Method for manufacturing semiconductor device

The manufacturing method of the semiconductor device provides reduction of the photoresist film distortion occurred in a development procedure and, as a result, makes measurement of the place difference of the photoresist mask correct. The manufacturing method of the semiconductor device to be published are those the photoresist film consisting the upper alignment-measuring mark is placed more than about 200 μm from an corner in device forming region formed adjoining scribing region, along with X-direction which is the measurement direction in scribing region formed on semiconductor substrate.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a method for manufacturing a semiconductor device, and more particularly to the method for manufacturing the semiconductor device using a lithography technique.

The present application claims priority of Japanese Patent Application No. 2002-055754 filed on Mar. 1, 2002, which is hereby incorporated by reference.

2. Description of the Related Art

In manufacturing of a semiconductor device such as an LSI (Large Scale Integrated circuit) or a like, a photo-lithography is used as a requisite process so as to produce a fine pattern of a thin film formed on a semiconductor substrate, for example, an insulating film such as an oxide film, or a conductive film such as a wiring film, or a like.

For example, in a case of producing a fine pattern of the insulating film using this kind of photolithography technique, photoresist is coated on the insulating film to form a photoresist film thereon. Next, an exposing process is performed by irradiating the photoresist film with an ultraviolet ray output from a light source such as a laser or a like, through a mask with a specified pattern. After this, a development process is performed to form a photoresist mask having a specified fine pattern, and followed by etching process to produce a fine pattern of the insulating film, using the formed photoresist mask.

Therefore, a fine patterning process of the insulating film is performed by etching processes using this photoresist mask. These photoresist mask formation processes are performed repeatedly in more than one process that requires photolithographic process.

In the case of these formations of each photoresist mask by repeating the processes corresponding with photolithographic processes, the amount of deviation of the photoresist mask formed from the right designed alignment is measured. Though the amount of deviation of the photoresist mask is usually determined depending on the accuracy of a exposure system (equipment), so called repeating procedures are performed since the photolithographic processes according to designed first layer of film are difficult in the case of the amount of deviation is relatively large from the result of the measurement of the amount of deviation. An increase of a cost is unavoidable when the repeating procedures are performed since the number of the processes is increased.

The above measurement of the amount of deviation of the photoresist mask is performed as the followings: firstly a first alignment-measuring mark for the measurement of a aligned side (hereinafter may be referred to as lower alignment-measuring mark) is formed on the semiconductor substrate as a groundwork, secondary the photoresist film is formed on the substrate after the formation of the insulating film which is a first layer of film, thirdly at the same time of the formation of the above photoresist mask exposing and developing the photoresist film, a second alignment-measuring mark for the measurement on a aligning side (hereinafter may be referred to as upper alignment-measuring mark) being comprised by the above photoresist film is formed so that the upper alignment-measuring mark on the aligning side corresponds to and is overlaid on the lower alignment-measuring mark on the aligned side. Then the amount of relative deviation between the upper alignment-measuring mark and the lower alignment-measuring mark is measured by the exposure system using the measurement for the alignment.

Next, with reference toFIGS. 10A,10B and10C, a conventional method for manufacturing a semiconductor device, for example, a semiconductor device as shown inFIG. 11will be explained sequentially as follows. Firstly, as shown inFIG. 10A, and a device forming region52and a mark forming region53are allocated on a p-type of a semiconductor substrate51for example, and a lower alignment-measuring mark55is formed in the mark forming region53of the semiconductor substrate51. In the lower alignment-measuring mark55, a recessed portion54whose a planar shape thereof is of almost square fore example as mentioned later is formed in a scribing region68as the mark forming region53on the semiconductor substrate51, by performing an etching process or a like. The lower alignment measuring mark55may be formed in the regions other than the cell regions, not being restricted to the scribing region68(as shown in FIG.15). Next, a photoresist film57is formed by coating the photoresist on all the surface of the insulating film56, after forming insulating film56such as an oxide film throughout on the surface of the semiconductor substrate51.

As shown inFIG. 10B, using the photolithographic process, at a same time of forming a photoresist mask59with a specified pattern in which a photoresist-removed opening portion such as a trench or a hole (hereinafter may be referred to as opening portion)58is formed in the device forming region52, by exposing the ultraviolet ray from a source of light such as a laser through a photomask (not shown) with a specified circuit pattern to the photoresist film57, and developing an upper alignment-measuring mark61corresponding to the lower alignment-measuring mark55on the mark forming region53.

The upper alignment-measuring mark61is made up of a photoresist pattern60whose plan shape is of square for example, and placed for example in the inside of the lower alignment-measuring mark55made up of the recessed portion54for example whose plan shape is of square, as mentioned before. In this case, the photoresist mask59and the photoresist pattern60which are formed on the device forming region52and the mark forming region53respectively are formed whose film thickness are the same since they are formed by the same procedures.

Next, alignment is checked, so as to make sure whether the photoresist mask59having the specified pattern made up of the opening portion58is in the right place with the lower pattern. That is, by using the lower alignment-measuring mark55formed on the lower layer and the upper alignment-measuring mark61formed on the upper layer as shown inFIG. 12, a relative amount of deviation from a right alignment between the lower alignment-measuring mark55and the upper alignment-measuring mark61in the X-direction (horizontal direction) or in the Y-direction (vertical direction) is measured. This means that the relative deviation between the lower alignment-measuring mark55and the upper alignment-measuring mark61is optically measured using the upper alignment-measuring mark61as mentioned above. Then when the result of the deviation measurement shows that the deviation is within tolerance, the photoresist mask59is judged to be formed with great alignment accuracy. An N-type semiconductor region62is formed selectively on the semiconductor substrate51by implanting ions which are n-type impurities such as phosphorus (P) through the opening portion58in the device forming region52using the photoresist mask59, as shown in FIG.10B. In this process, the above impurity ion is not implanted into the mark forming region53due to a masking effect of both of the photoresist film57and the insulating film56, since the photoresist film57and the insulating film56are formed and stacked on the mark forming region53. On the other hand, when it is judged that the photoresist mask59is not formed in the device forming region52with great alignment accuracy, the processing as above is repeated.

The photoresist mask59and the photoresist pattern60are removed by the method such as ashing, as shown in FIG.10C. Then, a semiconductor device63as shown inFIG. 11is manufactured, thermally stabilizing the semiconductor substrate51including the N-type semiconductor region62by annealing. In reality, the semiconductor device63is manufactured by repeating the photolithographic process as the above two or more times, the embodiment of a single step out of photolithographic processing for forming the N-type semiconductor region62is used to make the explanation simple.

In the manufacturing process of a semiconductor device63, a plurality of device regions (circuit device regions) having a same circuit pattern are formed on a piece of the semiconductor substrate51, then finally dicing of the semiconductor substrate51is performed on each semiconductor chip on which each device region is formed. In order to form more than one of the device regions on the semiconductor substrate51as mentioned above, patterns corresponding to each device region are transferred repeatedly using the mask (reticle mask) in which the patterns are drawn. The pattern repeatedly transferring process as the above is performed, as shown inFIG. 13, generally by using a reducing-projection type of exposure equipment called an aligner, a stepper, or a like, by using a photomask66made up of a semiconductor device pattern65with the size of four times or five times larger than a final pattern size of a product and the upper alignment-measuring mark61(FIG. 14) on an aligning side, and by exposing an ultra-violet ray to the photoresist film formed on the semiconductor substrate51through the reducing-projection lens67. Thus, the semiconductor device pattern65and the upper alignment-measuring mark61having respectively a final pattern size of a product are formed on the photoresist film by repeating reducing projection exposure and performing a subsequent developing process.

In the repeating transfer processes of patterns as mentioned above, since the upper alignment-measuring mark61is used only for the measurement of the deviation of the photoresist mask59, the upper alignment-measuring marks61are formed in regions other than the device forming region52, that is, in the scribing regions68other than a cell region, and are formed in detail for example in four positions around a periphery of the semiconductor device pattern65(one-shot-exposing region) as shown in FIG.14.FIG. 15is a plan view showing the semiconductor substrate51provided with four upper alignment-measuring marks61adjacent to the device forming region52, and formed by performing pattern repeatedly transferring process. The lower alignment-measuring mark55and the upper alignment-measuring mark61used for the measurement of the deviation of the photoresist mask59show the status that each of them is formed on the scribing region68for dicing without adversely affecting for forming a semiconductor device. The semiconductor substrate51is diced along with X and Y directions of the scribing region68, and it is divided into each semiconductor chip as mentioned above.

Each of the lower alignment-measuring mark55and the upper alignment-measuring mark61as shown inFIG. 12is placed in the scribing region68as shown in FIG.15. Also, the photoresist film is not removed in the scribing region68but on the other hand the photoresist film is removed in each device forming region52, as shown in the same figure. A photoresist-removed region70is set on the photoresist film in the scribing region68as shown inFIG. 12so that the photoresist film in the scribing region68is removed and that the upper alignment-measuring mark61on the upper side is formed on the photoresist-removed region70.

On the other hand, in the conventional manufacturing processes in the semiconductor device63there is a problem that measurement errors in appearance occur in the measurement of the deviation of the photoresist mask59using the photoresist film.

In other words, in the conventional method of the manufacturing processes of the semiconductor devices63, the upper alignment-measuring mark61on the upper side making up the photoresist pattern60are formed so that the upper alignment-measuring mark61are overlaid on the lower alignment-measuring mark55using the scribing region68on the semiconductor substrate51as the mark forming region53. However, in the conventional process the upper alignment measuring mark61on the upper side are formed with no relations to the device forming regions52around the scribing region68and a data ratio of the photoresist film (a ratio of a removed area to a remaining area).

Therefore, there occurs a phenomenon that the photoresist pattern60making up an arbitrary upper alignment-measuring mark61becomes deformed to be asymmetrical in a cross sectional shape, under the influence of an adjacent photoresist pattern making up another upper alignment-measuring mark61, or of the photoresist film remaining in the scribing region68as shown inFIG. 16,

The deformation (loss of its shape) of the photoresist pattern60making up the upper alignment-measuring mark61becomes remarkable as materials being different from each other or thickness of the photoresist film being thick. This tendency suggests that the deformation of the photoresist pattern60will be large considering the fact that the photoresist mask59is used in the ion impurities implantation process which is one of the main processes in manufacturing the semiconductor device such as LSIs, particularly deep ion impurities implantation process is required according to the recent tendency of high performance of LSIs, and a thick photoresist film for more than 4 μm is required according to this trend.

Thus, a margin of error in appearance occurs since the alignment of the photoresist mask is measured incorrectly as if a place difference of the photoresist mask59is occurred more than that of the actual difference in the measurement of the place difference of the photoresist mask59when the photoresist pattern60making up the upper alignment-measuring mark61changes its shape. A misconception of the margin of error in appearance as the actual place difference occurs in the manufacturing process of the semiconductor device when such a margin of measurement error in appearance occurs. Therefore, productivity of the semiconductor device becomes lower since unnecessary reprocessing is to be performed.

SUMMARY OF THE INVENTION

In view of the above, it is an object of the present invention to provide a method for manufacturing a semiconductor device being capable of preventing an upper alignment-measuring mark being made up of a photoresist film from chnging shape through a development process, hereby of measuring accurately an alignment deviation of a photoresist mask.

According to a first aspect of the present invention, there is provided a method for manufacturing a semiconductor device including:

a first step of forming a first alignment-measuring mark having a recessed pattern on a surface of a semiconductor, by using a photoetching process;

a second step of coating the surface of the semiconductor on which the first alignment-measuring mark is formed, with a photoresist film;

a third step of patterning the photoresist film by using a photolithography technique and of forming a photoresist mask with a second alignment-measuring mark on the semiconductor, wherein the second alignment-measuring mark is aligned to be overlaid on the first alignment-measuring mark;

hereby measuring a relative deviation from a right alignment between the first alignment-measuring mark and the second alignment-measuring mark;

wherein the second alignment-measuring mark is placed at a specified position on the semiconductor so that a ratio between a total area of photoresist-removed portions and a total area of photoresist-remaining portions within a first specified region extending in a first measuring direction from a center of the second alignment-measuring mark is equal approximately to that within a second specified region extending in a second measuring direction opposite to the first measuring direction from the center of the second alignment-measuring mark, the first alignment-measuring mark and the second alignment-measuring mark being located outside a cell region, and the first specified region and the second specified region being set outside the cell region.

In the foregoing, a preferable mode is one wherein each of the first alignment-measuring mask and the second alignment-measuring mask is formed as a rectangular shape of a planar pattern.

Another preferable mode is one wherein the photoresist film making up the second alignment-measuring mark is set to be more than 4 μm in thickness.

Still another preferable mode is one wherein the first specified region and the second specified region are set to be almost symmetrical with respect to the center line of the second alignment-measuring mark.

An additional preferable mode is one wherein the first alignment-measuring mark and the second alignment-measuring mark are located within a scribing region outside the cell region, and the first specified region and the second specified region are set within the scribing region outside the cell region.

A furthermore preferable mode is one wherein the scribing region is set to be within a range of 80 μm to 120 μm in width.

According to a second aspect of the present invention, there is provided a method for manufacturing a semiconductor device including:

a first step of forming a first alignment-measuring mark having a recessed pattern on a surface of a semiconductor, by using a photoetching process;

a second step of coating the surface of the semiconductor on which the first alignment-measuring mark is formed, with a photoresist film;

a third step of patterning the photoresist film by using a photolithography technique and of forming a photoresist mask with a second alignment-measuring mark on the semiconductor, wherein the second alignment-measuring mark is aligned to be overlaid on the first alignment-measuring mark;

hereby measuring a relative deviation from a right alignment between the first alignment-measuring mark and the second alignment-measuring mark;

wherein the second alignment-measuring mark is placed at a specified position on the semiconductor so that a ratio between a total area of photoresist-removed portions and a total area of photoresist-remaining portions within a first specified region extending in a first measuring direction from a center of the second alignment-measuring mark is equal approximately to that within a second specified region extending in a second measuring direction opposite to the first measuring direction from the center of the second alignment-measuring mark, the first alignment-measuring mark and the second alignment-measuring mark being located outside a device forming region, and the first specified region and the second specified region being set outside the device forming region; and

wherein the second alignment-measuring mark is placed at a distance of more than 200 μm from a corner of the device forming region being adjacent to the first specified region or the second specified region, in the first measuring direction or the second measuring direction

According to a third aspect of the present invention, there is provided a method for manufacturing a semiconductor device including:

a first step of forming an insulating film on a semiconductor and then of forming a first alignment-measuring mark having a recessed pattern on a surface of formed the insulating film, by using a photoetching process;

a second step of coating the surface of the insulting film on which the first alignment-measuring mark is formed, with a photoresist film;

a third step of patterning the photoresist film by using a photolithography technique and of forming a photoresist mask with a second alignment-measuring mark on the insulting film, wherein the second alignment-measuring mark is aligned to be overlaid on the first alignment-measuring mark;

hereby measuring a relative deviation from a right alignment between the first alignment-measuring mark and the second alignment-measuring mark;

wherein the second alignment-measuring mark is placed at a specified position on the insulting film so that a ratio between a total area of photoresist-removed portions and a total area of photoresist-remaining portions within a first specified region extending in a first measuring direction from a center of the second alignment-measuring mark is equal approximately to that within a second specified region extending in a second measuring direction opposite to the first measuring direction from the center of the second alignment-measuring mark, the first alignment-measuring mark and the second alignment-measuring mark being located outside a cell region, and the first specified region and the second specified region being set outside the cell region.

According to a fourth aspect of the present invention, there is provided a method for manufacturing a semiconductor device including:

a first step of forming an insulating film on a semiconductor and then of forming a first alignment-measuring mark having a recessed pattern on a surface of formed the insulating film, by using a photoetching process;

a second step of coating the surface of the insulting film on which the first alignment-measuring mark is formed, with a photoresist film;

a third step of patterning the photoresist film by using a photolithography technique and of forming a photoresist mask with a second alignment-measuring mark on the insulting film, wherein the second alignment-measuring mark is aligned to be overlaid on the first alignment-measuring mark;

hereby measuring a relative deviation from a right alignment between the first alignment-measuring mark and the second alignment-measuring mark;

wherein the second alignment-measuring mark is placed at a specified position on the insulting film so that a ratio between a total area of photoresist-removed portions and a total area of photoresist-remaining portions within a first specified region extending in a first measuring direction from a center of the second alignment-measuring mark is equal approximately to that within a second specified region extending in a second measuring direction opposite to the first measuring direction from the center of the second alignment-measuring mark, the first alignment-measuring mark and the second alignment-measuring mark being located outside a device forming region, and the first specified region and the second specified region being set outside the device forming region; and

wherein the second alignment-measuring mark is placed at a distance of more than 200 μm from a corner of the device forming region being adjacent to the first specified region or the second specified region, in the first measuring direction or the second measuring direction.

With the above configurations, in case of the measurement of a relative deviation between the alignment mark for the measurement on the aligned side and that on the aligning side the deformation of the photoresist film based on the data ratio of the alignment mark for the measurement on the aligning side can be almost the same in the direction to be measured since the alignment mark for the measurement on the aligning side is placed so that the ratio of removed areas of the photoresist film to remaining areas of the photoresist film between both sides of the alignment mark is almost the same. Therefore, errors in appearance due to the deformation of the photoresist film are hardly occurred.

Accordingly, it is possible to prevent an upper alignment-measuring mark being made up of a photoresist film from changing shape through a development process, hereby of measuring accurately an alignment deviation of a photoresist mask.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Best modes for carrying out the present invention will be described in further detail using embodiments with reference to the accompanying drawings.

First Embodiment

FIGS. 1A,1B, and1C are process diagrams for showing in order a method for manufacturing a semiconductor device according to a first embodiment of the present invention,FIG. 2is a cross section view showing schematically the semiconductor device produced using the method according to the first embodiment,FIG. 3is a plan view showing a main part of a semiconductor substrate obtained by performing a main process in the method according to the first embodiment,FIG. 4is an enlarged plan view showing a part ofFIG. 3, andFIG. 5is a cross sectional view showing a cross sectional shape of a photoresist pattern shape making up an upper alignment-measuring mark11formed in the method according to the first embodiment.

The method for manufacturing the semiconductor device13according to the embodiment will be described with reference toFIG. 1to FIG.5and FIG.7.

Firstly, as shown inFIG. 1A, and a device forming region2and a mark forming region3are allocated on a P,-type of a semiconductor substrate1for example, and a lower alignment-measuring mark5is formed in the mark forming region3of the semiconductor substrate1. In the lower alignment-measuring mark5, a recessed portion4whose a planar shape thereof is of almost square, for example, as mentioned later is formed as the mark forming region3in a scribing region18on the semiconductor substrate1, by performing an etching process or a like. The lower alignment-measuring mark5may be formed in the regions other than the cell regions, not being restricted to the scribing region18(as shown in FIG.3). Next, a photoresist film7of about 4 μm in thickness is formed by coating the photoresist throughout on the surface of an insulating film6, after having formed the insulating film6such as an oxide film or a like on all the surface of the semiconductor substrate1.

Next, as shown inFIG. 1B, in a photolithographic process, it is performed to expose the photoresist film7to an ultraviolet ray from a source such as a laser through a photo mask (not shown) with a specified pattern, and then to develop the photoresist film7, hereby forming a photoresist mask9with a specified pattern having an opening region8in the device forming region2and an upper alignment-measuring mark11in the mark forming region3at a same time. The photoresist mask9is used in a subsequent etching process, and it is expected that the upper alignment-measuring mark11is placed in a proper alignment with the corresponding lower alignment-measuring mark5, as formed in an earlier process.

Here, not only upper alignment-measuring mark11but various kinds of patterns (not shown) are formed in the scribing region18.

The upper alignment-measuring mark11as also shown inFIG. 4, is made up of, for example, a photoresist pattern10having a flat planar shaped square, and formed in such a manner that the upper alignment-measuring mark11are placed on and inside the lower alignment-measuring mark5made up of the recessed portion4for example whose plan shape is square. In this case, the photoresist mask9and the photoresist pattern10being formed on the device forming region2and the mark forming region3respectively are formed in the same film thickness since they are formed at the same time. The recessed portion4making up the lower alignment-measuring mark5is formed for example in a square whose one side of the recessed portion4is 30 μm to 40 μm in length, and the photoresist pattern10making up the upper alignment-measuring mark11is formed, for example, in a square shape of which one side of the photoresist pattern10is 8 μm to 12 μm in length.

The photoresist mask9and the photoresist pattern10are formed, generally by using a reducing projection type of exposure equipment called an aligner, a stepper or a like, by using a photomask made up of a semiconductor device pattern with the size of four times or five times larger than a final pattern size of a product and the upper alignment-measuring mark11on an aligning side, and by exposing an ultra-violet ray to the photoresist film7formed on the semiconductor substrate1through a reducing projection lens. Thus, the semiconductor device pattern and the upper alignment-measuring mark11having respectively a final pattern size of a product are formed on the photoresist film7by repeating reducing projection exposure and performing a subsequent developing process.

FIG. 3is a plan view showing the semiconductor substrate1provided with four upper alignment-measuring marks11adjacent to the device forming region2, and formed by performing pattern repeatedly transferring process. The lower alignment-measuring mark5and the upper alignment-measuring mark11used for the measurement of the deviation of the photoresist mask9show the status that each of them is formed on the scribing region18for dicing without adversely affecting for forming a semiconductor device13. The lower alignment-measuring mark5and the upper alignment-measuring mark11are formed in such a manner that the upper alignment-measuring mark11is placed within the lower alignment-measuring mark5as shown in FIG.4.

In this embodiment of the manufacturing processes of the semiconductor device13, as shown inFIG. 3, the measurement direction of the deviation is selected in X-direction. The upper alignment-measuring mark11formed in the scribing region18are placed so that ratios of removed areas of the photoresist film7and ratios of remaining areas of the photoresist film7are about same each other across the upper alignment-measuring mark11along X-direction and symmetrically.

In detail, the upper alignment-measuring mark11is placed at a specified position in the scribing region18on the semiconductor device1so that a ratio between a total area of photoresist-removed portions and a total area of photoresist-remaining portions within a right side region extending in a right direction from a center of the upper alignment-measuring mark11is equal approximately to that within a left side region extending in a left direction from the center of the upper alignment-measuring mark11.

With thus a configuration, the deviation of the photoresist mask9is measured correctly since the shape loss (deformation) of the photoresist film7due to the data ratio of the upper alignment-measuring mark11is almost the same in X-direction that is to be measured and therefore a margin of error in appearance due to the shape loss of photoresist film7is hardly occurred. In other words, since a photoresist film7of a certain measurement mark is not affected by adjoining other photoresist film7of the measurement mark and also by the photoresist film7remaining in the scribing region18when the photoresist film7making up the upper alignment-measuring mark11is developed, the photoresist pattern10making up the upper alignment-measuring mark11hardly changes its shape and therefore the shapes of the cross section of the left side and the right side of the upper alignment-measuring mark11are almost the same as shown in FIG.5.

Concretely, the result of a relationship shown inFIG. 7is obtained since the deviation depending on the distance is changed in the case that the width of the scribing region18being surrounded by the device forming region2is set about 100 μm and that the upper alignment-measuring mark11being formed in the scribing region18is formed along X-direction which starts from a specified corner (intersection)2A of the device forming region2. The characteristic ofFIG. 7shows that the measurement data of deviations of the photoresist mask9(the vertical axis) change depending on the distance from the specified corner2A to the upper alignment-measuring mark11in X-direction (horizontal axis), and that the measurement data of the deviations hardly change when the distance is set to be more than about 200 μm. This experiment results also indicate that the location of the photoresist mask9is measured correctly by placing the photoresist film making up the upper alignment-measuring mark11apart more than about 200 μm from the specified corner2A of the device forming region2. Though the width of the scribing region18is generally set to a range of 80 μm to 120 μm, almost the same effect is obtained also in the above range.

Next, an n-type semiconductor region12is selectively formed on the semiconductor substrate1, as shown inFIG. 1B, implanting n-type impurities such as phosphorus (P) through the opening region8in the device forming region2using the photoresist mask9, regarding the deviation of the photoresist mask9with specified pattern having the opening region8as in the allowable range. In this case, the above impurities do not implanted into the mark forming region3due to the masking effect of the photoresist film7and the insulating film6, since both of the photoresist film7and the insulating film6are formed in the mark forming region3.

As shown inFIG. 1C, the photoresist mask9and the photoresist pattern10on the semiconductor substrate1are removed by a method such as an ashing. Then after annealing and stabilizing thermally the semiconductor substrate1including the n-type semiconductor region12, a semiconductor device13as shown inFIG. 2is manufactured by dicing the semiconductor substrate1in each semiconductor chip along with the scribing region18.

In this way, according to this embodiment of the manufacturing procedures of the semiconductor device the photoresist film making up the upper alignment-measuring mark11is formed apart from the specified corner2A of the device forming region2formed adjacent to the scribing region18in the distance of more than 200 μm. Therefore, the measurement errors in appearance due to the deformation of the photoresist film are hardly occurred since the deformation of the photoresist film7based on the data ratio of the upper alignment-measuring mark11can be set almost the same in X-direction to be measured.

In conclusion, the deviation of the photoresist mask9is measured correctly by decreasing the deformation of the photoresist mask9making up the alignment mark for the measurement in the development process.

Second Embodiment

FIG. 6is a plan view showing a main part of a semiconductor substrate obtained by performing a main process in a method for manufacturing a semiconductor device according to a second embodiment of the present invention. A main difference between the manufacturing method according to the first embodiment and that according to the second embodiment is that Y-direction is elected as a measuring direction for measuring a relative deviation from a right alignment between a lower alignment-measuring mark5and an upper alignment-measuring mark15in the second embodiment.

In the manufacturing method of the semiconductor device according to this embodiment, the measurement direction of the deviation is selected in Y-direction and the upper alignment-measuring mark15formed in the scribing region18is placed so that ratios of removed areas of the photoresist film7to remaining areas of the photoresist film7between one side of the upper alignment-measuring mark15and the other side of the upper alignment-measuring mark15along with a measurement direction in a region excepting a cell region is almost the same.

Concretely, the measurement results of the deviation are confirmed that the results hardly change in the same way as embodiment 1, placing the upper alignment-measuring mark15apart from the specified corner (intersection)2A of the device forming region2for more than about 200 μm, setting the value of the width of the scribing region18being surrounded by the device forming region2at about 100 μm and forming the upper alignment-measuring mark15adjacent to the scribing region18along with Y-direction from the specified corner (intersection)2A of the device forming region2.

As described above, the second embodiment can achieve approximate same effects as the first embodiment.

Third Embodiment

FIG. 8is a cross sectional view showing a main part of a semiconductor substrate1obtained by performing a main process in a method for manufacturing a semiconductor device13according to a third embodiment of the present invention, andFIG. 9is an enlarged plan view showing a part of the semiconductor substrate1obtained by performing the main process in the method according to the third embodiment.

A main difference between the manufacturing method according to the first embodiment and that according to the third embodiment is that a lower alignment-measuring mark19having a recessed pattern is formed on a surface of an insulating film6as shown inFIG. 8instead of the semiconductor substrate1in the third embodiment.

In the manufacturing method of the semiconductor device13according to this embodiment, the lower alignment-measuring mark19is formed in a scribing region18that is to be mark forming region after having formed the insulating film6such as an oxide film in all the surface of the semiconductor substrate1as shown inFIGS. 8 and 9. In the lower alignment-measuring mark19, for example, a recessed portion20of which a planar shape thereof is of almost square for example is formed in the scribing region18as a mark forming region3on the semiconductor substrate1, by performing an etching process or a like.

In the next step, a photoresist film21is formed coating the photoresist on all the surface of the substrate substrate1. Then, an upper alignment-measuring mark22made up of a photoresist pattern23having a flat planar shaped square, is formed on the mark forming region3corresponding to the lower alignment-measuring mark19, at the same time of the formation of the photoresist mask (not shown) with specified patterns having an opening area in the device forming region2, by the photolithographic process in almost the same method as in the first embodiment.

As described above, the third embodiment can achieve approximate same effects as the first embodiment, since groundworks forming the lower alignment-measuring mark are only different between the first embodiment and the second embodiment.

It is apparent that the present invention is not limited to the above embodiments but may be changed and modified without departing from the scope and spirit of the invention. For example, the formation region of the alignment mark for the measurement on the aligning side can be selected in the region other than the cell region not restricting to the scribing region although the above embodiments are explained selecting the alignment mark for the measurement on the aligning side in the scribe formation region. Also for example, although the photolithographic technologies are described using the light as a means of exposure, the technologies are able to be applicable to the general photolithographic technologies using electron beams or X-rays other than the light.

The shape of the lower alignment-measuring mark on the aligned side and the upper alignment-measuring mark on the aligning side being formed on the groundwork is not respectively limited to a rectangular shape in a plan view but these two kinds of alignment-measuring marks can have any other shape such as a circular shape or a like. In the relative relationship between the lower alignment-measuring mark on the aligned side and the upper alignment-measuring mark on the aligning side, it is not necessary for the upper alignment-measuring mark on the aligning side to be placed inside of the lower alignment-measuring mark on the aligned side, but it may be possible for the reverse relationship. In other words, it is preferable that both of the lower alignment-measuring mark and the upper alignment-measuring mark are in such shapes or in such arrangements that these two kinds of alignment-measuring marks can measure the relative deviation. In the above embodiments, although the photoresist film making up the upper alignment-measuring mark on the aligning side is set to be about 4 μm in thickness, the film thickness of more than 4 μm is desirable considering the trend in which deeper ion impurity implantation is required in the processes of recent LSIs.