KR20090109492A - Multi-gray scale photomask, manufacturing method of multi-gray scale photomask, pattern transfer method, and manufacturing method of thin film transistor - Google Patents

Abstract

PURPOSE: A gray-scale photomask is provided to obtain resist pattern with profile at edge portion and improve production stability of TFT. CONSTITUTION: A method for forming gray-scale photomask comprises: a step of forming a first semi-transmission film and second half-transmission film on a transparent substrate (11); a step of patterning; and a step of forming transfer pattern containing light-transmitting part, first half light-transmitting part (12), and second half light-transmitting part.

Description

MULTI-GRAY SCALE PHOTOMASK, MANUFACTURING METHOD OF MULTI-GRAY SCALE PHOTOMASK, PATTERN TRANSFER METHOD, AND MANUFACTURING METHOD OF THIN FILM TRANSISTOR }

The present invention relates to a multi-gradation photomask used in a photolithography step.

DESCRIPTION OF RELATED ART Conventionally, in manufacture of electronic devices, such as a liquid crystal device, as one process, forming a resist pattern using the photolithography process is performed. In other words, a resist pattern is formed by exposing the resist film formed on the workpiece layer to be etched under a predetermined exposure condition using a photomask having a predetermined pattern to transfer the pattern, and developing the resist film. And a to-be-processed layer is etched using this resist pattern as a mask.

In the photomask, for example, as shown in FIG. 10, a light shielding portion 71 that shields exposure light, a light transmitting portion 73 that transmits exposure light, and a semi-transmissive portion 72 that transmits a portion of the exposure light. There is a multi-gradation photomask in which a transfer pattern having a pattern) is formed. This multi-gradation photomask can vary the amount of exposure light depending on the area. Therefore, by performing exposure and development using this multi-gradation photomask, a resist pattern having a residual film value (including zero residual film value) of at least three thicknesses can be formed. Thus, the multi-gradation photomask which realizes the resist pattern which has several different residual film values can reduce the number of photomasks used at the time of manufacture of an electronic device, such as a liquid crystal device, and can make a photolithography process efficient. This is very useful.

In FIG. 10, the light-shielding portion, the semi-transmissive portion, and the light-shielding portion are arranged adjacent to the substrate surface in this order, and such a transfer pattern can be usefully used for manufacturing thin film transistors.

The light shielding part 71 in the above-mentioned multi-gradation photomask is comprised with the light shielding film like Cr film, and the semi-transmissive part 72 is a semi-transmissive film which has a desired transmittance which permeate | transmits a part of exposure light, for example. (Japanese Patent Laid-Open No. 2006-268035).

However, when the transfer pattern is transferred to the resist film on the transfer member by using the multi-gradation photomask as described above, diffraction of the exposure light occurs at the pattern boundary such as the boundary between the semi-transmissive portion and the light shielding portion, and thus the intensity of transmitted light. The distribution is somewhat gentle curves. For example, in the semi-transmissive portion sandwiched between two adjacent light shielding portions as shown in FIG. 10, the intensity distribution of the transmitted light becomes a gentle mountain shape, and this tendency becomes more pronounced as the line width is smaller (see FIG. 8). That is, as can be seen from FIG. 8, the rise and fall of the light intensity distribution curve is not abrupt. When resist pattern transfer is performed using such a multi-gradation photomask, the profile of the resist pattern formed in the resist film on the transfer object becomes smooth, and the side surface of the pattern is tapered. As a result, when processing a thin film using the said resist pattern as a mask, it becomes difficult to control a process line width, In other words, in the process of manufacture of a panel etc., the margin of processing conditions becomes remarkably narrow, and mass production is carried out. Cause problems.

This invention is made | formed in view of such a point, and an object of this invention is to provide the multi-gradation photomask and pattern transfer method which can obtain the resist pattern which has a profile of a sharp rise.

The multi-gradation photomask of the present invention forms a first translucent film and a second translucent film each having a predetermined light transmittance on a transparent substrate, respectively, and performs predetermined patterning, respectively, so that the light transmitting portion and the first semitransmissive portion And a transfer pattern including a second semi-transmissive portion having a portion adjacent to the first semi-transmissive portion, wherein the second semi-transmissive portion has a representative wavelength within a range of i-g lines. The phase difference between the light transmitting portion is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the first wavelength with respect to the representative wavelength. The transmittance of the transflective portion is less than 10%, and the transmittance of the second translucent portion is 20% or more.

According to the above configuration, at the boundary of the first semi-transmissive portion and the second semi-transmissive portion, the exposure light intensity is canceled, contrast enhancement is performed, and contrast contrast is not between the light-transmitting portion and the second semi-transmissive film. Do not. For this reason, this multi-gradation photomask is provided at the boundary between the first and second semi-transmissive portions while preventing the exposure light from canceling at the boundary between the second semi-transmissive portion and the light-transmitting portion to prevent dark lines from appearing on the transfer object. As a result, a shape having an abrupt profile on the sidewall of the resist pattern formed on the transfer object can be obtained.

In the multi-gradation photomask of the present invention, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is preferably 180 degrees ± 30 degrees with respect to the representative wavelength.

In the multi-gradation photomask of the present invention, it is preferable that the phase difference between the second semi-transmissive portion and the transmissive portion is less than 60 degrees with respect to the representative wavelength. As a result, the exposure light is canceled between the second semi-transmissive portion and the light-transmitting portion to produce dark lines, and it is possible to prevent unnecessary streaks from being formed in the formed resist pattern. More preferably, they are 5 degrees or more and less than 30 degrees.

In the multi-gradation photomask of the present invention, the first semi-transmissive portion is formed by stacking a second semi-transmissive film and a first semi-transmissive film on the transparent substrate, and the second semi-transmissive portion is a second half on the transparent substrate. It may be configured by forming a light-transmitting film. Of course, an anti-reflective film or the like may be laminated on the first and / or second semi-transmissive film (or an anti-reflective layer or the like), but in that case, the phase difference condition or transmittance condition may be applied as the whole layer configuration of the part. It needs to be designed to be satisfied.

In the multi-gradation photomask of the present invention, the first translucent portion is formed by forming a first translucent film on the transparent substrate, and the second translucent portion is formed by forming a second translucent film on the transparent substrate. Can be. Also in this case, you may use an antireflection layer etc. similarly to the above.

In the multi-gradation photomask of the present invention, the first semi-transmissive portion, the second semi-transmissive portion, and the first semi-transmissive portion have a transfer pattern arranged in this order, and the first semi-transmissive portion has a portion adjacent to the light-transmitting portion. It is preferable that the transmittance | permeability of a said 1st semi-transmissive part is 3%-7% with respect to the said representative wavelength, and the transmittance | permeability of a said 2nd semi-transmissive part is 20%-80%. More preferably, the transmittance | permeability of a 1st semi-transmissive part is 4%-7%, and the transmittance | permeability of a 2nd semi-transmissive part is 30%-60%. If there is a difference of 40% or more between both semi-transmissive portions, since a clear step occurs in the resist pattern to be formed, it is preferable because the stability of thin film processing at the time of use of the mask is significantly increased. The photomask having such a transfer pattern is useful for the manufacture of a thin film transistor, in which case the effect of the present invention, which makes the end face of the resist pattern stand vertically, becomes particularly remarkable.

The multi-gradation photomask of the present invention is formed on a transparent substrate by forming a second translucent film and a first translucent film, each having a predetermined light transmittance, and a light shielding film, and by performing predetermined patterning, respectively, In a multi-gradation photomask formed by forming a transfer pattern comprising a first semi-transmissive portion, a second semi-transmissive portion having a portion adjacent to the first semi-transmissive portion, and a light-shielding portion, for the representative wavelength within the range of i-g line, 2 The phase difference between the semi-transmissive portion and the transmissive portion is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second translucent portion exceeds 90 degrees with respect to the representative wavelength, and with respect to the representative wavelength. The transmittance of the first semi-transmissive portion is less than 10%, the transmittance of the second semi-transmissive portion is 20% or more, and the light shielding portion, the first semi-transmissive portion, the second semi-transmissive portion, the first semi-transmissive portion, and the light-shielding portion are in this order. Arranged transfer pattern And it characterized in that it has.

Here, the width of the first semi-transmissive portion in the array direction (the width in the transverse direction in the semi-transmissive portion 12 in FIG. 1B to be described later) is set to be equal to or greater than the width required for inversion of the phase of the exposure light. For example, it can be 1 micrometer or more, Preferably you may be 1 micrometer-8 micrometers. The structure of such a multi-gradation photomask enables the edge of the resist pattern to be formed at the boundary between the first semi-transmissive portion and the second semi-transmissive portion, and at the second semi-transmissive portion side, the resist (here Can suppress the film reduction caused by the photoresist being exposed to light. In addition, it is a preferable aspect to laminate | stack an anti-reflective film or to include an anti-reflective layer in the light shielding film used here.

The manufacturing method of the multi-gradation photomask of this invention is a process of preparing the photomask blank which laminated | stacked the 2nd translucent film, the 1st translucent film, and the light shielding film in this order on the transparent substrate, and made it on the said photomask blank. A step of forming a first resist pattern, and a step of patterning the first semi-transmissive film by etching using the light-shielding film patterned by etching using the first resist pattern or the first resist pattern as a mask. And forming a second resist pattern on the substrate surface including the light-shielding film and the first semi-transmissive film subjected to the pattern processing, and etching the at least second semi-transmissive film by etching using the second resist pattern as a mask. A manufacturing method of a multi-gradation photomask having a step of processing, wherein the second semi-transmissive portion and the light-transmitting portion have a representative wavelength within a range of i-g lines. The phase difference thereof is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the transmittance of the first semi-transmissive portion with respect to the representative wavelength is It is less than 10%, characterized in that the transmittance of the second translucent portion is 20% or more.

In addition, a method of manufacturing a multi-gradation photomask of the present invention comprises the steps of preparing a photomask blank in which a first translucent film and a light shielding film are laminated on a transparent substrate in this order, and a first resist pattern on the photomask blank. A step of forming and patterning the first semi-transmissive film by etching using the light-shielding film patterned by etching using the first resist pattern or the first resist pattern as a mask, and the pattern Masking the second resist pattern, forming a second translucent film on the substrate surface including the processed light shielding film and the first translucent film, forming a second resist pattern on the second translucent film, and As a manufacturing method of the multi-gradation photomask which comprises the process of pattern-processing at least the said 2nd semi-transmissive film by an etching, it is representative in the range of i line | wire-g line | wire. The phase difference between the second semi-transmissive portion and the light transmitting portion is less than 90 degrees with respect to the wavelength, and the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength. The transmittance of the first semi-transmissive portion is less than 10% and the transmittance of the second semi-transmissive portion is 20% or more with respect to the representative wavelength. Moreover, in the manufacturing process of the said photomask, you may replace the formation order of a 1st semi-transmissive film and a 2nd semi-transmissive film.

In the pattern transfer method of the present invention, the transfer pattern is transferred to a resist film on a transfer object by an exposure machine that irradiates irradiated light in a wavelength region of i-g line using the multi-gradation photomask. It is done.

In the pattern transfer method of this invention, it is preferable that the resist film on the said to-be-transferred body does not have a sensitivity substantially with respect to the exposure amount of the part corresponding to the said 1st translucent part. According to this method, it is possible to prevent the resist film of the portion corresponding to the first semi-transmissive portion from being exposed to light and reducing the film.

Or in the pattern transfer method of this invention, the resist film on the said to-be-transmitted body reduces film | membrane after image development in correspondence with the exposure amount of the part corresponding to the said 2nd semi-transmissive part, and based on the film | membrane reduction amount previously, It is preferable that the resist film thickness on the body is determined. In this case, the resist film thickness is appropriately determined based on the convenience of the processing process, the use of the electronic device to be manufactured, and the required precision.

The method for manufacturing a thin film transistor of the present invention is characterized by producing a thin film transistor using the pattern transfer method. This method is very advantageous in yield, production efficiency and stability in mass production of thin film transistors.

The multi-gradation photomask of the present invention forms a second semi-transmissive film and a first semi-transmissive film, each having a predetermined light transmittance, on a transparent substrate, respectively, and performs predetermined patterning, respectively, so that the light-transmitting portion and the first semi-transmissive portion And a transfer pattern comprising a second semi-transmissive portion having a portion adjacent to the first semi-transmissive portion, wherein the multi-tone photomask transmits the second semi-transmissive portion to a representative wavelength within a range of i-g lines. The phase difference between the light portion is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion exceeds 90 degrees with respect to the representative wavelength, and the first half with respect to the representative wavelength. Since the transmittance of the light transmitting portion is less than 10% and the transmittance of the second semi-transmissive portion is 20% or more, a resist pattern having a profile having a sharp rising shape at the edge portion can be obtained.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail with reference to an accompanying drawing.

In recent thin film transistors (TFTs), techniques such as increasing the operating speed of the liquid crystal by reducing the width of the channel portion or improving the brightness of the liquid crystal by reducing the size of the TFT have been proposed as compared with the prior art. From these, the pattern tends to be miniaturized, and on the other hand, it is expected that the required precision for the resist pattern shape to be obtained becomes higher.

MEANS TO SOLVE THE PROBLEM The present inventors pay attention to using the phase shift effect of a transflective film in response to said request, and exhibit the phase shift effect of a transflective film in the fine pattern area | region like the channel part of TFT, and the edge part has a rapid profile By obtaining a resist pattern, it was thought that manufacturing stability, such as TFT, can be improved and a yield can be improved.

On the other hand, in the multi-gradation photomask, it has conventionally been known to use a translucent film for a portion corresponding to the channel portion. However, when this translucent film is used as a phase shifter, exposure is transmitted through both at the boundary between the translucent portion and the transmissive portion. The light intensity of the light is canceled, resulting in dark lines. For this reason, it is necessary to suppress phase reversal of exposure light between the translucent portion and the transparent substrate.

Therefore, the inventors of the present invention exhibit the phase shift effect at the edge of the fine pattern region (for example, the channel portion) to increase the resolution, and further, by preventing the problem caused by the phase shift reversal substantially between the light transmitting portions. The present invention has found and found that the channel portion can provide a multi-gradation photomask in which a resist pattern having an abrupt profile of the edge can be obtained while preventing dark lines from appearing at the boundary portion between the semi-transmissive portion (channel portion) and the transparent portion. Invented.

That is, the core of the present invention forms a second semi-transmissive film and a first semi-transmissive film each having a predetermined light transmittance on the transparent substrate, and performs predetermined patterning, respectively, so that the light-transmitting portion, the first semi-transmissive portion, In the multi-gradation photomask formed by forming a transfer pattern including a second semi-transmissive portion having a portion adjacent to the first semi-transparent portion, the second semi-transmissive portion and the light-transmitting portion with respect to a representative wavelength within a range of i-g lines. The phase difference between and is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the first semi-transmissive relative to the representative wavelength. By using a multi-tone photomask in which the negative transmittance is less than 10% and the transmittance of the second semi-transmissive portion is 20% or more, a resist pattern having a sharp profile in the edge portion is obtained.

Here, the representative wavelength means any one wavelength among i-line, h-line, and g-line. In the multi-gradation photomask of the present invention, preferably, the above-described phase difference condition is satisfied for any wavelength in the range of the i line to the g line.

In addition, the transmittance | permeability of a 1st semi-transmissive part means the light transmittance of this 1st semi-transmissive part, when the film | membrane which consists of a single | mono layer or lamination is formed on a transparent substrate, and comprises the 1st semi-transmissive part. That is, the first semi-transmissive portion (here, when the line width is fine, the transmittance of light is changed, as described later if the line width is minute, so that the light transmittance having a sufficient width) to 100%, the first semi-transmissive portion (here Is also the transmittance of the first semi-transmissive portion having a sufficient width.

As this transmittance | permeability, you may design the photomask prescribed | regulated above which has a transmittance | permeability (henceforth a membrane transmittance | permeability) determined by the transparent substrate, the composition of a film | membrane, and a film thickness. However, in a photomask having a more precise pattern, since the effective transmittance under actual exposure light varies depending on the pattern shape, it is preferable to design the photomask as the effective transmittance described later.

FIG. 1A is a diagram showing a pattern of a part of the multi-gradation photomask according to the embodiment of the present invention. The pattern shown in FIG. 1 is a pattern formed by forming the 1st semi-transmissive part 12 and the 2nd semi-transmissive part 13 on the transparent substrate 11, Preferably, between the 1st semi-transmissive parts 12 Distance D is 2 micrometers-6 micrometers. A 1st semi-transmissive part is comprised by laminating | stacking a 2nd semi-transmissive film and a 1st semi-transmissive film on a transparent substrate, and a 2nd semi-transmissive part is comprised by forming a 2nd semi-transmissive film on a transparent substrate. Alternatively, the first semi-transmissive portion may be formed by forming a first semi-transmissive film on the transparent substrate, and the second semi-transmissive portion may be formed by forming a second semi-transmissive film on the transparent substrate. In addition, in FIG.1 (b), the light shielding part 14 is also formed by the light shielding film in this multi-gradation photomask.

In this multi-gradation photomask, the phase difference with respect to the exposure light (here, g-line as a representative wavelength) between the light transmitting portion 11 and the second semi-transmissive portion 13 is less than 90 degrees, preferably less than 60 degrees, Moreover, the phase difference between the 1st semi-transmissive part 12 and the 2nd semi-transmissive part 13 exceeds 90 degree | times, Preferably it is 180 +/- 30 degree | times.

Thus, by setting the phase difference with respect to the exposure light between the light transmitting part and the second semi-transmissive part, and the phase difference between the first semi-transmissive part 12 and the second semi-transmissive part 13 as described above, the first semi-transmissive The phase shift effect is obtained between the light portion 12 and the second semi-transmissive portion 13, and substantially does not cause the phase shift effect between the light-transmitter and the second semi-transmissive portion. For this reason, this multi-gradation photomask can obtain the resist pattern which has an abrupt profile in an edge, preventing a dark line from appearing in the boundary part between a 2nd semi-transmissive part and a translucent part.

As the transparent substrate 11, a glass substrate etc. are mentioned. As the first semi-transmissive membrane 12 and 13 which partially transmit the exposure light, chromium oxide, nitride, carbide, oxynitride, oxynitride carbide, metal silicide or the like can be used. In particular, a metal silicide film such as a molybdenum silicide (MoSix, MoSi oxide, nitride, carbide, oxynitride, oxynitride carbide) film or the like is preferable. In addition, the first semi-transmissive portion is configured by stacking a second semi-transmissive membrane and a first semi-transmissive membrane on a transparent substrate, and the second semi-transmissive portion is configured by forming a second semi-transmissive membrane on a transparent substrate, In the photomask of this invention, it is preferable to select the raw material with an etching selectivity for a 1st semi-transmissive film and a 2nd semi-transmissive film. For example, it is preferable to use oxide of chromium, nitride, etc. as a 1st semi-transmissive film, and to use a metal silicide type | system | group film as a 2nd semi-transmissive film.

Moreover, as a light shielding film which shields exposure light, metal silicide films, such as metal films, such as a chromium film, a silicon film, a metal oxide film, and a molybdenum silicide film, etc. are mentioned. As the light shielding film, a laminate of an antireflection film is preferably used. Examples of the antireflection film include chromium oxides, nitrides, carbides, fluorides, and the like.

In the multi-gradation photomask of the present invention, the transmittance of the first semi-transmissive film 12 is less than 10% when the transmittance of the transparent substrate 11 is 100%, and is 3% to 7%, especially 4% to It is preferable that it is 7%, and when the transmittance | permeability of the 2nd translucent film 13 makes the transmittance | permeability of the transparent substrate 11 100%, it is 20% or more, It is preferable that it is 20%-80%. Especially preferably, they are 30%-60%.

As a material which comprises a light shielding film, it is preferable to use what substantially does not transmit exposure light. However, when laminating | stacking a light shielding film with a 2nd semi-transmissive film and / or a 1st semi-transmissive film in a 1st semi-transmissive part, you may use the film | membrane of about 3.0 optical density with these films.

The multi-gradation photomask described above is provided with a first semi-transmissive portion B, a second semi-transmissive portion C, and a transmissive portion D, as shown in FIG. Such a multi-gradation photomask is, for example, as shown in Fig. 2A, on the first semi-transmissive portion B and the second semi-transmissive portion C 22 of the transparent substrate 21. Is formed, and the first semi-transmissive membrane 23 is formed on the first semi-transmissive portion B of the second semi-transmissive membrane 22.

Alternatively, in the multi-gradation photomask, as shown in FIG. 2B, a first semi-transmissive layer 23 is formed on the first semi-transmissive portion B of the transparent substrate 21, and on the second semi-transmissive portion C. The second semi-transmissive film 22 is formed. In the case shown in FIG.2 (b), the transmittance | permeability differs from a 1st semi-transmissive film and a 2nd semi-transmissive film.

Alternatively, in the multi-gradation photomask, as shown in FIG. 2C, the light blocking portion A, the first semi-transmissive portion B, the second semi-transmissive portion C, and the light-transmitting portion D are provided on the transparent substrate 21. Such a multi-gradation photomask forms a first semi-transmissive film 23 on the light-shielding portion A and the first semi-transmissive portion B of the transparent substrate 21, and the light-shielding film A on the light-shielding portion A of the first semi-transmissive film 23. 24, the anti-reflection film 25 and the second semi-transmissive film 22 are formed, and the second semi-transmissive film 22 is formed on the second semi-transmissive portion C of the transparent substrate 21.

Alternatively, as shown in FIG. 2D, the multi-gradation photomask includes the second semi-transmissive film 22 on the light-shielding portion A, the first semi-transmissive portion B, and the second semi-transmissive portion C of the transparent substrate 21. To form the first semi-transmissive film 23 on the light-shielding portion A and the first semi-transmissive portion B of the second semi-transmissive film 22, and the light-shielding film A on the light-shielding portion A of the first semi-translucent film 23 24) and the anti-reflection film 25 are formed.

In addition, the pattern shape in FIG. 2 is an example for showing a laminated structure typically, It is not limited to this.

The process of manufacturing the photomask of this invention is shown in FIGS.

Next, the structure shown to Fig.2 (a) can be manufactured by the process shown to Fig.3 (a)-(h), for example. In addition, the manufacturing method of the structure shown to Fig.2 (a) is not limited to these methods. Here, the material of the second translucent film 22 is made of molybdenum silicide, and the material of the first translucent film 23 is made of chromium oxide. In addition, in the following description, the resist material which comprises a resist layer, the etchant used at the time of an etching, the developing solution used at the time of image development, etc. select suitably what can be used by a conventional photolithography and an etching process. For example, an etchant is appropriately selected depending on the material constituting the etching target film, and a developer is appropriately selected depending on the resist material to be used.

As shown in FIG. 3A, a photomask blank on which the second translucent film 22 and the first translucent film 23 are formed is prepared on the transparent substrate 21, and a resist is formed on the photomask blank. The layer 26 is formed, and as shown in Fig. 3B, the resist layer 26 is exposed and developed so that the light transmitting portion D is exposed to form an opening. Next, as shown in Fig. 3C, the exposed first semi-transmissive film 23 is etched using this resist layer 26 (resist pattern) as a mask, and Fig. 3D is shown. The resist layer 26 is removed as shown in FIG.

Next, as shown in Fig. 3E, the exposed second semi-transmissive film 22 is etched using the first semi-transmissive film 23 as a mask. In addition, the second semi-transmissive film may be etched using the resist pattern in FIG. 3C as a mask.

Next, a resist is applied to the whole surface, and drawn and developed, so that the resist layer is in the region except the second semi-transmissive portion C on the first semi-transmissive film 23 as shown in FIG. (26) is formed, and the exposed first semitransmissive film 23 is etched using this resist layer 26 (resist pattern) as a mask as shown in Fig. 3G. Next, as shown in Fig. 3H, the resist layer 26 is removed. In this way, the structure as shown in Fig. 2A can be produced.

Next, the structure shown in (b) of FIG. 2 can be manufactured by the process shown to (a)-(h) of FIG. 4, for example. In addition, the manufacturing method of the structure shown in FIG.2 (b) is not limited to these methods. Here, the material of the second translucent film 22 is made of molybdenum silicide, and the material of the first translucent film 23 is made of chromium oxide. In addition, in the following description, the resist material which comprises a resist layer, the etchant used at the time of an etching, the developing solution used at the time of image development, etc. select suitably what can be used by a conventional photolithography and an etching process. For example, an etchant is appropriately selected depending on the material constituting the etching target film, and a developer is appropriately selected depending on the resist material to be used.

As shown in FIG. 4A, a photomask blank in which the first translucent film 23 is formed on the transparent substrate 21 is prepared, and a resist layer 26 is formed on the photomask blank. As shown in 4 (b), the resist layer 26 is exposed and developed so that the second semi-transmissive portion C and the transmissive portion D are exposed to form an opening. Next, as shown in Fig. 4C, the exposed first semi-transmissive film 23 is etched using this resist layer 26 (resist pattern) as a mask, and Fig. 4D is shown. The resist layer 26 is removed as shown in FIG.

Next, as shown in Fig. 4E, the second semi-transmissive film 22 is formed on the entire surface, and a resist is applied, drawn, and developed on the entire surface thereof, so that the second translucent film 22 is formed. As shown in FIG. 4, the resist layer 26 is formed in the region of the second semi-transmissive portion C of the second semi-transmissive film 22, and as shown in FIG. 4G, the resist layer 26 The exposed second semitransmissive film 22 is etched using (resist pattern) as a mask. Next, as shown in Fig. 4H, the resist layer 26 is removed. In this manner, the configuration as shown in Fig. 2B can be manufactured.

Next, the structure shown in (c) of FIG. 2 can be manufactured by the process shown to (a)-(h) of FIG. 5, for example. In addition, the manufacturing method of the structure shown to Fig.2 (c) is not limited to these methods. Here, the material of the second translucent film 22 is made of molybdenum silicide, and the material of the first translucent film 23 is made of chromium oxide. In addition, in the following description, the resist material which comprises a resist layer, the etchant used at the time of an etching, the developing solution used at the time of image development, etc. select suitably what can be used by a conventional photolithography and an etching process. For example, an etchant is appropriately selected depending on the material constituting the etching target film, and a developer is appropriately selected depending on the resist material to be used.

As shown in FIG. 5A, a photomask blank on which the first semi-transmissive film 23 and the light shielding film 24 (the antireflection film 25 is formed on the surface thereof) is formed on the transparent substrate 21. The resist layer 26 was prepared on this photomask blank, and the resist layer 26 was drawn so that the 2nd semi-transmissive part C and the transmissive part D may be exposed as shown in FIG.5 (b). Development to form an opening. Next, as shown in Fig. 5C, the exposed antireflection film 25 and the light shielding film 24 are etched using the resist layer 26 (resist pattern) as a mask, and then thereafter, Figs. As shown in 5d, the resist layer 26 is removed.

Next, as shown in Fig. 5E, the second semi-transmissive film 22 is formed on the entire surface. Next, as shown in Fig. 5F, the resist is applied to the entire surface. After coating, drawing and developing are performed to form a resist layer 26 on the light shielding portion A and the second translucent portion C of the antireflection film 25, and as shown in Fig. 5G, the resist layer ( 26) The second semi-transmissive film 22, the anti-reflection film 25, and the light shielding film 24 were etched using (resist pattern) as a mask, and then, as shown in Fig. 5H. The resist layer 26 is removed. In this way, the structure as shown in FIG.2 (c) can be manufactured.

Next, the structure shown in FIG.2 (d) can be manufactured by the process shown to FIG.6 (a)-(h), for example. In addition, the manufacturing method of the structure shown in FIG.2 (d) is not limited to these methods. Here, the material of the second translucent film 22 is made of molybdenum silicide, and the material of the first translucent film 23 is made of chromium oxide. In addition, in the following description, the resist material which comprises a resist layer, the etchant used at the time of an etching, the developing solution used at the time of image development, etc. select suitably what can be used by a conventional photolithography and an etching process. For example, an etchant is appropriately selected depending on the material constituting the etching target film, and a developer is appropriately selected depending on the resist material to be used.

As shown in FIG. 6A, the second semi-transmissive film 22, the first semi-transmissive film 23, and the light-shielding film 24 (the antireflection film 25 is formed on the surface of the transparent substrate 21). Formed), a resist layer 26 is formed on the photomask blank, and the second semi-transmissive portion C and the light-transmitting portion D are exposed as shown in FIG. The resist layer 26 is exposed and developed so as to form an opening. Next, as shown in Fig. 6C, using the resist layer 26 (resist pattern) as a mask, the exposed antireflection film 25 and the light shielding film 24 are etched, and then the figure is shown. As shown in 6 (d), the exposed first translucent film 23 is further etched to remove the resist layer 26.

Next, a resist is applied to the whole surface, drawing and developing, so that the light shielding portion A of the antireflection film 25 and the second semi-transmissive film 22 of the antireflection film 25 are shown as shown in FIG. A resist layer 26 is formed on the light portion C, and as shown in FIG. 6F, the antireflection film 25 and the light shielding film 24 exposed using the resist layer 26 (resist pattern) as a mask. Etch it. Next, as shown in Fig. 6G, the second semi-transmissive film 22 is etched using the resist layer 26 (resist pattern) as a mask, and then, in Fig. 6H. As shown, the resist layer 26 is removed. In this way, the structure as shown in Fig. 2D can be manufactured.

The transfer pattern of the multi-gradation photomask is transferred to the to-be-processed layer by irradiating the exposure light by an exposure machine using the above-mentioned multi-gradation photomask. Thereby, the cross-sectional shape is good in a semi-transmissive part, and the resist pattern of the residual film value of desired thickness can be obtained.

Here, the Example performed in order to clarify the effect of this invention is demonstrated.

(A), (c), (e) is a top view which shows a multi-gradation photomask, (b), (d), (f) of FIG. 7 is (a), (c), It is a figure which shows the cross section of the resist pattern formed in the resist film on the to-be-transferred body by exposing using the multi-gradation photomask shown in (e).

In the multi-gradation photomask shown in FIG. 7A, the second semi-transmissive film 33 is formed on the transparent substrate 31, and among these, only the portion forming the first semi-transmissive portion, The 1st semi-transmissive film 32 is laminated | stacked and comprised. Here, the laminated film of the first semi-transmissive portion and the second semi-transmissive portion of the second semi-transmissive portion adjust the refractive index and the film thickness of each film so that the phase difference in the exposure light (here, the representative wavelength g line) is approximately 180 degrees. I am getting it. In addition, the relationship between a film thickness and a refractive index can be calculated | required by following formula (1). Here, phi represents a phase shift amount, n represents a refractive index, and d represents a film thickness.

d = (φ / 360) × [λ / (n-1)]

In addition, the phase difference between the 2nd semi-transmissive film 33 and the transparent part 31 was less than 30 degree | times. In addition, the transmittance | permeability of the 2nd semi-transmissive membrane was 50%, and the transmittance | permeability of the 1st semi-transmissive membrane was 5%. The resist pattern formed by pattern transfer using such a multi-gradation photomask has a cross-sectional shape as shown in Fig. 7B. That is, in the recesses 42a to 42c of the resist layer 42 formed on the substrate 41, the edge is prominent due to the effect of the phase, and even if the line width is the smallest (reference 42a), the side surface and the horizontal plane The angle (taper angle) which is made between is larger than the comparative example mentioned later.

In the multi-gradation photomask shown in FIG. 7C, the light shielding film 34 is further laminated by patterning on the first semi-transmissive portion of the photomask having the same configuration as described above. Here, the light shielding film is formed on the first semi-transmissive film, leaving the periphery of the first semi-transmissive portion on the second semi-transmissive portion about 5 μm. The film material and the film thickness were adjusted to have the same phase difference as above. The resist pattern formed by pattern transfer using such a multi-gradation photomask has a cross-sectional shape as shown in Fig. 7D. That is, in the recesses 42a to 42c of the resist layer 42 formed on the substrate 41, the edge is prominent due to the effect of the phase, and even if the line width is the smallest (reference 42a), between the side and the horizontal plane. Angle (taper angle) is large. In this case, since the light shielding film 34 is formed in the portion where the resist layer is to be left, there is no film reduction of the resist layer 42.

In the multi-gradation photomask (comparative example) shown in Fig. 7E, a light-transmitting film 34 is formed on the transparent substrate 31, and the light shielding film 34 is formed only in a portion to serve as a light shielding portion. ) Is a conventional multi-gradation photomask. The resist pattern formed by pattern transfer using such a multi-gradation photomask has a cross-sectional shape as shown in Fig. 7F. That is, in the recesses 42a to 42c of the resist layer 42 formed on the substrate 41, the angle (taper angle) between the side surface and the horizontal surface is small, and in particular, the line width is small (reference numeral 42a) or the recess In the section 42b, the cross section is curved.

As described above, since the phase shift effect is obtained between the first semi-transmissive portion and the second semi-transmissive portion and the phase shift effect is suppressed between the transmissive portion and the second semi-transmissive membrane, the second The resist pattern which has an abrupt profile of an edge can be obtained, preventing a dark line from appearing at the boundary part between a translucent part and a translucent part. As a result, in the process of panel manufacture, when obtaining the resist pattern of desired line | wire width, the margin of processing conditions can be taken large.

In addition, as shown in FIG. 8, even when the translucent part is formed using the same translucent film, when the line width of patterning differs, the residual film value of the resist pattern obtained by exposing the said photomask may not become the same. . That is, when the line width of the semi-transmissive portion becomes smaller than a predetermined dimension (for example, 5 μm), since the diffraction occurs due to the limitation of the resolution of the optical system of the exposure machine, the intensity of the exposure light passing through the pattern of the semi-transmissive portion The distribution changes.

For example, in the photomask for manufacturing a liquid crystal display device, a portion corresponding to the channel portion may be formed in the transflective portion, and portions corresponding to the source and drain may be formed in the light shielding portion. In such a pattern, the transflective portion having the portion adjacent to the light shielding portion decreases the transmittance in the vicinity of the adjacent portion due to the influence of diffraction under the optical conditions of the exposure machine (at the resolution of the exposure unit). For example, as shown to (a) and (b) of FIG. 8, the light intensity distribution of the transmitted light of the semi-transmissive area | region B pinched by the light shielding part A falls generally, and a peak falls. This tendency is more prominent as the line width of the semi-transmissive region B becomes smaller. In particular, in the channel portion having a small line width surrounded by the source and drain, the exposure light transmittance is lower than that of the used semi-transmissive film. do. In other words, the transmittance of the semi-transmissive portion actually used in the pattern is different from the inherent transmittance of the semi-transmissive membrane found in a sufficiently large area. Therefore, about the inspection of the transmittance | permeability after the said patterning, it is preferable to carry out based on the effective transmittance rather than the intrinsic transmittance | permeability of a translucent film.

Of course, in the semi-transmissive portion adjacent to the transmissive portion, the smaller the line width of the semi-transmissive portion is, the effect of diffraction of the exposure light is, more effectively, than the light transmittance inherent in the translucent film.

As means for measuring said effective transmittance | permeability, it is preferable to reproduce or approximate the exposure conditions by an exposure machine. As such an apparatus, the apparatus shown in FIG. 9 is mentioned, for example. This apparatus comprises a light source 51, an irradiation optical system 52 for irradiating light from the light source 51 to the photomask 53, and an objective lens system 54 for forming light transmitted through the photomask 53. And an imaging means 55 for imaging an image obtained through the objective lens system 54.

The light source 51 emits a light beam having a predetermined wavelength, and for example, a halogen lamp, a metal halide lamp, a UHP lamp (ultra high pressure mercury lamp), or the like can be used. For example, it can use as a light source which has the spectral characteristic approximating the exposure machine using a mask.

The irradiation optical system 52 guides the light from the light source 51 to irradiate the photomask 53 with light. This irradiation optical system 52 is provided with an aperture mechanism (opening aperture 57) in order to make the numerical aperture NA variable. It is preferable that this irradiation optical system 52 is provided with the visual field stop 56 for adjusting the irradiation range of the light in the photomask 53. As shown in FIG. Light passing through the irradiation optical system 52 is irradiated to the photomask 53 held by the mask holder 53a. This irradiation optical system 52 is disposed in the case 63.

The photomask 53 is held by the mask holder 53a. The mask holder 53a supports the lower end of the photomask 53 and the vicinity of the side edges of the photomask 53 while the main plane of the photomask 53 is approximately vertical, and tilts the photomask 53. It is fixed and kept. The mask holder 53a is a photomask 53, which is a large mask (e.g., 1220 mm x 1400 mm, 13 mm thick or more), or photomask 53 of various sizes. ) To maintain. In addition, substantially vertical means that the angle from the vertical shown by (theta) in FIG. 9 is within about 10 degrees. Light irradiated to the photomask 53 passes through the photomask 53 and is incident on the objective lens system 54.

The objective lens system 54 includes, for example, a first group (simulator lens) 54a in which light passing through the photomask 53 is incident, infinity correction is applied to the light beam, and the light is parallel. It consists of the 2nd group (imaging lens) 54b which forms the light beam which passed through 1 group. The aperture lens (aperture aperture 57) is equipped with the simulator lens 54a, and the numerical aperture NA is variable. The light beam passing through the objective lens system 54 is received by the imaging means 55. This objective lens system 54 is disposed in the case 63.

The imaging means 55 captures an image of the photomask 53. As this imaging means 55, imaging elements, such as CCD, can be used, for example.

In this apparatus, since the numerical aperture of the irradiation optical system 52 and the numerical aperture of the objective lens system 54 are respectively variable, the ratio of the numerical aperture of the irradiation optical system 52 to the numerical aperture of the objective lens system 54, that is, The sigma value (σ: coherency) can be varied.

Moreover, in this apparatus, the control means which has the calculation means 61 and the display means 62 which perform image processing, an operation, the comparison with a predetermined threshold value, and display with respect to the picked-up image obtained by the imaging means 55, etc. The movement operation means 65 which changes the position of 64 and the case 63 is provided. For this reason, a predetermined calculation is performed by a control means using the obtained captured image or the light intensity distribution obtained based on this, and the picked-up image under the conditions using other exposure light, or light intensity distribution and transmittance | permeability can be calculated | required. .

In the apparatus shown in Fig. 9 having such a configuration, since the NA and sigma values are variable, and the source of the light source can also be changed, the exposure conditions of various exposure machines can be reproduced. In general, in the case of simply approximating an exposure apparatus of a large photomask, such as for manufacturing a liquid crystal device, NA is 0.08 as the exposure optical system using irradiation light obtained by equalizing the light intensities of i-line, h-line, and g-line. What is necessary is just to apply the conditions whose coherence (sigma) which is the NA ratio of an irradiation system and an objective system is about 0.8.

In view of the above, in the present invention, based on the pattern shape and the semi-transmissive film to be used (preferably considering the light source wavelength distribution of the exposure machine and the conditions of the optical system), from the transmittance (effective transmittance) of the photomask actually to be obtained. It is preferable to calculate the transmittance (transmittance in a sufficiently large area) of the semi-transmissive film to be used, and to design the photomask.

Moreover, it is preferable that the transmittance | permeability of the 1st, 2nd translucent part used as the management value of this invention is based on the said effective transmittance | permeability. In addition, as an effective transmittance value used here, it can cover as a peak value of light intensity distribution in FIG. This correlates with the resist residual film value on the transfer target when the mask is used.

In addition, it is preferable that the photomask of this invention confirms and evaluates a light transmittance characteristic using the apparatus shown in FIG. The cancellation of transmitted light due to phase inversion and the change in light intensity distribution due to diffraction can be comprehensively evaluated as the light intensity distribution received by the transfer target when the mask is used, and the profile of the resist pattern to be formed is based on the most realistic method. Can be evaluated by.

The present invention is not limited to the above embodiment, and various modifications are possible. In particular, it goes without saying that the number, size, processing procedure, etc. of the members in the above embodiment can be variously changed.

1 (a) and 1 (b) show a pattern of a part of a multi-gradation photomask according to an embodiment of the present invention.

2 (a) to 2 (d) show the structure of a multi-gradation photomask according to an embodiment of the present invention.

FIG.3 (a)-(h) are figures for demonstrating the manufacturing method of the structure of the multi-gradation photomask shown to FIG. 2 (a).

4 (a) to 4 (h) are diagrams for explaining a method for producing a structure of a multi-gradation photomask shown in FIG. 2 (b).

5 (a) to 5 (h) are diagrams for explaining a method of manufacturing the structure of the multi-gradation photomask shown in FIG. 2 (c).

6 (a) to 6 (h) are diagrams for explaining a method for producing a structure of a multi-gradation photomask shown in FIG. 2 (d).

(A), (c), (e) is a top view which shows a multi-gradation photomask, (b), (d), (f) is (a), (c), (e) A resist pattern formed using the multi-gradation photomask shown in FIG.

8A and 8B are diagrams showing patterns of light shielding films and semi-transmissive films and light intensity distributions corresponding thereto.

9 shows an example of an apparatus for reproducing exposure conditions of an exposure machine.

10 is a diagram showing a pattern of a part of a conventional multi-gradation photomask.

<Explanation of symbols for the main parts of the drawings>

11: transparent substrate

12: first translucent part

13: second translucent part

14: shading part

61 calculation means

62 Display Means

64 control means

65 means of movement

Claims (15)

On the transparent substrate, a first semi-transmissive film and a second semi-transmissive film each having a predetermined light transmittance are respectively formed, and predetermined patterning is performed respectively, so as to be adjacent to the light-transmitting portion, the first semi-transmissive portion, and the first semi-transmissive portion. A multi-gradation photomask formed by forming a transfer pattern including a second semi-transmissive portion having a portion, wherein a phase difference between the second semi-transmissive portion and the light-transmitting portion is 90 with respect to a representative wavelength within a range of i to g-lines. Less than a degree, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the transmittance of the first semi-transmissive portion is less than 10% with respect to the representative wavelength. And a transmittance of the second semi-transmissive portion is 20% or more. The method of claim 1, A multi-gradation photomask, wherein the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is 180 degrees ± 30 degrees with respect to the representative wavelength. The method of claim 2, The multi-gradation photomask, wherein the phase difference between the second semi-transmissive portion and the light-transmitting portion is less than 60 degrees with respect to the representative wavelength. The method of claim 3, The first semi-transmissive portion is configured by stacking a second semi-transmissive film and a first semi-transmissive film on the transparent substrate, and the second semi-transmissive portion is formed by forming a second semi-transmissive film on the transparent substrate. Multi-gradation photomask. The method of claim 3, The first semi-transmissive portion is formed by forming a first translucent film on the transparent substrate, and the second semi-transmissive portion is formed by forming a second translucent film on the transparent substrate. The method of claim 1, A first translucent portion, a second translucent portion, and a transfer pattern in which the first translucent portion is arranged in this order, wherein the first translucent portion has a portion adjacent to the transmissive portion, and with respect to the representative wavelength, A multi-gradation photomask, wherein the transmittance of the first semi-transmissive portion is 3% to 7% and the transmittance of the second semi-transmissive portion is 20% to 80%. On the transparent substrate, a light-transmitting portion, a first semi-transmissive portion, and a first semi-transmissive portion are formed by forming a second semi-transmissive film and a first semi-transmissive film, each having a predetermined light transmittance, and a light-shielding film, and performing predetermined patterning, respectively. A multi-gradation photomask formed by forming a transfer pattern comprising a second semi-transmissive portion having a portion adjacent to and a light-shielding portion, between the second semi-transmissive portion and the light-transmitting portion with respect to a representative wavelength within a range of i-g lines. The phase difference of is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the transmittance of the first semi-transmissive portion is Less than 10%, the second semi-transmissive portion has a transmittance of 20% or more, and has a transfer pattern in which the light-shielding portion, the first semi-transmissive portion, the second semi-transmissive portion, the first semi-transmissive portion, and the light-shielding portion are arranged in this order. Multisystem to say Photomasks. Preparing a photomask blank in which a second semitransmissive film, a first semitransmissive film, and a light shielding film are laminated on the transparent substrate in this order; forming a first resist pattern on the photomask blank; The process of pattern-processing the said 1st semi-transmissive film by etching using the resist pattern or the light shielding film patterned by the etching using the said 1st resist pattern as a mask, and the said light shielding film and the 1st board | substrate Fabrication of a multi-gradation photomask comprising a step of forming a second resist pattern on a substrate surface including a light-transmitting film and a step of patterning at least the second semi-transmissive film by etching using the second resist pattern as a mask. As a method, the phase difference between the said 2nd semi-transmissive part and the light transmissive part is less than 90 degree with respect to the representative wavelength in the range of i line | wire (g)-the said representative wavelength. The phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees, the transmittance of the first semi-transmissive portion is less than 10% with respect to the representative wavelength, and the second semi-transparent portion A method for producing a multi-gradation photomask, wherein the transmittance is 20% or more. Preparing a photomask blank in which a first translucent film and a light shielding film are laminated on the transparent substrate in this order; forming a first resist pattern on the photomask blank; and the first resist pattern or the first agent. A substrate comprising a step of pattern-processing the first semi-transmissive film by etching using a light-shielding film patterned by etching using a resist pattern as a mask, and a patterned, light-shielding film, and a first semi-transmissive film Forming a second semi-transmissive film on the surface, forming a second resist pattern on the second semi-transmissive film, and etching at least the second semi-transmissive film by etching using the second resist pattern as a mask A method of manufacturing a multi-gradation photomask having a step of processing, wherein the second semi-transmissive portion and the light-transmitting portion are used for a representative wavelength within a range of i-g lines. The phase difference of is less than 90 degrees, the phase difference between the first semi-transmissive portion and the second semi-transmissive portion is greater than 90 degrees with respect to the representative wavelength, and the transmittance of the first semi-transmissive portion is Less than 10%, and the second semi-transmissive portion has a transmittance of 20% or more. The transfer pattern is transferred to a resist film on the transfer object by an exposure machine that irradiates irradiated light in a wavelength region of i-g line using the multi-gradation photomask of any one of claims 1 to 7. Pattern transfer method, characterized in that. The method of claim 10, The pattern transfer method according to claim 1, wherein the resist film on the transfer member has substantially no sensitivity with respect to an exposure amount of a portion corresponding to the first translucent portion. The method of claim 11, The resist film on the transfer object is reduced after the development, corresponding to the exposure amount of the portion corresponding to the second translucent portion, and based on the film reduction amount, the resist film thickness on the transfer material is previously determined. Pattern transfer method, characterized in that. A thin film transistor is manufactured using the pattern transfer method of claim 10, wherein the thin film transistor is manufactured. A thin film transistor is manufactured using the pattern transfer method of claim 11, wherein the thin film transistor is manufactured. A thin film transistor is manufactured using the pattern transfer method of claim 12, wherein the thin film transistor is manufactured.

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