Patent Publication Number: US-10777422-B2

Title: Method for processing target object

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
     This application is a Continuation of U.S. patent application Ser. No. 16/135,178, filed on Sep. 19, 2018, which is a Continuation-in-part of International Application No. PCT/JP2017/019024, filed on May 22, 2017, which claims priority from Japanese Patent Application No. 2016-104414, filed on May 25, 2016, all of which are incorporated herein in their entireties by reference. 
    
    
     TECHNICAL FIELD 
     An embodiment of the present disclosure relates to a method for processing a target object. 
     BACKGROUND 
     In a manufacturing process of an electronic device such as a semiconductor device, a mask is formed on a target layer, and etching is performed for transferring a pattern of the mask to the target layer. As the mask, a resist mask is generally used. The resist mask is formed by a photolithography technology. Accordingly, a critical dimension of a pattern formed on a layer to be etched is influenced by, for example, a resolution limit of the resist mask formed by the photolithography technology and a pattern density. However, recently, with the high integration of electronic devices, it is required to form a pattern having dimensions smaller than the resolution limit of the resist mask. Therefore, as described in Japanese Patent Application Laid-Open No. 2004-080033, there has been suggested a technology for decreasing a width of an opening provided by a resist mask by forming a silicon oxide film on the resist mask and adjusting the dimensions of the resist mask. 
     In a method of forming a micro-pattern disclosed in Japanese Patent Application Laid-Open No. 2004-080033, a photoresist pattern is formed on a material film on which a micro pattern is to be formed, and then a silicon oxide film is deposited on the material film, but the silicon oxide film needs to be conformally thinly formed without damaging the photoresist pattern thereunder. Then, dry etching is also performed on a lower film, but at an initial stage, a spacer is formed on a lateral wall of the photoresist pattern and subsequently a polymer film is formed on the photoresist pattern. 
     SUMMARY 
     In an aspect, a method for processing a target object is provided. The method includes: a first step of adjusting a width of a mask pattern of a mask provided on a main surface of a target layer included in the target object, the main surface being divided into a plurality of areas; and a second step of etching the target layer by using the mask after the first step. The first step includes: a third step of measuring the width of the mask pattern for each of the plurality of areas of the main surface, a fourth step of calculating a positive difference value obtained by subtracting a reference value of the width of the mask pattern from the width of the mask pattern measured in the third step for each of the plurality of areas of the main surface after the third step; and a fifth step of forming a film having a thickness of the positive difference value of each of the plurality of areas of the main surface calculated in the fourth step on a surface of the mask of the target object introduced into a processing container of a plasma processing device after the fourth step. The fifth step includes: a sixth step of supplying first gas into the processing container; a seventh step of purging an inside of the processing container after the sixth step; an eighth step of generating plasma of second gas within the processing container after the seventh step; a ninth step of purging the inside of the processing container after the eighth step; and repeating the sixth step to ninth step thereby forming a film on a surface of the mask. In the fifth step, a temperature of the target layer of the target object introduced into the processing container is adjusted for each of the plurality of areas by using pre-acquired correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a film deposited on the surface of the mask on the target layer, and a film thickness corresponding to the difference value calculated for each of the plurality of areas in the fourth step; and a processing time required in the sixth step falls within a time period during which the film thickness of the film deposited on the surface of the mask on the target layer increases or decreases according to a temperature of the target layer in the sixth step. 
     The foregoing summary is illustrative only and is not intended to be in any way limiting. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features will become apparent by reference to the drawings and the following detailed description. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a flowchart illustrating a method for processing a target object according to an embodiment. 
         FIG. 2  is a cross-sectional view illustrating a target object to which the method illustrated in  FIG. 1  is applied. 
         FIG. 3  is a diagram illustrating an example of a processing system, which is usable for carrying out the method illustrated in  FIG. 1 . 
         FIG. 4  is a diagram illustrating an example of a plasma processing device, which may include the processing system illustrated in  FIG. 3 . 
         FIG. 5  is a flowchart illustrating an example of a step of adjusting a groove width of a pattern before etching, which is a step that may be included in the method illustrated in  FIG. 1 . 
         FIG. 6A  is a cross-sectional view illustrating a state of an target object before the steps illustrated in  FIG. 5  is performed, and  FIG. 6B  is a cross-sectional view illustrating a state of the target object after the steps illustrated in  FIG. 5  is performed. 
         FIG. 7  is a diagram schematically illustrating some of a plurality of divided areas of a main surface of a target object in the method for processing a target object according to an embodiment as an example. 
         FIG. 8  is a flowchart illustrating an example of a step of adjusting a groove width of a pattern, which is a part of the steps illustrated in  FIG. 5 . 
         FIG. 9  is a flowchart illustrating an example of a step of forming a uniform film on a main surface of the target object, which may be included in the steps illustrated in  FIG. 8 . 
         FIG. 10A  is a diagram schematically illustrating a state of a target object before the sequence illustrated in each of  FIGS. 8 and 9  is executed,  FIG. 10B  is a diagram schematically illustrating a state of the target object during execution of the sequence illustrated in each of  FIGS. 8 and 9 , and  FIG. 10C  is a diagram schematically illustrating a state of the target object after the sequence illustrated in each of  FIGS. 8 and 9  is executed. 
     
    
    
     DETAILED DESCRIPTION 
     In the following detailed description, reference is made to the accompanying drawing, which form a part hereof. The illustrative embodiments described in the detailed description, drawing, and claims are not meant to be limiting. Other embodiments may be utilized, and other changes may be made, without departing from the spirit or scope of the subject matter presented here. 
     When a pattern having a smaller value than a resolution limit of a resist mask is formed, there is a demand for very precisely controlling a critical dimension (CD) of a groove of the pattern. When the pattern is elaborate, an influence by a variation in the critical dimension is increased. Accordingly, in forming a pattern on an target object, there is a need for implementing a method of suppressing a variation in the highly precise critical dimension in order to achieve the miniaturization with high integration. 
     In an aspect, a method for processing a target object is provided. The method includes: a first step of adjusting a width of a mask pattern of a mask provided on a main surface of a target layer included in the target object, the main surface being divided into a plurality of areas; and a second step of etching the target layer by using the mask after the first step. The first step includes: a third step of measuring the width of the mask pattern for each of the plurality of areas of the main surface, a fourth step of calculating a positive difference value obtained by subtracting a reference value of the width of the mask pattern from the width of the mask pattern measured in the third step for each of the plurality of areas of the main surface after the third step; and a fifth step of forming a film having a thickness of the positive difference value of each of the plurality of areas of the main surface calculated in the fourth step on a surface of the mask of the target object introduced into a processing container of a plasma processing device after the fourth step. The fifth step includes: a sixth step of supplying first gas into the processing container; a seventh step of purging an inside of the processing container after the sixth step; an eighth step of generating plasma of second gas within the processing container after the seventh step; a ninth step of purging the inside of the processing container after the eighth step; and repeating the sixth step to ninth step thereby forming a film on a surface of the mask. In the fifth step, a temperature of the target layer of the target object introduced into the processing container is adjusted for each of the plurality of areas by using pre-acquired correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a film deposited on the surface of the mask on the target layer, and a film thickness corresponding to the difference value calculated for each of the plurality of areas in the fourth step; and a processing time required in the sixth step falls within a time period during which the film thickness of the film deposited on the surface of the mask on the target layer increases or decreases according to a temperature of the target layer in the sixth step. 
     In the method, before the second step of etching the target layer, the first step of adjusting the width of the mask pattern of the mask is performed. In the first step, the main surface of the target layer is divided into a plurality of areas, in the third and fourth steps, a difference value between the width of the mask pattern and the reference value of the width is calculated for each of the plurality of areas, and in the fifth step, a film having a film thickness corresponding to the difference value is formed on the mask and the width of the mask pattern in each of the plurality of areas is corrected to the reference value. In the fifth step, the film is very precisely formed in each atom layer on the mask by the same method as an atomic layer deposition (ALD) method by using the film forming processing in which the sixth step to the ninth step are repeatedly executed. Since the film thickness of the film formed by the film forming processing is different according to a temperature of the target layer, in the tenth step, the temperature of the target layer is adjusted so that the temperature of the target layer becomes a temperature required for forming a film having the film thickness corresponding to the difference value calculated in the fourth step for each of the plurality of areas by using correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a formed film. As described above, before the etching performed in the second step, a film thickness corresponding to a correction amount of the mask pattern is determined for each of the plurality of areas of the main surface of the target layer, a temperature of the target layer required for forming the film thickness is determined by using the correspondence data, and the same film forming processing as the ALD method is performed in the state where the temperature of the target layer is adjusted to the temperature determined for each of the plurality of areas, so that the variation of the pattern of the mask may be precisely and sufficiently suppressed for each of the plurality of areas of the main surface of the target layer. 
     In an embodiment, the temperature of the target layer is adjusted based on the correspondence data for each of the plurality of areas such that a temperature of each of the plurality of areas in the target layer of the target object introduced into the processing container becomes a temperature corresponding to a film thickness of the difference value calculated for each of the plurality of areas in the fourth step. 
     In an embodiment, in the fifth step the film on the surface of the mask is conformally formed regardless of the plurality of areas, the temperature of the target layer is adjusted based on the correspondence data for each of the plurality of areas such that a temperature of each of the plurality of areas in the target layer of the target object introduced into the processing container becomes a temperature corresponding to a value obtained by subtracting a film thickness of the film conformally formed from a film thickness of the difference value calculated for each of the plurality of areas, and adjusting the temperature of the layer based on the correspondence data for each of the plurality of areas is performed before adjusting the temperature of the layer using the pre-acquired correspondence data or after the film forming processing. As described above, for a common film thickness among the film thicknesses of the plural areas, it is possible to partially form the film without adjusting a temperature of the target layer performed on each of the plurality of areas. 
     In an embodiment, the first step includes re-executing the third step and the fourth step after execution of the fifth step, and re-executing the fifth step when the re-execution of the third step and the fourth step does not cause a difference value calculated in the fourth step to satisfy a preset reference range. As described above, after the film is formed by the fifth step, a difference value of the width of the mask pattern is calculated again, it is determined whether the difference value is within a reference range, and the forming of the film is performed again when the difference value is not within the reference range, so that the variation of the width of the mask pattern may be further sufficiently suppressed. 
     In an embodiment, the first gas may include an aminosilane-based gas, and the second gas may include a gas containing oxygen atoms and carbon atoms. 
     In an embodiment, aminosilane-based gas of the first gas may include aminosilane having one to three silicon atoms. The aminosilane-based gas of the first gas may include aminosilane having one to three amino groups. As described above, as the aminosilane-based gas of the first gas, aminosilane having one to three silicon atoms may be used. Further, as the aminosilane-based gas of the first gas, aminosilane having one to three amino groups may be used. 
     In another aspect, a method for processing a target object is provided. The method includes: measuring a width of a mask pattern of a mask provided on a surface of a target layer included in a target object for each of a plurality of areas formed on the surface of the target layer; calculating a positive difference value obtained by substracting a predetermined reference value from the measured width of the mask pattern for each of the plurality of areas; adjusting a temperature of the target layer for each of the plurality of areas such that a film having a film thickness corresponding to the difference value is formed by using pre-acquired correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a film deposited on the surface of the mask on the target layer, and the difference value calculated for each of the plurality of areas; and forming a film having the film thickness of the difference value for each of the plurality of areas on the surface of the mask of the target object by using an atomic layer deposition, after the adjusting. 
     In the embodiment, the forming may be performed by repeatedly executing a sequence including: supplying a first gas into a processing container; purging an inside of the processing container; and generating plasma of a second gas within the processing container. 
     In the embodiment, a time for supplying the first gas may fall within a time period during which the film thickness of the film deposited on the surface of the mask increases or decreases according to an increase or decrease in temperature of the target layer. 
     In the embodiment, the method further includes: measuring a width of the mask pattern of the mask formed with the film after the forming for each of the plurality of areas; and determining whether or not re-adjustment of the width is required. 
     In the embodiment, the method further includes: etching the target layer using the mask having a pattern width adjusted by the forming. 
     In the embodiment, the adjusting of the temperature, the forming, and the etching are performed in a processing container without unloading the target object. 
     In yet another aspect, a method for processing a target object is provided. The method includes: a first step of adjusting a width of a pattern of a first mask provided on a surface of a first film of a target layer of a target object; a second step of etching the first film using the first mask after the first step to form a second mask; a third step of adjusting a width of a pattern of the second mask; and a fourth step of etching the target layer using the second mask the width of which is adjusted. The first step includes: measuring the width of the pattern of the first mask for each of a plurality of areas formed in the first film; calculating a positive difference value obtained by substracting a predetermined reference width from the measured value of the width for each of the plurality of areas; adjusting a temperature of the target layer for each of the plurality of areas such that a film having a film thickness corresponding to the difference value is formed by using pre-acquired correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a film deposited on the surface of the mask on the target layer, and the difference value calculated for each of the plurality of areas; and forming a film having the film thickness of the difference value for each of the plurality of areas on the surface of the mask of the target object by using an atomic layer deposition, after the adjusting. The third step includes: measuring the width of the pattern of the second mask for each of a plurality of areas; calculating a positive difference value obtained by subtracting a predetermined reference width from the measured value of the width for each of the plurality of areas; adjusting a temperature of the target layer for each of the plurality of areas such that a film having a film thickness corresponding to the difference value is formed by using pre-acquired correspondence data indicating correspondence between a temperature of the target layer and a film thickness of a film deposited on the surface of the second mask on the target layer, and the difference value calculated for each of the plurality of areas; and forming a film having the film thickness of the difference value for each of the plurality of areas on the surface of the mask of the target object by using an atomic layer deposition, after the adjusting. 
     As described above, there is provided the method of suppressing a variation in a highly precise critical dimension in forming a pattern on an target object. 
     Hereinafter, various embodiments will be described in detail with reference to the drawings. Further, in each drawing, the same reference numeral is given to the same or similar parts. 
       FIG. 1  is a flowchart illustrating a method for processing a target object according to an embodiment. Method MT illustrated in  FIG. 1  is an embodiment of a method for processing a target object.  FIG. 2  is a cross-sectional view illustrating a target object (hereinafter, referred to as a wafer W), which is a target of application of method MT illustrated in  FIG. 1 . A wafer W illustrated in  FIG. 2  includes a substrate BA, a layer to be etched EL 2 , a layer to be etched EL 1 , an organic film OL, an antireflection film AL, and a mask MK. 
     The layer to be etched EL 2  is provided on the substrate BA. The layer to be etched EL 1  is provided on the layer to be etched EL 2 . The layer to be etched EL 1  and the layer to be etched EL 2  are layers containing silicon, and for example, amorphous silicon layers or polycrystalline silicon layers. The organic film OL is a film formed of an organic material and is provided on the layer to be etched EL 1 . The antireflection film AL is an antireflection film containing Si, and is provided on the organic film OL. The mask MK is provided on the antireflection film AL and on a main surface FW of the wafer W. The mask MK is a mask formed of an organic material, and for example, a resist mask. A pattern providing an opening is formed in the mask MK by photolithography. 
     Method MT (the method for processing the target object) is executed by a processing system including a plasma processing device.  FIG. 3  is a diagram illustrating an example of a processing system, which is usable for carrying out method MT illustrated in  FIG. 1 . The processing system  1  illustrated in  FIG. 3  includes a control unit Cnt, a table  122   a,  a table  122   b,  a table  122   c,  and a table  122   d,  an accommodating container  124   a,  an accommodating container  124   b,  an accommodating container  124   c,  and an accommodating container  124   d,  a loader module LM, a load lock chamber LL 1 , a load lock chamber LL 2 , a transfer chamber  121 , ad a plasma processing apparatus  10 . 
     The control unit Cnt is a computer including a processor, a storage unit, an input device, and a display device, and controls each unit of the processing system  1 , which will be described below. The control unit Cnt is connected to a transport robot Rb 1 , a transport robot Rb 2 , an optical observation device OC, and the plasma processing apparatus  10 . Further, in the plasma processing apparatus  10  illustrated in  FIG. 4 , which will be described below, the control unit Cnt is connected to a valve group  42 , a flow rate controller group  44 , an exhaust device  50 , a first high frequency power supply  62 , a matcher  66 , a second high frequency power supply  64 , a matcher  68 , a power supply  70 , a heater power supply HP, and a chiller unit. 
     The control unit Cnt is operated according to a computer program (a program based on an input recipe) for controlling each unit of the processing system  1  in each step of method MT and transmits a control signal. Each unit, for example, the transport robots Rb 1  and Rb 2 , the optical observation device OC, and the plasma processing apparatus  10  of the processing system  1  is controlled by the control signal from the control unit Cnt. In the plasma processing apparatus  10  illustrated in  FIG. 4 , by the control signal from the control unit Cnt, it is possible to control a selection and a flow rate of gas supplied from the gas source group  40 , the exhaust of the exhaust device  50 , supply of power from the first high frequency power supply  62  and the second high frequency power supply  64 , application of a voltage from the power supply  70 , supply of power from the heater power supply HP, and a coolant flow rate and a coolant temperature from the chiller unit. Further, each step of method MT for processing the target object disclosed in the present specification may be executed by operating each unit of the processing system  1  under the control of the control unit Cnt. In the storage unit of the control unit Cnt, a computer program for executing method MT and various data (for example, corresponding data DT to be described below) used for executing method MT are stored to be readable. 
     The tables  122   a  to  122   d  are arranged along an edge of the loader module LM. The accommodating containers  124   a  to  124   d  are provided in the tables  122   a  to  122   d,  respectively. The wafers W may be accommodated in the accommodating containers  124   a  to  124   d.    
     The transport robot Rb 1  is provided inside the loader module LM. The transport robot Rb 1  takes out the wafer W accommodated in any one of the accommodating containers  124   a  to  124   d  and transports the wafer W to the load lock chamber LL 1  or LL 2 . 
     The load lock chamber LL 1  and LL 2  are provided along another edge of the loader module LM and connected to the loader module LM. The load lock chambers LL 1  and LL 2  constitute a preliminary depression chamber. Each of the load lock chambers LL 1  and LL 2  is connected to the transfer chamber  121 . 
     The transfer chamber  121  is a chamber, which is capable of decompressing pressure, and the transport robot Rb 2  is provided inside the transfer chamber  121 . The plasma processing apparatus  10  is connected to the transfer chamber  121 . The transport robot Rb 2  take outs the wafer W from the load lock chamber LL 1  or the load lock chamber LL 2  and transports the wafer W to the plasma processing apparatus  10 . 
     The processing system  1  includes the optical observation device OC. The wafer W may be shifted between the optical observation device OC and the plasma processing apparatus  10  by the transport robot Rb 1  and the transport robot Rb 2 . The wafer W is accommodated in the optical observation device OC by the transport robot Rb 1 , and after the wafer W is aligned in the optical observation device OC, the optical observation device OC measures a groove width of a pattern of the mask (for example, the mask MK) of the wafer W and transmits a measurement result to the control unit Cnt. In the optical observation device OC, the groove width of the pattern of the mask may be measured for each of the plurality of areas ER (to be described below) of the main surface FW. 
       FIG. 4  is a diagram illustrating an example of the plasma processing device, which may include the processing system illustrated in  FIG. 3 .  FIG. 4  schematically illustrates a cross-section structure of the plasma processing apparatus  10  usable in various embodiments of method MT for processing the target object. 
     As illustrated in  FIG. 4 , the plasma processing apparatus  10  is a plasma etching device including a parallel flat electrode, and includes the processing container  12 . The processing container  12  approximately has a cylindrical shape and defines a processing space Sp. The processing container  12  is formed of, for example, aluminum, and an inner wall surface thereof is subjected to an anodizing treatment. The processing container  12  is protected and grounded. 
     A support part  14  approximately having a cylindrical shape is provided on a bottom of the processing container  12 . The support part  14  is formed of, for example, an insulating material. The insulating material forming the support part  14  may include oxygen, like quartz. The support part  14  is extended from the bottom of the processing container  12  in a vertical direction within the processing container  12 . A mounting table PD is provided within the processing container  12 . The mounting table PD is supported by the support part  14 . 
     The mounting table PD holds the wafer W on an upper surface of the mounting table PD. The main surface FW of the wafer W is on the opposite side of a back surface of the wafer W, which is in contact with the upper surface of the mounting table PD, and faces an upper electrode  30 . The mounting table PD includes a lower electrode LE and an electrostatic chuck ESC. The lower electrode LE includes a first plate  18   a  and a second plate  18   b.  The first plate  18   a  and the second plate  18   b  are formed of, for example, metal, such as aluminum, and approximately have a disk shape. The second plate  18   b  is provided on the first plate  18   a,  and is electrically connected with the first plate  18   a.    
     The electrostatic chuck ESC is provided on the second plate  18   b.  The electrostatic chuck ESC has a structure, in which an electrode that is a conductive film is disposed between a pair of insulating layers or a pair of insulating sheets. A DC power supply  22  is electrically connected to an electrode of the electrostatic chuck ESC through a switch  23 . When the wafer W is disposed on the mounting table PD, the wafer W is in contact with the electrostatic chuck ESC. The back surface (the surface opposite to the main surface FW) of the wafer W is in contact with the electrostatic chuck ESC. The electrostatic chuck ESC adsorbs the wafer W by an electrostatic force such as a Coulomb force generated by a DC voltage from the DC power supply  22 . Accordingly, the electrostatic chuck ESC may hold the wafer W. 
     A focus ring FR is provided on a peripheral portion of the second plate  18   b  so as to surround the edge of the wafer W and the electrostatic chuck ESC. The focus ring FR is provided for improving uniformity of etching. The focus ring FR is formed of a material appropriately selected by a material of a film to be etched, and may be formed of, for example, quartz. 
     A coolant flow path  24  is provided inside the second plate  18   b.  The coolant flow path  24  constitutes a temperature control mechanism. Coolant is supplied to the coolant flow path  24  through a pipe  26   a  from a chiller unit (not illustrated) provided outside the processing container  12 . The coolant supplied to the coolant flow path  24  returns to the chiller unit through a pipe  26   b.  As described above, the coolant is supplied so as to circulate the coolant flow path  24 . By controlling a temperature of the coolant, a temperature of the wafer W supported by the electrostatic chuck ESC may be controlled. 
     A gas supply line  28  is provided to the plasma processing apparatus  10 . The gas supply line  28  supplies a heat transfer gas, for example, He gas from a heat transfer gas supply mechanism to a section between an upper surface of the electrostatic chuck ESC and the back surface of the wafer W. 
     A temperature adjusting unit HT for controlling a temperature of the wafer W is provided in the plasma processing apparatus  10 . The temperature adjusting unit HT is embedded in the electrostatic chuck ESC. The heater power supply HP is connected to the temperature adjusting unit HT. Power is supplied to the temperature adjusting unit HT from the heater power supply HP, so that a temperature of the electrostatic chuck ESC is adjusted and a temperature of the wafer W arranged on the electrostatic chuck ESC is adjusted. Further, the temperature adjusting unit HT may also be embedded in the second plate  18   b.    
     The temperature adjusting unit HT includes a plurality of heating elements emitting heat, and a plurality of temperature sensors each configured to detect a temperature in the vicinity of the plurality of heating elements. When the wafer W is aligned on the electrostatic chuck ESC, each of the plurality of heating elements is arranged in each of the plurality of areas ER (to be described below) of the main surface FW of the wafer W. When the wafer W is aligned and arranged on the electrostatic chuck ESC, the control unit Cnt recognizes the heating element and the temperature sensor corresponding to each of the plurality of areas ER of the main surface FW of the wafer W in association with the area ER. The control unit Cnt may distinguish the area ER, and the heating element and the temperature sensor corresponding to the area ER by, a number, such as a figure or a character, for each of the plurality of areas (for each of the plurality of areas ER). The control unit Cnt detects a temperature of one area ER by the temperature sensor provided at a position corresponding to the one area ER, and controls a temperature of the one area ER by the heating element provided at the position corresponding to the one area ER. Further, the temperature detected by one temperature sensor when the wafer W is arranged on the electrostatic chuck ESC is the same as a temperature of the area ER on the temperature sensor in the wafer W (more particularly, a temperature of the area ER in a target layer J 1  which is to be described below). 
     The plasma processing apparatus  10  includes the upper electrode  30 . The upper electrode  30  is arranged to face the mounting table PD above the mounting table PD. The lower electrode LE and the upper electrode  30  are provided substantially parallel to each other, and constitute a parallel flat electrode. The processing space Sp for performing the plasma processing on the wafer W is provided between the upper electrode  30  and the lower electrode LE. 
     The upper electrode  30  is supported on an upper part of the processing container  12  through an insulating shielding member  32 . The insulating shielding member  32  is formed of an insulating material, and may include, for example, oxygen, like quartz. The upper electrode  30  may include an electrode plate  34  and an electrode support body  36 . The electrode plate  34  faces the processing space Sp, and a plurality of gas discharge holes  34   a  is provided to the electrode plate  34 . In an embodiment, the electrode plate  34  contains silicon. In a separate embodiment, the electrode plate  34  may contain a silicon oxide. 
     The electrode support body  36  supports the electrode plate  34  to be detachable, and may be formed of a conductive material, for example, aluminum. The electrode support body  36  may have a water cooling structure. A gas diffusion chamber  36   a  is provided inside the electrode support body  36 . A plurality of gas flow holes  36   b  communicating with the gas discharge holes  34   a  is extended downward from the gas diffusion chamber  36   a.  A gas inlet  36   c  guiding a processing gas to the gas diffusion chamber  36   a  is formed in the electrode support body  36 , and a gas supply pipe  38  is connected to the gas inlet  36   c.    
     A gas source group  40  is connected to the gas supply pipe  38  through a valve group  42  and a flow rate controller group  44 . The gas source group  40  includes a plurality of gas sources. The plurality of gas sources may include a source of organic group-containing aminosilane-based gas, a source of fluorocarbon-based gas (C x F y  gas (x and y are integers of 1 to 10) a source of gas having oxygen atoms and carbon atoms (for example, carbon dioxide gas), a source of nitrogen gas, a source of hydrogen gas, and a source of noble gas. As the aminosilane-based gas, gas having a molecular structure with a relatively small number of amino groups may be used, and for example, monoaminosilane (H 3 —Si—R (R is an amino group, which may include an organic group and may be substituted) may be used. The aminosilane-based gas (gas included in first gas G 1  which is to be described below) may include aminosilane, which may have one to three silicon atoms, or may include aminosilane having one to three amino groups. The aminosilane having one to three silicon atoms may be monosilane (monoaminosilane) having one to three amino groups, disilane having one to three amino groups, or trisilane having one to three amino groups. Further, the aminosilane may have an amino group which may be substituted. Further, the amino group may be substituted by any one of a methyl group, an ethyl group, a propyl group, and a butyl group. Further, the methyl group, the ethyl group, the propyl group, or the butyl group may be substituted by halogen. As the fluorocarbon-based gas, predetermined fluorocarbon-based gas, such as CF 4  gas, C 4 F 6  gas, and C 4 F 8  gas, may be used. As the noble gas, predetermined noble gas, such as Ar gas and He gas, may be used. 
     The valve group  42  includes a plurality of valves, and the flow rate controller group  44  includes a plurality of flow rate controllers, such as a mass flow controller. Each of the plurality of gas sources of the gas source group  40  is connected to the gas supply pipe  38  through a corresponding valve of the valve group  42  and a corresponding flow rate controller of the flow rate controller group  44 . Accordingly, the plasma processing apparatus  10  may supply the gas from the one or more gas sources selected from the plurality of gas sources of the gas source group  40  into the processing container  12  with a separately controlled flow rate. 
     In the plasma processing apparatus  10 , a deposit shield  46  is detachably provided along an inner wall of the processing container  12 . The deposit shield  46  is also provided on an outer periphery of the support part  14 . The deposit shield  46  prevents etching by-products (deposits) from being deposited in the processing container  12 , and may be formed by coating an aluminum material with ceramics, such as Y 2 O 3 . The deposit shield may be formed of a material, for example, quartz, including oxygen, in addition to Y 2 O 3 . 
     An exhaust plate  48  is provided at the bottom side of the processing container  12 , that is, a space between the support part  14  and the lateral wall of the processing container  12 . The exhaust plate  48  may be formed by coating an aluminum material with ceramics, such as Y 2 O 3 . An exhaust port  12   e  is provided in the processing container  12  which is a lower side of the exhaust plate  48 . The exhaust device  50  is connected to the exhaust port  12   e  through an exhaust pipe  52 . The exhaust device  50  includes a vacuum pump, such as a turbo molecular pump, and may decompress a space within the processing container  12  to a desired vacuum level. A loading and unloading port  12   g  of the wafer W is provided on the lateral wall of the processing container  12 , and the loading and unloading port  12   g  may be opened and closed by a gate valve  54 . 
     The plasma processing apparatus  10  further includes the first high frequency power supply  62  and the second high frequency power supply  64 . The first high frequency power supply  62  is a power supply generating first high frequency power for generating plasma, and generates high frequency power at a frequency of 27 to 100 MHz, for example, 60 MHz. Further, the first high frequency power supply  62  has a pulse specification, and may be controlled at a frequency of 5 to 10 kHz and a duty of 50 to 100%. The first high frequency power supply  62  is connected to the upper electrode  30  through the matcher  66 . The matcher  66  is a circuit for matching output impedance of the first high frequency power supply  62  and input impedance at a load side (the lower electrode (LE) side). Further, the high frequency power supply  62  may be connected to the lower electrode LE through the matcher  66 . 
     The second high frequency power supply  64  is a power supply for generating second high frequency power for drawing ions to the wafer W, that is, high frequency bias power, and generates high frequency bias power at a frequency within a range of 400 kHz to 40.68 MHz, for example, a frequency of 13.56 MHz. Further, the second high frequency power supply  64  has a pulse specification and may be controlled at a frequency of 5 to 40 kHz and a duty of 20 to 100%. The second high frequency power supply  64  is connected to the lower electrode LE through the matcher  68 . The matcher  68  is a circuit for matching output impedance of the second high frequency power supply  64  and input impedance at the load side (the lower electrode (LE) side). 
     The plasma processing apparatus  10  further includes the power supply  70 . The power supply  70  is connected to the upper electrode  30 . The power supply  70  applies a voltage for drawing positive ions present within the processing space Sp into the electrode plate  34  to the upper electrode  30 . In the example, the power supply  70  is a DC power supply generating a negative DC voltage. When the voltage is applied to the upper electrode  30  from the power supply  70 , the positive ions present in the processing space Sp collide with the electrode plate  34 . Accordingly, secondary electrons and/or silicon are discharged from the electrode plate  34 . 
     Method MT will be described hereinafter in detail based on an embodiment carried out in the processing system  1  including the plasma processing apparatus  10  as an example with reference to  FIGS. 1, 5, 8, and 9 . Further, method MT may be carried out in a processing system different from the processing system  1 , and the processing system may include a plasma processing device, other than the plasma processing apparatus  10 . 
     First, method MT illustrated in  FIG. 1  includes steps SA 1  to SA 4 . Step SA 1  includes step SA 11  (the second step) of etching the antireflection film AL by using the mask MK illustrated in  FIG. 2 . Step SA 2  subsequent to step SA 1  includes step SA 21  (the second step) of etching the organic film OL by using the mask formed of the antireflection film AL by the etching performed in step SA 11 . Step SA 3  subsequent to step SA 2  includes step SA 31  of etching the layer to be etched EL 1  by using the mask formed of the organic film OL by the etching performed in step SA 21 , and step SA 32  of removing the mask by ashing the mask formed of the organic film OL after step SA 31 . Step SA 4  subsequent to step SA 3  includes step SA 41  of etching the layer to be etched EL 2  by using the mask formed of the layer to be etched EL 1  by the etching performed in step SA 31 . 
     In step SA 11 , the antireflection film AL is etched. Particularly, a processing gas containing fluorocarbon gas is supplied into the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . Further, high-frequency power is supplied from the first high frequency power supply  62 . High-frequency bias power is supplied from the second high frequency power supply  64 . A pressure inside the processing container  12  is set to a predetermined pressure by operating the exhaust device  50 . Through the foregoing steps, plasma of the fluorocarbon gas is generated within the processing space Sp of the processing container  12 . An active species including fluorine in the generated plasma etches a region exposed from the mask MK out of the entire region of the antireflection film A. By the etching of the antireflection film AL, the mask used for etching the organic film OL is formed from the antireflection film AL. 
     In step SA 21 , the organic film OL is etched. Particularly, a processing gas containing nitrogen gas and hydrogen gas is supplied to the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . Further, high-frequency power is supplied from the first high frequency power supply  62 . High frequency bias power is supplied from the second high frequency power supply  64 . The pressure inside the processing container  12  is set to a predetermined pressure by operating the exhaust device  50 . Through the foregoing steps, plasma of the processing gas containing nitrogen gas and hydrogen gas is generated in the processing space Sp of the processing container  12 . Hydrogen radical, which is an active species of hydrogen in the generated plasma etches the region exposed from the mask formed of the antireflection film AL in step SA 11  out of the entire region of the organic film OL. By the etching of the organic film OL, a mask used for etching the layer to be etched EL 1  is formed of the organic film OL. Further, as gas for etching the organic film OL, a processing gas containing oxygen may be used. 
     Step SA 31  of step SA 3  subsequent to step SA 2 , the layer to be etched EL 1  is etched. Particularly, a processing gas is supplied to the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . The processing gas may be appropriately selected depending on a material forming the layer to be etched EL 1 . For example, the layer to be etched EL 1  is formed of a silicon oxide, the processing gas may include fluorocarbon gas. Further, high-frequency power is supplied from the first high frequency power supply  62 . High frequency bias power is supplied from the second high frequency power supply  64 . The pressure inside the processing container  12  is set to a predetermined pressure by operating the exhaust device  50 . Through the steps, plasma is generated. The active species in the generated plasma etches the region exposed from the mask formed of the organic film OL by the etching performed in step SA 21  out of the entire region of the layer to be etched EL 1 . After step SA 31 , in step SA 32 , the mask formed of the organic film OL in step SA 21  is ashed. Particularly, a processing gas is supplied to the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group. The processing gas may include oxygen gas and oxygen atoms. Further, high frequency power is supplied from the first high frequency power supply  62 . High frequency bias power is supplied from the second high frequency power supply  64 . The pressure inside the processing container  12  is set to a predetermined pressure by operating the exhaust device  50 . Through the steps, plasma is generated. The active species in the generated plasma ashes the mask formed of the organic film OL in step SA 21 . Further, as gas for ashing the mask formed of the organic film OL in step SA 21 , a processing gas containing nitrogen gas and hydrogen gas may be used. 
     In step SA 41  of step SA 4  subsequent to step SA 3 , the layer to be etched EL 2  is etched. Particularly, a processing gas is supplied to the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . The processing gas may be appropriately selected depending on a material forming the layer to be etched EL 2 . For example, when the layer to be etched EL 2  is formed of amorphous silicon, the processing gas may include halogen-based gas. Further, high frequency power is supplied from the first high frequency power supply  62 . High frequency bias power is supplied from the second high frequency power supply  64 . The pressure inside the processing container  12  is set to a predetermined pressure by operating the exhaust device  50 . Through the steps, plasma is generated. The active species in the generated plasma etches the region exposed from the mask formed of the layer to be etched EL 1  by the etching and ashing performed in steps SA 31  and SA 32  out of the entire region of the layer to be etched EL 2 . 
     Steps SA 1 , SA 2 , SA 3 , and SA 4  may include step SAA (the first step) of adjusting a groove width of the pattern before the etching. In step SAA, before the etching, a groove width of the pattern of the mask used in the etching is adjusted. When step SAA is performed in step SA 1 , step SAA is performed before step SA 11 . When step SAA is performed in step SA 2 , step SAA is performed before step SA 21 . When step SAA is performed in step SA 3 , step SAA is performed before step SA 31 . When step SAA is performed in step SA 4 , step SAA is performed before step SA 41 . 
     A state of a wafer W, which is a processing target of step SAA (that is, a processing target of the step illustrated in  FIG. 5  to be described below) is illustrated in  FIG. 6A .  FIG. 6B  is a cross-sectional view illustrating a state of the wafer W before the step illustrated in  FIG. 5  (step SAA) is performed. The wafer W illustrated in  FIG. 6A  includes a target layer J 1  and a mask J 2 . The mask J 2  is provided on a main surface J 11  of the target layer J 1  (when the mask J 2  corresponds to a mask MK, the main surface J 11  corresponds to a main surface FW of the wafer W). 
     When step SAA illustrated in  FIG. 1  is executed in step SA 1  of etching the antireflection film AL, the target layer J 1  is the antireflection film AL and the mask J 2  is the mask MK. In step SA 11 , after step SAA is executed, the target layer J 1  is etched by using the mask, on which the processing of adjusting the groove width is performed. 
     When step SAA illustrated in  FIG. 1  is executed in step SA 2  of etching the organic film OL, the target layer J 1  is the organic film OL, and the mask J 2  is the mask formed of the antireflection film AL by the etching performed in step SA 11 . In step SA 21 , after step SAA is executed, the target layer J 1  is etched by using the mask, on which the processing of adjusting the groove width is performed. 
     When step SAA illustrated in  FIG. 1  is executed in step SA 3  of etching the layer to be etched EL 1 , the target layer J 1  is the layer to be etched EL 1 , and the mask J 2  is the mask formed of the organic film OL by the etching performed in step SA 21 . In step SA 31 , after step SAA is executed, the target layer J 1  is etched by using the mask, on which the processing of adjusting the groove width is performed. 
     When step SAA illustrated in  FIG. 1  is executed in step SA 4  of etching the layer to be etched EL 2 , the target layer J 1  is the layer to be etched EL 2 , and the mask J 2  is the mask formed of the layer to be etched EL 1  by the etching and the ashing performed in steps SA 31  and SA 32 . In step SA 41 , after step SAA is executed, the target layer J 1  is etched by using the mask, on which the processing of adjusting the groove width is performed. 
     Next, step SAA illustrated in  FIG. 1  will be described in detail with reference to  FIG. 5 .  FIG. 5  is a flowchart illustrating an example of the step of adjusting a groove width of a pattern before etching, which is a step (step SAA) may be included in the method illustrated in  FIG. 1 . 
     In step SAA (in the processing performed by the control unit Cnt), the main surface J 11  of the target layer J 1  of the wafer W is divided into the plurality of areas ER.  FIG. 7  is a diagram schematically illustrating some of a plurality of divided areas ER of the main surface of the target layer J 1  of the wafer W in method MT according to an embodiment as an example. The plurality of areas ER does not overlap. The main surface J 11  of the target layer J 1  (the main surface FW of the wafer W) is coated with the plurality of areas ER. A shape of the area ER is, for example, a shape of an area concentrically extended based on a center point of the main surface J 11  (a center point of the main surface FW) of the target layer J 1 , or an area in a lattice shape, but is not limited thereto. 
     As illustrated in  FIG. 5 , step SAA includes steps SB 1  to SB 7 , and steps SB 5  to SB 7  may be executed a plurality of times (repeatedly) according to determination results of steps SB 3  and SB 4 . First, in step SB 1  (the third step), a value of a groove width of the pattern of the mask J 2  is measured for each of the plurality of areas ER of the main surface J 11  of the target layer J 1  by the optical observation device OC of the processing system  1 . 
     In step SB 2  (the fourth step) subsequent to step SB 1 , a positive difference value obtained by subtracting a reference value of the groove width from the value of the groove width of the pattern of the mask J 2  measured in step SB 1  is calculated for each of the plurality of areas ER of the main surface J 11  of the target layer J 1 . 
     In step SB 3  subsequent to step SB 2 , it is determined whether the adjustment of the groove width of the pattern has been already once performed (the case where the adjustment of the groove width of the pattern has been already once performed is the case where the adjustment of the groove width of the pattern has been already once performed in steps SB 5  to SB 7 , which will be described below), and when the adjustment of the groove width of the pattern has not been performed yet (when the adjustment of the groove width of the pattern is initially performed) (step SB 3 : No), the process proceeds to step SB 5 . In step SB 3 , when the adjustment of the groove width of the pattern has been already once performed (step SB 3 : Yes), the process proceeds to step SB 4 . 
     In step SB 4 , it is determined whether it is necessary to re-adjust the groove width of the pattern based on the difference value of the groove width of the pattern calculated in step SB 2 . In step SB 4 , when it is necessary to re-adjust the groove width of the pattern (step SB 4 : Yes), steps SB 5  to SB 7  are re-executed. That is, steps SB 1  and SB 2  are re-executed after steps SB 5  to SB 7  are executed, and when the difference value calculated in step SB 2  does not satisfy a predetermined reference range due to the re-execution (step SB 4 : Yes), steps SB 5  to SB 7  are re-executed. The reference range is a range including the reference value of the groove width used in step SB 2 . In step SB 4 , when it is not necessary to re-adjust the groove width of the pattern (step SB 4 : No), that is, when the difference value calculated in step SB 2  satisfies the predetermined reference range, the processing of step SAA is terminated. 
     In step SB 5  subsequent to step SB 3  (Yes) and step SB 4  (Yes), the wafer W is shifted to the plasma processing apparatus  10  from the optical observation device OC by the transport robot Rb 1  and the transport robot Rb 2  and the wafer W is loaded into the processing container  12  of the plasma processing apparatus  10 . 
     In step SB 6  (the fifth step) subsequent to step SB 5 , a film J 3  having a film thickness of the difference value of each of the plurality of areas ER calculated in step SB 2  (a film in which a film thickness of each of the plurality of areas ER is the difference value calculated in step SB 2  for each of the plurality of areas ER) is formed on a surface J 21  of the mask J 2  of the wafer W loaded into the processing container  12 . The film J 3  is a silicon oxide film.  FIG. 6B  is a cross-sectional view illustrating a state of the wafer W before the step illustrated in  FIG. 5  (step SB 6 ) is performed. In the wafer W illustrated in  FIG. 6B , the film J 3  is formed on the surface J 21  of the mask J 2 . Further, the contents of the processing performed in step SB 6  will be described in detail below. 
     In step SB 7  subsequent to step SB 6 , the wafer W is shifted to the optical observation device OC from the plasma processing apparatus  10  by the transport robot Rb 1  and the transport robot Rb 2  and the wafer W is loaded into the optical observation device OC. After step SB 7 , steps SB 1 , SB 2 , and SB 3  are re-executed. 
     Step SB 6  will be described in detail with reference to  FIGS. 8 and 9 .  FIG. 8  is a flowchart illustrating an example of the step of adjusting the groove width of the pattern, which is a part of the steps illustrated in  FIG. 5  (step SB 6 ).  FIG. 9  is a flowchart illustrating an example of a step of forming a uniform film on the main surface J 11  of the target layer J 1 , which is a step (step SCC) that may be included in the steps illustrated in  FIG. 8 . 
     As illustrated in  FIG. 8 , step SB 6  includes steps SC 1  to SC 9 . Steps SC 5  to SC 8  form sequence SQ 1 . Sequence SQ 1  and step SC 9  are film forming processing for forming the film J 3  on the surface J 21  of the mask J 2  of the wafer W. Steps SC 1  to SC 4  are preparation processing required for executing the film forming processing constituted by sequence SQ 1  and step SC 9 . 
     In step SC 1 , the wafer W loaded into the processing container  12  of the plasma processing apparatus  10  is aligned and provided on the electrostatic chuck ESC. In step SC 2  subsequent to step SC 1 , similar to step SB 3 , it is determined whether the adjustment of the groove width of the pattern has been already once performed (the case where the adjustment of the groove width of the pattern has been already once performed is the case where the adjustment of the groove width of the pattern has been already once performed in steps SB 5  to SB 7 , which is to be described below), and when the adjustment of the groove width of the pattern has not been performed yet (when the adjustment of the groove width of the pattern is initially performed) (step SC 2 : No), the process proceeds to step SC 3 . Further, the determination result of step SC 2  corresponds to the determination result of step SB 3  illustrated in  FIG. 5 . Further, there is a case where step SC 3  is not executed when step SAA including step SC 3  is performed in step SA 2  of etching the organic film (step SAA is performed after step SA 1  and before step SA 21 ). 
     In step SC 2 , when the adjustment of the groove width of the pattern has been already once performed (step SC 2 : Yes), the process proceeds to step SC 4  or step SCC (the twelfth step). Further, since the determination result of step SC 2  is the same as the determination result of step SB 3 , the determination processing of step SC 2  may be performed by referring to the determination result of step SB 3 . 
     In step SCC, the film is conformally formed on the surface J 21  of the mask J 2  regardless of the plurality of areas ER. Step SCC will be described in detail with reference to  FIG. 9  below. Further, as illustrated in  FIG. 8 , step SB 6  may be the configuration, which does not include step SCC, but when step SB 6  includes step SCC, step SCC may be executed between step SC 3  or step SC 2  (No) and step SC 4  (that is, before step SC 4 ) or after step SC 9  (Yes) (that is, after the film forming processing), which is to be described below. 
     Step SC 3  subsequent to step SC 2  (Yes), secondary electrons are emitted to the wafer W. Step SC 3  is an step of emitting the secondary electrons to the mask J 2  by generating plasma within the processing space Sp of the processing container  12  and applying a negative DC voltage to the upper electrode  30  before sequence SQ 1  and step SC 9  of forming the film J 3  on the surface J 21  of the mask J 2  are executed. 
     As described above, before the series of processes of sequence SQ 1  to step SC 9  of forming the film J 3  on the surface J 21  of the mask J 2  are executed, the secondary electrons are emitted to the mask J 2 , so that it is possible to reform the mask J 2  before the film J 3  is formed, thereby suppressing damage to the mask J 2  due to the subsequent steps. 
     The contents of the processing of step SC 3  will be described in detail. First, hydrogen gas and noble gas are supplied into the processing container  12 , and high-frequency power is supplied from the first high frequency power supply  62 , so that plasma is generated within the processing space Sp. Hydrogen gas and noble gas are supplied into the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . Accordingly, positive ions in the processing space Sp are drawn into the upper electrode  30 , so that the positive ions collide with the upper electrode  30 . The positive ions collide with the upper electrode  30 , so that the secondary electrons are discharged from the upper electrode  30 . The discharged secondary electrons are emitted to the wafer W, so that the mask J 2  is reformed. Further, the positive ions collide with the electrode plate  34 , so that silicon, which is the material forming the electrode plate  34 , is discharged together with the secondary electrons. The discharged silicon is combined with oxygen discharged from the configuration component of the plasma processing apparatus  10  exposed to plasma. The oxygen is discharged from the member, for example, the support part  14 , the insulating shielding member  32 , and the deposit shield  46 . A silicon oxide compound is generated by a combination of silicon and oxygen, and the silicon oxide compound is deposited on the wafer W and covers and protects the mask J 2 . As described above, in step SC 3  of emitting the secondary electrons to the mask J 2 , the negative DC voltage is applied to the upper electrode  30  by generating plasma within the processing space Sp, so that the secondary electrons are emitted to the mask J 2  and simultaneously silicon is discharged from the electrode plate  34  to cover the mask J 2  with the silicon oxide compound including the silicon. Further, the secondary electrons are emitted to the mask J 2 , the mask J 2  is covered with the silicon oxide compound, and then the inside of the processing container  12  is purged, and the process proceeds to step SC 4  or step SCC. As described above, when the silicon oxide compound covers the mask J 2  in step SC 3 , it is possible to further suppress damage to the mask J 2  due to the subsequent steps. 
     Further, in step SC 3 , in order to reform the mask or form the protection film by the emission of the secondary electrons in step SC 3 , the discharge of silicon may be suppressed by minimizing the bias power of the second high frequency power supply  64 . Further, in method MT, step SC 3  may be excluded. 
     After step SC 3  or step SC 2  (No), the process proceeds to step SC 4  (the tenth step) by going through step SCC or without going through step SCC. In step SC 4 , for each of the plurality of areas ER of the main surface J 11  of the target layer J 1  of the wafer W, a temperature of the target layer J 1  of the wafer W is adjusted by using a temperature adjusting unit HT. In step SC 4 , the temperature of the target layer J 1  is adjusted for each of the plurality of areas ER by using pre-acquired correspondence data DT indicating correspondence between the temperature of the target layer J 1  and a film thickness of a film deposited on the surface J 21  of the mask J 2  on the target layer J 1  (a film formed by the film forming processing (sequence SQ 1  and step SC 9 ), which will be described below), and the film thickness corresponding to the difference value calculated for each of the plurality of areas ER in step SB 2 . The correspondence data DT is pre-acquired data by depositing the film J 3  on the surface J 21  of the mask J 2  based on the same condition as that of the film forming processing constituted by sequence SQ 1  and step SC 9  (the condition in which the temperature of the target layer J 1  is excluded) for each temperature of the target layer J 1 , and is stored to be readable in the storage unit of the control unit Cnt. 
     In step SC 4 , when step SB 6  does not include step SCC, the temperature of the target layer J 1  is adjusted based on the correspondence data DT for each of the plurality of areas ER so that the temperature of each of the plurality of areas ER in the target layer J 1  of the wafer W loaded into the processing container  12  becomes the temperature corresponding to the film thickness of the difference value calculated for each of the plurality of areas ER in step SB 2 . 
     In step SC 4 , when step SB 6  includes step SCC, that is, step SCC is performed before step SC 4 , after step SC 3 , or after step SC 2  (No), or step SCC is performed after the film forming processing constituted by step SQ 1  and step SC 9 , the temperature of the target layer J 1  is adjusted based on the correspondence data DT for each of the plurality of areas ER so that the temperature of each of the plurality of areas ER in the target layer J 1  of the wafer W loaded into the processing container  12  becomes the temperature corresponding to the value obtained by subtracting a film thickness of the conformally formed film in step SCC from the film thickness of the difference value calculated for each of the plurality of areas ER in step SB 2 . 
     In the film forming processing (the eleventh step) constituted by step SQ 1  and step SC 9  subsequent to step SC 4 , the film (the film J 3  or a part of the film J 3  when step SCC is executed in step SB 6 ) is formed on the surface J 21  of the mask J 2  on the target layer J 1  of the wafer W loaded into the processing container  12 . The film forming processing constituted by step SQ 1  and step SC 9  is the step of conformally forming the silicon oxide film on the surface J 21  of the mask J 2  of the wafer W with a uniform thickness for each of the plurality of areas ER by the same method as the atomic layer deposition (ALD) method. During the execution of step SC 5  of sequence SQ 1 , the temperature of the target layer J 1  of the wafer W adjusted for each of the plurality of areas ER in step SC 4  is maintained. Because of this, the film formed by the film forming processing may have a different film thickness for each of the plurality of areas ER, but after the film J 3  including the film formed by the film forming processing is formed on the surface J 21  of the mask J 2  (step SB 4 : No) and after step SAA, the groove width of the mask J 2  has a desired value (the reference value of the groove width for each of the plurality of areas ER used for calculating the difference value in step SB 2 ). 
     The film forming processing (sequence SQ 1  and step SC 9 ) will be described in detail. Sequence SQ 1  includes steps SC 5  to SC 8 . In step SC 5  (the sixth step), first gas G 1  is supplied into the processing container  12 . Particularly, in step SC 5 , as illustrated in  FIG. 10A , the first gas G 1  containing silicon is introduced into the processing container  12 . The first gas G 1  includes organic contained aminosilane-based gas. The first gas G 1  is aminosilane-based gas, and gas having a molecular structure with a relatively small number of amino groups may be used as the first gas G 1 , and for example, monoaminosilane (H 3 —Si—R (R is an amino group, which may include an organic group and may be substituted) may be used. Further, the aminosilane-based gas used as the first gas G 1  may include aminosilane, which may have one to three silicon atoms, or may include aminosilane having one to three amino groups. The aminosilane having one to three silicon atoms may be monosilane (monoaminosilane) having one to three amino groups, disilane having one to three amino groups, or trisilane having one to three amino groups. Further, the aminosilane may have an amino group which may be substituted. Further, the amino group may be substituted by any one of a methyl group, an ethyl group, a propyl group, and a butyl group. Further, the methyl group, the ethyl group, the propyl group, or the butyl group may be substituted by halogen. The first gas G 1  of the organic group-containing aminosilane-based gas is supplied into the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . In step SC 5 , plasma of the first gas G 1  is not generated. 
     A processing time required in step SC 5  is within a time, in which the film thickness of the film deposited on the surface J 21  of the mask J 2  on the target layer J 1  is in an increasing/decreasing state according to a high/low temperature of the target layer J 1  in step SC 5 . The processing time may be a time shorter than a processing time (a processing time during which the film having the film thickness may be formed on the surface J 21  of the mask J 2  on the target layer J 1  regardless of the temperature of the target layer J 1 ), corresponding to a self-limited region in the ALD method. 
     Molecules of the first gas G 1  are attached to the main surface J 11  of the target layer J 1  (particularly, the surface J 21  of the mask J 2  on the main surface J 11 ) as a reaction precursor (a layer Ly 1 ) as illustrated in  FIG. 10B . The molecules of the first gas G 1  are attached to the surface J 21  of the mask J 2  by chemical adsorption based on a chemical combination, and plasma is not used. Further, as the first gas, gas G 1 , which is attachable to the surface J 21  of the mask J 2  by a chemical combination based on the temperature of the target layer J 1  adjusted for each of the plurality of areas ER in step SC 4  and also contains silicon, may be used. 
     In the meantime, for example, in the case where monoaminosilane is selected as the first gas G 1 , monoaminosilane is selected because monoaminosilane has relatively high electro negativity and chemical adsorption may be relatively easily performed due to a molecular structure having polarity. The layer Ly 1  of the reaction precursor formed by the attachment of the molecules of the first gas G 1  to the surface J 21  of the mask J 2  becomes a state close to a monomolecular layer (single layer) because the attachment is the chemical adsorption. As the amino group R of the monoaminosilane is smaller, the molecular structure of the molecule adsorbed to the surface J 21  of the mask J 2  becomes smaller, so that steric inhibition caused by a size of the molecule is reduced, and thus the molecules of the first gas G 1  may be uniformly adsorbed to the surface J 21  of the mask J 2  for each of the plurality of areas ER and the layer Ly 1  may be formed with the uniform film thickness for each of the plurality of areas ER for the surface J 21  of the mask J 2 . 
     As described above, since the first gas G 1  includes the organic group-containing aminosilane-based gas, the reaction precursor (the layer Ly 1 ) of silicon is formed on the mask J 2  along an atomic layer of the surface J 21  of the mask J 2  by step SC 5 . 
     In step SC 6  (the seventh step) subsequent to step SC 5 , the inside of the processing container  12  is purged. Particularly, the first gas G 1  supplied in step SC 5  is exhausted. In step SC 6 , inert gas, such as nitrogen gas or noble gas (for example, Ar) may be supplied into the processing container  12  as purge gas. That is, the purge of step SC 6  may be any one of gas purge, in which inert gas flows into the processing container  12  or purge by a vacuum state. In step SC 6 , the molecules excessively attached to the surface J 21  of the mask J 2  may be removed. By the steps, the layer Ly 1  of the reaction precursor becomes a very thin monomolecular layer. 
     In step SC 7  (the eighth step) subsequent to step SC 6 , as illustrated in  FIG. 10B , plasma P 1  of second gas is generated in the processing space Sp of the processing container  12 . The second gas includes gas containing oxygen atoms and carbon atoms, and may include, for example, carbon dioxide gas. In step SC 7 , a temperature of the target layer J 1  of the wafer W when the plasma P 1  of the second gas is generated may be, for example, 0° C. or higher and 200° C. or lower. The second gas including a gas containing oxygen atoms and carbon atoms is supplied into the processing container  12  from the gas source selected from the plurality of gas sources of the gas source group  40 . Further, high-frequency power is supplied from the first high frequency power supply  62 . In this case, bias poser of the second high frequency power supply  64  may be applied, and plasma may also be generated only with the second high frequency power supply  64 . A pressure of the space within the processing container  12  is set to a predetermined pressure by supplying high frequency bias power from the second high frequency power supply  64  and operating the exhaust device  50 . As described above, the plasma P 1  of the second gas is generated within the processing space Sp. 
     As illustrated in  FIG. 10B , when the plasma P 1  of the second gas is generated, active species of oxygen and active species of carbon, for example, oxygen radical and carbon radical, are generated, and as illustrated in  FIG. 10C , a layer Ly 2  (layer included in the film J 3 ), which is a silicon oxide layer, is formed as a monomolecular layer. Since the carbon radical may exert a function of suppressing the mask J 2  from being oxygen eroded, the silicon oxide film may be stably formed on the surface J 21  of the mask J 2  as a protection layer. Binding energy of Si—O bond of the silicon oxide layer is about 192 kcal, and is higher than binding energy (about 50 to 110 kcal, about 70 to 110 kcal, and 100 to 120 kcal) of C—C bond, C—H bond, and C—F bond, which are several bond species of the organic film forming the mask, so that the silicon oxide film may exert a function as the protection film. 
     As described above, since the second gas includes oxygen atoms, in step SC 7 , the oxygen atoms are bound to the reaction precursor (the layer Ly 1 ) of silicon arranged on the mask J 2 , so that the layer Ly 2  of the silicon oxide layer may be conformally formed with a different film thickness for each of the plurality of areas ER on the mask J 2 . Further, since the second gas includes carbon atoms, the erosion of the mask J 2  due to the oxygen atoms may be suppressed by the carbon atoms. Accordingly, in sequence SQ 1 , by the same method as the ALD method, the layer Ly 2  of the silicon oxide film may be conformally formed on the surface J 21  of the mask J 2  for each of the plurality of areas ER with the uniform film thickness according to the temperature of each of the plurality of areas ER. 
     In step SC 8  (the ninth step) subsequent to step SC 7 , the inside of the processing container  12  is purged. Particularly, the second gas supplied in step SC 7  is exhausted. In step SC 8 , inert gas, such as nitrogen gas or noble gas (for example, Ar) may be supplied into the processing container  12  as purge gas. That is, the purge of step SC 8  may be any one of gas purge, in which inert gas flows into the processing container  12  or purge by a vacuum state. 
     In step SC 9  subsequent to sequence SQ 1 , it is determined whether the number of times of the repetition of sequence SQ 1  reaches a predetermined number of times (for example, 50 times), and when it is determined that the number of times of the repetition of sequence SQ 1  does not reach the predetermined number of times (step SC 9 : No), sequence SQ 1  is executed again, and when it is determined that the number of times of the repetition of sequence SQ 1  reaches the predetermined number of times (step SC 9 : Yes), step SB 6  is terminated. That is, in step SC 9 , by repeatedly executing sequence SQ 1  until the number of times of the repetition of sequence SQ 1  reaches the predetermined number of times, the film having the film thickness according to a temperature of each of the plurality of areas ER is formed on the surface J 21  of the mask J 2  for each of the plurality of areas. The number of times of the repetition of sequence SQ 1  controlled by step SC 9  is determined according to the processing time of step SC 5  and the film thickness of the film (the film J 3 , or a part of the film J 3  when step SCC is executed in step SB 6 ) formed by the film forming processing constituted by sequence SQ 1  and step SC 9 . 
     Herein, step SCC will be described in detail with reference to  FIG. 9 . Step SCC constituted by sequence SQ 2  and step SD 5 . Sequence SQ 2  constituted by steps SD 1  to SD 4 . Step SD 1  of sequence SQ 2  corresponds to step SC 5  of sequence SQ 1  illustrated in  FIG. 8 , but step SD 1  is different from step SC 5  in that a temperature of the target layer J 1  in step SD 1  is different from the temperature of the target layer J 1  in step SC 5 , and the processing time required in step SD 1  is different from a processing time required in step SC 5 . In steps SD 2  to SD 4  of sequence SQ 2 , the same processing as that of steps SC 6  to SC 8  of sequence SQ 1  illustrated in  FIG. 8  is performed, respectively. 
     The number of times of the repetition of sequence SQ 2  controlled by step SD 5  is determined according to the film thickness of the film (the part of the film J 3 ) formed by step SCC. The film J 3  formed in step SB 6  is formed of the film formed in step SCC and the film formed by the film forming processing (sequence SQ 1  and step SC 9 ). The film thickness of the film J 3  formed in step SB 6  is a sum value of the film thickness of the film formed in step SCC and the film thickness of the film formed by the film forming processing (sequence SQ 1  and step SC 9 ). 
     A processing time in step SD 1  of sequence SQ 2  is a processing time corresponding to a self-limited region (the processing time, in which the film having the film thickness may be formed on the surface J 21  of the mask J 2  on the target layer J 1  regardless of the temperature of the target layer J 1 ) in the ALD method, and is longer than the processing time of step SC 5  of sequence SQ 1 . In step SD 1 , a temperature of the target layer J 1  of the wafer W may be, for example, 0° C. or higher and 200° C. or longer. 
     A particular example of a method of writing the correspondence data DT according to an embodiment will be described. The correspondence data DT indicates correspondence between the temperature of the target layer J 1  and the film thickness of the film (the film formed by the film forming processing (sequence SQ 1  and step SC 9 ) deposited on the surface J 21  of the mask J 2  on the target layer J 1 , and is data pre-acquired before the execution of method MT by depositing the film J 3  on the surface  21  of the mask J 2  based on the same condition (the condition, in which the temperature of the target layer J 1  is executed) as that of the film forming processing constituted by sequence SQ 1  and step SC 9  for each temperature of the target layer J 1 . 
     First, for each of the plurality of temperatures (hereinafter, a value of the temperature is referred to as “KR”) of the target layer J 1 , a relation (hereinafter, the relation is referred to as “F1” with a function of the processing time TM and the temperature KR) between the processing time in step SC 5  (hereinafter, a value of the processing time is referred to as “TM”) and the film thickness (hereinafter, a value of the film thickness is referred to as “VL”) formed by the film forming processing is measured. For each of the temperatures KR, a relation VL (VL=F1(TM; KR)) of the processing time TM and the film thickness VL may be preferably approximated by the logarithm function VL=α1(KR)×1n(TM)+β1(KR) (Equation 1). α1(KR) is a constant determined for each KR, 1n(TM) is a natural logarithm for TM, and β1(KR) is a constant determined for each KR. In Equation 1 (approximate expression), the film thickness VL of the film formed by the film forming processing is larger as when the temperature KR is higher as can be seen from the equation (Arrhenius plot) of Arrhenius for the temperature KR, but in the self-limited region of the ALD method, the film thickness VL of the film formed by the film forming processing converges to a nearly constant value, regardless of KR. 
     α1(KR) and β1(KR) included in Equation 1 may be approximated as described below. A reciprocal (1/α1(KR)) of α1(KR) may be preferably approximated by a first function, 1/α1(KR)=α2×KR+β2 (Equation 2). α2 and β2 are constants determined at the time of the calculation of Equation 2 (approximate expression). β1(KR) may be preferably approximated by a logarithm function, β1(KR)=α3×1n(KR)+β3 (Equation 3) as a function of KR. α3 and β3 are constants determined at the time of the calculation of Equation 3 (approximate expression). 1n(KR) is a natural logarithm for KR. 
     Equations 2 and 3 are applied to α1(KR) and β1(KR) included in Equation 1, respectively, so that Equation 1 is expressed by VL=1n(TM)/(α2×KR+β2)+α3×1n(KR)+β3 (Equation 4). That is, the film thickness VL may be uniquely calculated according to the temperature KR when the processing time TM is fixed with a constant value (the processing time required in step SC, which is shorter than the processing time corresponding to the self-limited region in the ALD method and the processing time, in which the film thickness VL is sufficiently changed by the temperature KR). As described above, the correspondence data DT may be written by Equation 4. Further, the correspondence data DT may also be written by a method, other than the method using Equations 1 to 4. 
     In method MT according to the embodiment, before step SA 11  (or step SA 21 , step SA 31 , and step SA 41 ) of etching the target layer J 1 , step SAA of adjusting the groove width of the pattern of the mask J 2  is performed. In step SAA, the main surface J 11  of the target layer J 1  is divided into the plurality of areas ER, a difference value between the groove width of the mask J 2  and the reference value of the groove width is calculated for each of the plurality of areas ER in steps SB 1  and SB 2 , and the film J 3  having the film thickness corresponding to the difference value is formed on the mask J 2  in step SB 6  to correct the groove width of the mask to the reference value for each of the plurality of areas ER. In step SB 6 , the film is very precisely formed on the mask J 2  for every atom layer by the same method as the ALD method by using the film forming processing, in which steps SC 5  to SC 8  are repeatedly executed. The film thickness of the film formed by the film forming processing is different according to a temperature of the target layer J 1 , so that in step SC 4 , the temperature of the target layer J 1  is adjusted so as to be the temperature required for forming the film having the film thickness corresponding to the difference value calculated in step SB 2  for each of the plurality of areas ER by using the corresponding data DT indicating the correspondence between the temperature of the target layer J 1  and the film thickness of the formed film. As described above, before the etching performed in step SA 11  (or step SA 21 , step SA 31 , and step SA 41 ), a film thickness corresponding to a correction amount of the groove of the mask J 2  is determined for each of the plurality of areas ER of the main surface J 11  of the target layer J 1 , a temperature of the target layer J 1  required for forming the film thickness is determined by using the correspondence data DT, and the same film forming processing as the ALD method is performed in the state where the temperature of the target layer J 1  is adjusted to the temperature determined for each of the plurality of areas ER, so that the variation of the pattern of the mask J 2  may be precisely and sufficiently suppressed for each of the plurality of areas ER of the main surface J 11  of the target layer J 1 . 
     Further, when step SCC of conformally forming the film on the surface J 21  of the mask J 2  regardless of the plurality of areas ER is used in method MT, for the common film thickness among the film thicknesses of the plural areas ER, it is possible to partially form the film by step SCC without adjusting the temperature of the target layer J 1  performed on each of the plurality of areas ER in step SC 4 . 
     Further, after the film J 3  is formed in step SB 6 , a difference value of the groove width of the mask J 2  is calculated again and it is determined whether the difference value is within the reference range (steps SB 1  to SB 4 ), and when the difference value is not within the reference range, it is necessary to form the film J 3  again, so that the variation of the groove width of the mask J 2  may be more sufficiently suppressed. 
     In the foregoing, the embodiment has been described with the principle of the present disclosure, but those skilled in the art recognizes that the present disclosure may be changed in disposition and details without departing from the principle. The present disclosure is not limited to the specific configurations disclosed in the present embodiment. Accordingly, all modifications and changes in the claims and the scope of the spirit of the claims are claimed.