thickness of 10 nm or more on the low-resistance film  23  by sputtering the pure copper target  11 , while oxygen is being introduced into the vacuum atmosphere in which the pure copper target  11  is arranged ( FIG. 5(   a )). A transparent electroconductive film of an oxide can be disposed tightly adhering to this adhering film  29 . 
     In such a case, since oxygen is contained in the adhering film  29 , the oxygen in the transparent oxide electroconductive film is prevented from diffusing into the low-resistance layer  23 . 
     Since the adhering film  29  is made of copper and copper oxide similar to the makeup of the barrier film  22 , the adhering film  29  can be etched with the same etchant (etching liquid or etching gas) as in the case of the barrier film  22  and the low-resistance film  23 . Consequently, a patterned wiring film  27  can be formed by etching a laminated film  28  composed of the barrier film  22 , the low-resistance film  23  and the adhering film  29  ( FIG. 5(   b )). 
     In the above discussions, explanation has been provided for the case where the barrier film  22 , the low-resistance film  23  and the adhering film  29  are formed by sputtering the same pure copper target  11  in the same vacuum chamber  2 , but the present invention is not limited thereto. 
     In  FIG. 6 , a reference numeral  80  denotes a second embodiment of the sputtering apparatus, whereas a reference numeral  90  in  FIG. 7  denotes a third embodiment of the sputtering apparatus. The second and third embodiments of the sputtering apparatus  80 ,  90  comprise a first vacuum chamber  2   a , a second vacuum chamber  2   b  connected to the first vacuum chamber  2   a , a first pure copper target  11   a  arranged inside the first vacuum chamber  2   a , and a second pure copper target  11   b  arranged inside the second vacuum chamber  2   b.    
     The following description pertains to the steps for forming a laminated film for a wiring film by using the second and third embodiments of the sputtering apparatuses  80 ,  90 . 
     First, a vacuum atmosphere is formed inside the first and second vacuum chambers  2   a ,  2   b  by the vacuum evacuation system  9 . While the vacuum atmosphere is being maintained, an object  21  having a film to be formed thereon is carried into the first vacuum chamber  2   a , and held by a substrate holder  7   a.    
     While vacuum evacuation is being continued, the sputtering gas and the oxygen gas are introduced into the first vacuum chamber  2   a  from the gas feeding system  8 , a voltage is applied to the first pure copper target  11   a  from an electric power source  5 , and a barrier film  22  is formed by sputtering the first pure copper target  11   a  in the vacuum atmosphere containing oxygen. 
     The object  21  with the barrier film  22  formed thereon is carried from the first vacuum chamber  2   a  into the second vacuum chamber  2   b , and held by a substrate holder  7   b . While the interior of the second vacuum chamber  2   a  is being evacuated to vacuum, the sputtering gas is introduced, and a low-resistance film  23  is formed by sputtering the second pure copper target  11   b  in the vacuum atmosphere containing no oxygen. 
     When an adhering film  29  is further to be formed on a surface of the low-resistance layer  23 , the object  21  with the low-resistance film  23  formed thereon is returned from the second vacuum chamber  2   b  to the first vacuum chamber  2   a  in the case of the second embodiment of the sputtering apparatus  80 . While the interior of the first vacuum chamber  2   a  is being evacuated to vacuum, the sputtering gas and the oxygen gas are introduced; and the adhering film  29  is formed by sputtering the first pure copper target  11   a  in the vacuum chamber containing oxygen. 
     On the other hand, in the third embodiment of the sputtering apparatus  90 , a third vacuum chamber  2   c  is connected to the second vacuum chamber  2   a ; and the object  21  formed with the low-resistance film  23  is carried from the second vacuum chamber  2   b  into the third vacuum chamber  2   c , and held by a substrate holder  7   c.    
     A third pure copper target  11   c  is arranged inside the third vacuum chamber  2   c . While the inside of the third vacuum chamber  2   c  is being evacuated to vacuum, the sputtering gas and the oxygen gas are introduced, and an adhering film  29  is formed by sputtering the third pure copper target  11   c  in the vacuum atmosphere containing the oxygen gas. 
     In the second and third embodiments of the sputtering apparatuses  80 ,  90 , different vacuum atmospheres (the vacuum atmosphere containing oxygen and the atmosphere containing no oxygen) are formed inside the separate vacuum chambers  2   a  to  2   c . Accordingly, it does not take a long time to perform the vacuum evacuation until a next film is formed after the formation of one film is terminated, as compared to the sputtering apparatus  1  of the first embodiment in which the different vacuum atmospheres are alternately formed in the same vacuum chamber  2 . 
     Further, in order to lower the resistance of the entire wiring film  27 , the low-resistance film  23  is made thicker than the barrier film  22  and the adhering film  29 . Therefore, the film-forming time period for the low-resistance film  23  is longer than the film-forming time period for the barrier film  22  and the adhering film  29 . If a film requiring a longer film-forming time period is formed in an exclusive vacuum chamber as in the second and third embodiments of the sputtering apparatuses  80 ,  90 , the productivity is enhanced. 
     Further, if, as in the third embodiment of the sputtering apparatus  90 , the number of the vacuum chambers  2   a  to  2   c  is the same as that of the copper films constituting the wiring film  27  and the respective copper films are formed in the exclusive vacuum chambers  2   a  to  2   c , the productivity is further enhanced. 
     As to the second embodiment of the sputtering apparatus  80 , the first and second vacuum chambers  2   a ,  2   b  may be directly connected as shown in  FIG. 6 , or in the alternative, the first and second vacuum chambers  2   a ,  2   b  may be connected to the same transfer chamber so that the object  21  to form a film thereon may be carried in and out between the first and second vacuum chambers  2   a ,  2   b  via the transfer chamber. 
     Meanwhile, as to the third embodiment of the sputtering apparatus  90 , the first to third vacuum chambers  2   a  to  2   c  may be connected in series as shown in  FIG. 7  so that the object  21  having a film to be formed thereon may be transferred from the first vacuum chamber  2   a  to the third vacuum chamber  2   c  via the second vacuum chamber  2   b . Alternatively, the first to third vacuum chambers  2   a  to  2   c  may be connected to the same transfer chamber so that the object  21  for a film to be formed thereon may be carried in and out among the first to third vacuum chambers  2   a  to  2   c  via the transfer chamber. 
     In any of the above-mentioned cases, since the object  21  to form a film thereon moves between or among the vacuum chambers without contacting the atmosphere, the wiring films  25 ,  27  having a good film quality are obtained. 
     Next, one embodiment of the electronic device according to the present invention will be explained. 
     In  FIG. 3 , a reference numeral  3  denotes an electronic device (liquid crystal display device) with a wiring film of the present invention, which has a TFT substrate  30  and a color substrate  50 . 
     This liquid crystal display device  3  is an active type; the TFT substrate  30  has a glass substrate  31 ; and a TFT (thin film transistor)  40 , a display pixel  35 , and a storage condenser  39  are disposed on the glass substrate  31 . 
     The TFT  40  has a gate electrode  41 , a drain electrode  42  and a source electrode  43 ; the storage condenser  39  has a storage electrode  38 ; and the display pixel  35  has a pixel electrode  36 . The gate electrode  41 , the drain electrode  42 , the source electrode  43  and the storage electrode  38  are constituted with wiring films  25 ,  27 , as explained above. 
     Further, the TFT  40  has a gate insulating film  44 , a channel semiconductor layer  46 , a drain semiconductor layer  47  and a source semiconductor layer  48 . 
     The drain semiconductor layer  47  and the source semiconductor layer  48  are arranged apart from each other and in contact with one face of the channel semiconductor layer  46 . The gate insulating film  44  and the gate electrode  41  are arranged at that face on a side opposite to the channel semiconductor layer  46  in a position between the drain semiconductor layer  47  and the source semiconductor layer  48 . 
     The drain electrode  42  and the source electrode  43  are arranged in contact with the surfaces of the source semiconductor layer  48  and the drain semiconductor layer  47 , respectively. 
     The gate electrode  41 , the drain electrode  42  and the source electrode  43  are extended outside the TFT  40  so that a voltage can be applied from an exterior electric power source. 
     The channel semiconductor layer  46 , and the drain and source semiconductor layers  47 ,  48  are constituted of amorphous silicon, a polysilicon or the like. 
     The drain semiconductor layer  47  and the source semiconductor layer  48  are of the same electroconductive type of a p-type or n-type electroconductive type, and the channel semiconductor layer  46  is the same electroconductive type as or an opposite electroconductive type to the drain semiconductor layer  47  and the source semiconductor layer  48 . 
     First, a case where the channel semiconductor layer  46  is of the same electroconductive type as that of the source and drain semiconductor layers  47 ,  48  will be explained. 
     The channel semiconductor layer  46  has a lower resistance with a higher impurity concentration than the drain and source semiconductor layer  47 ,  48 . 
     When an operating voltage is applied between the drain electrode  42  and the source electrode  43 , a gate voltage is applied to the gate electrode, the gate voltage induces a charge on a surface of the channel semiconductor layer, thereby a low-resistance storage layer is formed, so that the drain semiconductor layer  47  and the source semiconductor layer  48  are connected through the storage layer and the TFT is electrically turned on. No storage layer is formed as long as the gate voltage is not applied, so that the TFT  40  is electrically cut off. 
     Next, a case where the channel semiconductor layer  46  and the drain and source semiconductor layers  47 ,  48  are of different electroconductive types will be explained. When such a voltage that induces charges having a polarity opposite to that of the channel semiconductor layer  46  onto a surface of the channel semiconductor layer  46  is applied to the gate electrode  41  in a state such that an operating voltage is applied between the drain electrode  42  and the source electrode  43 , an inversion layer being the same electroconductive type as that of the drain and source semiconductor layers  47 ,  48  is formed at a portion of the channel semiconductor layer  46  above the gate electrode  41 , so that the drain semiconductor layer  47  and the source semiconductor layer  48  are connected through the inversion layer, and the TFT is electrically turned on. No inversion layer is formed as long as no gate voltage is applied, and the TFT  40  is cut off. 
     A part of the surface of the source electrode  43  is exposed, and a pixel electrode  36  extended from the display pixel  35  contacts the exposed part of the source electrode  43 . 
     The pixel electrode  36  is extended up to a position where the storage condenser  39  is located, and is arranged opposed to the storage electrode  38  disposed on the glass substrate  31  through an insulating film (gate insulating film  44 ). Accordingly, the storage condenser  39  is formed by an opposed portion. 
     Therefore, the electrode on one side of the condenser  39  having storage capacity is the storage electrode  38 , and the electrode on the other side is the pixel electrode  36 . The electrode on the other side is not limited to the pixel electrode  36 , and it may be another electrode (a common electrode  55 , for example). 
     The TFT substrate  30  and the color filter substrate  50  are placed away by a constant distance, and liquid crystals  4  are sealed therebetween. 
     In the color filter substrate  50 , a black matrix  52  is arranged at a position opposed to the TFT  40 ; and a color filter  53  is arranged at a position opposed to the display pixel  35 . The common electrode  55  is arranged at least at a portion of the color filter substrate  50  opposed to the display pixel  35 . The pixel electrode  36  and the common electrode  55  are constituted of transparent metallic films of ITO or the like. 
     The TFT substrate  30  and the color filter substrate  50  have polarization plates  49 ,  59 , respectively. When a voltage is applied between the pixel electrode  36  and the common electrode  55  by turning on or cutting off of the TFT  40 , the orientation of the liquid crystals  4  above the display pixel  35  is changed, so that the polarized direction of the light passing the liquid crystals  4  is changed, thereby controlling transmission of the light irradiated to the display pixel  35  to the outside of the liquid crystal display device  3  and the shielding thereof. 
     The storage capacity is connected in parallel to a liquid crystal capacity formed between the pixel electrode  36  and the common electrode  55 . When the TFT  40  is electrically conducted and the liquid crystal capacity between the pixel electrode  36  and the common electrode  55  is charged by the voltage of the power supply voltage via the TFT  40 , the storage capacity is charged by the power supply voltage. 
     Even when the TFT  40  is cut off by charges stored in the storage capacity to cut off the pixel electrode  36  from the power supply voltage, the same voltage as in the case of the state of turning on of the TFT  40  is applied to the pixel electrode  36 , so that the polarized state of the liquid crystals  4  above the display pixel  35  is maintained. When this liquid crystal capacity is discharged, the polarized state of the liquid crystals  4  is changed. 
     The storage electrode  38  and the gate electrode  41  contact the glass substrate  31 , and the drain electrode  42  and the source electrode  43  contact the semiconductor layers (the drain semiconductor layer  47  and the source semiconductor layer  48 ). 
     The storage electrode  38 , the gate electrode  41 , the drain electrode  42  and the source electrode  43  are constituted of the wiring films  25  and  27  formed by the present invention; and the barrier film  22  contacts the glass substrate  31  or the semiconductor layers  47 ,  48 . Therefore, adhesion among the storage electrode  38 , the gate electrode  41  and the glass substrate  31  and adhesion among the drain electrode  42 , the source electrode  43  and the semiconductor layers  47 ,  48  are high. Meanwhile, since the low-resistance film  23  arranged on the barrier film  22  contains no oxygen and has a lower resistance than the barrier film  22 , the resistance in an extending direction of each electrode film (the direction orthogonal to that of the film thickness) is low. 
     The electronic device according to the present invention is not limited to the liquid crystal display device. 
     In  FIG. 4 , a reference numeral  6  denotes a part of a semiconductor device as another embodiment of the electronic device according to the present invention. In  FIG. 4 , a transistor  60  of the semiconductor device  6  is shown. 
     This transistor  60  has the same parts as those of the TFT  40  shown in the above  FIG. 3  except that it is not disposed on a glass substrate but has a semiconductor substrate (silicon substrate)  61 . Thus, explanation is omitted for the same reference numerals used for the same parts. 
     In this transistor  60 , portions of the surfaces of the source semiconductor layer  48  and the drain semiconductor  47  are also exposed; and a barrier film  22  of the source electrode  43  and a barrier film  22  of the drain electrode  42  tightly adhere to the exposed portions, respectively. 
     Consequently, adhesion of the drain electrode  42  and the source electrode  43  to the silicon substrate  61  is high, and the barrier film  22  prevents copper from diffusing into the silicon substrate  61 . 
     Further, a reference numeral  64  of  FIG. 4  denotes an insulating film in order to insulate the drain electrode  42  and the source electrode  43  from the gate electrode  41 ; and a reference numeral  74  of the same figure denotes an insulating film in order to insulate the drain electrode  42  and the source electrode  43  from a place other than the source semiconductor layer  48  and the drain semiconductor layer  47  of the silicon substrate  61 . 
     In a case where the electronic device is the semiconductor device  6 , the drain semiconductor  47 , the source semiconductor  48  and the channel semiconductor layer  46  are formed by diffusing impurities into the silicon substrate  61 . In a case where the electronic device is the liquid crystal display device, the semiconductor device  6 , the drain semiconductor  47 , the source semiconductor  48  and the channel semiconductor layer  46  are formed by tightly adhering semiconductors such as silicon on the surface of the glass substrate  31  according to a CVD method or the like. 
     Further, the insulating films (such as, the gate insulating film  44  or the like) are constituted of a nitride film of silicon nitride (such as silicon nitride or the like) an oxide film such as silicon oxide or the like. 
     The above description explains a case where the gate electrode  41 , the drain electrode  42 , the source electrode  43  and the storage electrode  38  are constituted of the wiring film  25 ,  27  formed by the present invention, respectively, but the present invention is not limited thereto. After either one or both of the source electrode  43  and the drain electrode  42  are formed by the wiring film-forming method of the present invention, the gate electrode  41  and the storage electrode  38  may be formed by a method different from the present invention. Alternatively, after either one or both of the gate electrode  41  and the storage electrode  38  are formed by the wiring film-forming method of the present invention, the source electrode and the drain electrode may be formed by a method different from the present invention. 
     In addition, all of the source electrode  43 , the drain electrode  42 , the gate electrode  41  and the storage electrode  38  may be constituted of the wiring film  25  with the two-layer structure or all the electrodes may be constituted of the wiring film  27  with the three-layer structure. Furthermore, with one or more of the source electrode  43 , the drain electrode  42 , the gate electrode  41  and the storage electrode  38  being constituted of the wiring film  25  with the two-layer structure, the remaining electrode or electrodes may be constituted of the wiring film  27  with the three-layer structure. As discussed above, since the adhering film  29  prevents oxygen from diffusing into the low-resistance film  23 , the wiring film  27  with the three-layer structure is effectively used as a film contacting an electrode formed by an oxide transparent conductive film (such as the pixel electrode  36  or the common electrode  55 ). 
     EXAMPLES 
     Glass substrates were used as the object  21  to form a film thereon, and barrier films  22  were formed as to the respective combinations of film forming conditions: ratios of the partial pressure of the oxygen gas to that of the sputtering gas (Ar) at the time of sputtering and the annealing temperatures after the film formation. 
     In each combination, the introduction of sputtering gas was set such that the partial pressure of the introduced amount was a constant value (0.4 Pa). The ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas is a value obtained by dividing the partial pressure of the oxygen gas by the partial pressure of the sputtering gas (0.4 Pa) and multiplying the quotient by 100. 
     &lt;Adhesion Test&gt; 
     A total of 100 1 mm grid squares were inscribed in 10 lines×10 columns on each barrier film  22  with a tip-sharp cutter knife, and an adhesive tape (No. 610 Scotch tape) was stuck thereto. Then, the number of the remaining barrier films  22  after the adhesive tape was peeled was counted. Results thereof are given in the following Table 1 together with the ratios of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas and the annealing temperature. The unit of the annealing temperature in Table 1 below is ° C. 
     
       
         
           
               
             
               
                 TABLE 1 
               
             
            
               
                   
               
               
                 Adhesion test 
               
            
           
           
               
               
            
               
                   
                 Annealing temperature 
               
            
           
           
               
               
               
               
               
            
               
                   
                 O 2  ratio 
                 Not 
                   
                   
               
               
                   
                 [%] 
                 annealed 
                 350 
                 450 
               
               
                   
                   
               
            
           
           
               
               
               
               
               
            
               
                   
                 0 
                 30/100 
                 28/100 
                 35/100 
               
               
                   
                 0.1 
                 48/100 
                 52/100 
                 57/100 
               
               
                   
                 3.0 
                 77/100 
                 81/100 
                 79/100 
               
               
                   
                 10.0 
                 92/100 
                 93/100 
                 91/100 
               
               
                   
                 20.0 
                 99/100 
                 97/100 
                 98/100 
               
               
                   
                   
               
            
           
         
       
     
     When all the barrier films  22  were peeled from the glass substrate, the evaluation was 0/100, whereas when none was peeled, the evaluation was 100/100. Thus, the greater the number of the numerator, the higher the adhesion. 
     As seen from the above Table 1, the higher the partial pressure of the oxygen gas, the greater the adhesion. When the ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas is not less than 3.0%, more than half of the barrier film  22  remains. Thus, Table 1 shows that in order to ensure the adhesion as a wiring film for an electronic device, the ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas is required to be not less than 3.0%. More particularly, it is seen that when such high adhesion that not less than 90% of the barrier film may be left without being peeled is required, the ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas need not be less than 10%. 
     &lt;Resistance Value&gt; 
     Resistivity of each barrier film  22  annealed at 350° C. was measured. Measuring results thereof are given in the following table 2. 
     
       
         
           
               
             
               
                 TABLE 2 
               
             
            
               
                   
               
               
                 Resistivity 
               
            
           
           
               
               
               
            
               
                   
                 O 2  ratio 
                 After annealing at 350° C. 
               
               
                   
                 [%] 
                 Resistivity [μΩ cm] 
               
               
                   
                   
               
            
           
           
               
               
               
            
               
                   
                 0 
                 2.1 
               
               
                   
                 1.0 
                 4.0 
               
               
                   
                 3.0 
                 6.0 
               
               
                   
                 10.0 
                 7.2 
               
               
                   
                 20.0 
                 8.0 
               
               
                   
                   
               
            
           
         
       
     
     The higher the partial pressure of the oxygen gas, the greater the resistivity. Looking at Table 2, when the ratio of the partial pressure of the oxygen gas to the partial pressure of the sputtering gas is 20.0%, the resistivity is at a maximum of 8.0. This value shows that the film is usable as a barrier film of the above wiring film for an electronic device. 
     &lt;Film Composition&gt; 
     With respect to three kinds of barrier films formed at different partial pressure of the oxygen gas, the content of oxygen atoms and that of copper atoms were measured by an XPS method (X-ray photoelectron spectroscopy). Results thereof are given in the following Table 3. 
     
       
         
           
               
             
               
                 TABLE 3 
               
             
            
               
                   
               
               
                 Film composition 
               
            
           
           
               
               
               
            
               
                 O 2  ratio [%] 
                 Cu [Atomic %] 
                 O [Atomic %] 
               
               
                   
               
            
           
           
               
               
               
            
               
                 5 
                 96.2 
                 3.8 
               
               
                 10 
                 94.9 
                 5.1 
               
               
                 15 
                 90.5 
                 9.5 
               
               
                   
               
            
           
         
       
     
     It was confirmed from the above Table 3 that as the partial pressure of the oxygen gas at the time of sputtering increases, the content of oxygen atoms contained in the barrier films  22  becomes greater.