JP2009094345A - Surface planarizing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To planarize a substrate or thin film having an uneven portion of several nm on a surface. <P>SOLUTION: The substrate 12 is disposed in a chamber 11 into which reactive gas is introduced. A projection portion 21 is irradiated with light having a wavelength longer than an absorption end wavelength of a wavelength band wherein gas molecules forming the reactive gas can be directly excited. The projection portion 21 is thus irradiated with the light and then the reactive gas is dissociated through a non-resonance process with near-field light generated in a local region of the projection portion 21 to generate active species. The activated active species and the projection portion 21 are subjected to chemical reaction to generate reaction products, and the projection portion 21 is removed. Nonresonant light for the reactive gas is used as the light, so etching proceeds only with the near-field light generated in the local region of the projection portion 21. Further, the projection portion 21 where the near-field light is generated is removed as the reaction proceeds, and a process for planarization automatically ends. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a surface flattening method for flattening a substrate surface such as a silicon wafer or a thin film surface such as a Cr thin film.

  In recent years, with the miniaturization and high integration of semiconductor devices, there is a demand for a technique for manufacturing a highly miniaturized and multilayered thin film structure. In this way, when manufacturing a thin film structure that is miniaturized and multi-layered, for example, if irregularities occur on the surface of a substrate such as a silicon wafer, the irregularities on the substrate surface are also formed on the thin film that is laminated thereon. A corresponding step is formed. If this level difference is large and steep, the processing accuracy and the like of the thin film stacked on the step further decreases. Further, such irregularities cause disconnection of the substrate wiring or insulation failure between the wiring layers, greatly affecting the reliability and yield of the entire semiconductor device. For this reason, in order to solve the problem based on unevenness on the substrate surface or the like, it is necessary to improve the flatness of the substrate or thin film having a thin film structure.

As a method for flattening the surface of the substrate or the like, chemical mechanical polishing is generally used (see, for example, Patent Documents 1 and 2). In this CMP, a polishing pad is pasted on a circular polishing surface plate, the surface of the substrate mounted on the substrate holder is pressed against the polishing pad, and the substrate surface is pressed so as to press the substrate surface against the polishing pad. Both the polishing platen and the substrate holder are rotated while supplying the slurry containing the abrasive fine particles on the surface, and the surface of the substrate is flattened by the generated mechanical friction and the chemical reaction of the slurry.
Japanese Patent Laid-Open No. 11-138418 JP 2003-257913 A

  However, when CMP as described above is used, coarse particles such as agglomerated slurry and solidified by-products form fine scratches on the substrate surface, resulting in fine recesses. Remained on the substrate surface. Moreover, it was not able to polish even the convex part of the substrate surface smaller than the size of the slurry, and the fine convex part remained on the substrate surface. Furthermore, when using CMP, it is necessary to set the optimum polishing conditions according to the material to be polished and the plate thickness (necessary to determine the conditions), but in reality the unevenness is minimized. It was impossible to find the conditions, and it was very difficult to determine the processing conditions.

  Such fine irregularities have dimensions of a few nanometers. Therefore, these irregularities are not used in currently used semiconductor devices with a degree of integration such as LSI (Large Scale Integration) and VLSI (Very Large Scale Integration). Does not significantly affect the reliability of the semiconductor device. However, in the ultra-thinned thin film structure such as the nano-optical device that is expected to advance in the future, the irregularities of these nano-orders greatly affect the problems such as disconnection between the substrate wirings. It was a big barrier to realization. For this reason, a technique capable of planarizing the substrate surface to the atomic level has been desired.

  Therefore, the present invention has been devised in view of the above-described problems, and the object of the present invention is to flatten a substrate or thin film having a concavo-convex portion of several nm size to the atomic level. The present invention provides a method for flattening the surface.

  In order to solve the above-mentioned problems, the present inventor arranges the substrate in a chamber into which a source gas is introduced, and emits light having a wavelength longer than the absorption edge wavelength of gas molecules of the source gas into the recess. To generate a near-field light in the local region of the recess, and based on the near-field light generated in the recess, dissociate the source gas through a non-resonant process to generate a decomposition product, A surface flattening method has been invented, which comprises flattening the recess by depositing the generated decomposition product in the recess.

  That is, the invention according to claim 1 of the present application is a surface planarization method for planarizing a recess formed on a substrate surface or a thin film surface laminated on the substrate, and the substrate is placed in a chamber into which a source gas is introduced. And irradiating the concave portion with light having a wavelength longer than the absorption edge wavelength of the gas molecules of the source gas, thereby generating near-field light in a local region of the concave portion, and generating a near-field generated in the concave portion. Based on light, the source gas is dissociated through a non-resonant process to generate a decomposition product, and the generated decomposition product is deposited in the recess to flatten the recess. To do.

  The invention according to claim 2 of the present application is characterized in that, in the invention according to claim 1, the source gas is a molecule or a compound composed of a constituent element of the substrate or the thin film.

  According to a third aspect of the present invention, there is provided a surface flattening method for flattening a convex portion formed on a substrate surface or a thin film surface laminated on the substrate, wherein the substrate is placed in a chamber into which a reactive gas is introduced. And irradiating the convex part with light having a wavelength longer than the absorption edge wavelength of the gas molecules of the reactive gas, thereby generating near-field light in a local region of the convex part, Based on the near-field light generated in the local region, the reactive gas is dissociated through a non-resonant process to generate active species, and the generated active species and the convex portion are chemically reacted to generate a reaction product. By generating, the convex portion is removed.

  The invention according to claim 4 of the present application is characterized in that, in the invention according to claim 3, the reactive gas is composed of a fluorine-based gas.

  In the invention according to claim 1 of the present application, since light having a wavelength longer than the absorption edge wavelength of the gas molecules of the source gas, that is, non-resonant light is irradiated, in the local region of the concave portion where the near-field light is generated. Only, a decomposition product is generated from the raw material gas through a non-resonant process. By depositing this decomposition product in the recess, the recess is flattened.

  In the invention according to claim 3 of the present application, since light having a wavelength longer than the absorption edge wavelength of the gas molecule of the reactive gas, that is, non-resonant light is irradiated, the local area of the convex portion where the near-field light is generated. Only in the region, highly reactive active species are generated from the reactive gas through a non-resonant process. By this chemical reaction between the active species and the convex portion, only the convex portion is etched and the convex portion is flattened.

  Further, in the surface flattening method to which the present invention is applied, the unevenness of the substrate surface where near-field light is generated is removed with the progress of the reaction, and the flattening process is automatically ended. For this reason, planarization is performed in a self-organized manner without performing special control from others, and the process in the planarization becomes very simple.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

  First, a substrate that is an object of a surface planarization method to which the present invention is applied will be described.

  The substrate 11 which is the subject of the present invention has a convex portion 21 and a concave portion 22 formed on the surface thereof as schematically shown in FIG. The convex portions 21 and the concave portions 22 are of a size that can be visually recognized with respect to the substrate 11 in FIG. 1, but actually, for example, the size is about several nm, that is, the size of nano-order or the size of several μm. It is configured.

  In the present invention, the substrate 11 to be planarized is embodied by, for example, a silicon wafer (Si) or the like. Further, the object of planarization includes a thin film laminated on the substrate 11, for example, a Cr thin film used as a photomask. In the following description, when only “substrate” is described, a thin film is also included.

  The surface flattening method to which the present invention is applied is realized using a surface flattening apparatus 1 as schematically shown in FIG.

  The surface flattening device 1 includes a chamber 11, a stage 13 in the chamber 11, a gas supply unit 17 for supplying a gas into the chamber 11, and a light source 14 for irradiating the chamber 11 with light. I have. Further, the surface flattening device 1 includes an illumination optical system 16 that can control the shape and polarization direction of light, a reflection mirror 15 that reflects light emitted from the light source 14 to the illumination optical system 16, and a chamber 11. An opening window 18 for introducing light into the chamber 11 and an exhaust port 19 for exhausting gas in the chamber 11 are provided.

In the chamber 11, a mixed gas formed by mixing a raw material gas or a reactive gas and an inert gas is supplied from the gas supply unit 17 at any time so as to have a predetermined pressure. The source gas is introduced into the chamber 11 when the substrate 11 having the recesses 22 is planarized. For example, a silane gas such as SiH ₄ (monosilane) or Si ₂ H ₆ (disilane), Cr ( η ⁵ -C ₅ H ₅ ) ₂ (chromocene), Cr (CO ₆ ) (hexacarbonylchromium) and the like. The reactive gas is introduced into the chamber 11 when the substrate 11 having the convex portions 21 is flattened. For example, SF ₆ (sulfur hexafluoride), CHF ₃ (trifluoromethane), CF ₄ (carbon tetrafluoride). ), And a fluorine gas such as C ₃ F ₈ (octafluoropropane). Further, the inert gas is embodied by a gas formed by mixing any one or two or more of N ₂ , He, Ar, Kr, Xe and the like.

  The stage 13 is provided with a mounting unit (not shown) for mounting the substrate 12 and a heating mechanism (not shown) for heating the substrate 12, thereby depositing a reactive gas on the substrate 12. Can control the film formation of gas molecules. The stage 13 may be provided with a high-precision stage mechanism (not shown) for adjusting the position of the substrate 12 with high precision.

  The light source 14 emits light having a predetermined wavelength based on control by a driving power source (not shown). As will be described in detail below, the light source 14 emits light having a wavelength longer than the absorption edge wavelength of the gas molecule of the reactive gas or source gas. The light source 1 is embodied by, for example, a He—Ne laser oscillator or an Ar laser oscillator.

  The illumination optical system 16 is embodied with a polarization lens, a focusing lens, and the like (not shown). As a result, the beam diameter and beam shape can be controlled in accordance with the position, size, range, and the like of the convex portion 21 and the concave portion 22, and the light irradiation range can be narrowed down.

  Next, the light emitted from the light source 14 of the surface flattening device 1 described above will be described.

  FIG. 3 shows the relationship of the potential energy with respect to the internuclear distance of the gas molecules of the source gas and reactive gas introduced into the chamber 11. Usually, with respect to the gas molecules introduced into the chamber 11, light having a photon energy equal to or greater than the energy difference Ea between the ground level and the excited level, that is, light having a wavelength shorter than the absorption edge wavelength of the gas molecules. When this light is irradiated (hereinafter referred to as resonance light), the gas molecules are directly excited to the excitation level. Since this excited level exceeds the dissociation energy Eb, active species and decomposition products are generated by photodissociating gas molecules in the direction indicated by the arrows.

  In the present invention, it is not a resonance process in which a gas molecule as described above is irradiated with resonance light to directly excite the gas molecule to an excitation level and then dissociate, but from the absorption edge wavelength of the gas molecule. The substrate surface is flattened using a non-resonant process that occurs when light of a long wavelength (hereinafter, this light is referred to as non-resonant light) is applied to the gas molecules as near-field light. Do.

  When irradiated with non-resonant light that is propagating light, gas molecules are not normally excited to the excitation level, but when irradiated with non-resonant light that is near-field light, this gas molecule undergoes a non-resonant process and becomes an active species. Or dissociated into decomposition products. This non-resonant process is classified into process T1, process T2, and process T3 as shown in FIG. Process T1 refers to a process in which gas molecules are excited through a plurality of molecular vibration levels (multistage transition), and as a result, are excited to the excited level and then dissociated into active species. In process T2, when light having a light energy higher than the dissociation energy Eb of gas molecules (hereinafter referred to as S1 mode) is irradiated, the gas molecules are excited to the molecular vibration level of the energy level higher than the dissociation energy. As a result, it refers to the process of being directly dissociated into active species. Further, in the process T3, when light having a light energy less than Eb of gas molecules (hereinafter referred to as S2 mode) is irradiated, the gas molecules are excited through a plurality of molecular orbital levels (multistage transition), This refers to the process of being dissociated into active species after being excited to a molecular vibration level of less than Ea and greater than or equal to Eb.

  In this way, when non-resonant light, which is near-field light, is irradiated, the non-resonant process occurs when the gas molecules are irradiated to the molecular vibration level when the near-field light is irradiated to the gas molecules. This is because it can be directly excited.

  In other words, in normal photodissociation using propagating light, the electric field intensity of propagating light has a uniform distribution in a molecular size space, so that only light electrons among the nuclei and electrons that make up gas molecules Reacts, but cannot change internuclear distance. On the other hand, in the photodissociation using near-field light, the electric field intensity of the near-field light is significantly displaced in a molecular size space, resulting in an uneven distribution. For this reason, when using near-field light, not only the electrons of gas molecules but also the nuclei react, and the internuclear distance can be changed periodically, and the molecules are excited directly into the vibrational level. (Non-adiabatic chemical reaction).

  The near-field light here refers to non-propagating light that clings to the surface of the object when the surface of the object having a size of about 1 μm or less is irradiated with the propagation light. This near-field light has a very strong electric field component, but has a property that the electric field component rapidly decreases as the distance from the surface of the object increases. The thickness from the object surface at which this very strong electric field component is seen depends on the size of the object, and is of the same thickness as the size of the object. The local region in the present invention refers to a local region on the object surface where such a very strong electric field component is seen. This local region means, for example, a region near the outer peripheral surface of the convex portion 21 in FIG. 1A or a region near the inner peripheral surface of the concave portion 22 in FIG.

  Based on the principle description of the present invention, processes including a surface flattening method to which the present invention is applied will be described.

  First, the case where the board | substrate 12 with which the convex part 21 is formed in the surface is planarized is demonstrated. In the case where the object to be flattened is the substrate 12 having the convex portions 21, a reactive gas is introduced into the chamber 11 and flattening is performed using etching.

  First, as shown in FIGS. 2 and 5A, the substrate 12 is placed on the stage 13 in the chamber 11. In this case, a reactive gas may be introduced into the chamber 11 from the gas supply unit 17 in advance, or the reactive gas may be introduced after the substrate 12 is arranged.

  Next, as shown in FIG. 5B, the light source 14 irradiates the substrate 12 with light through the reflecting mirror 15 and the like. As a result, near-field light is generated in the local region of the convex portion 21. In this case, since the irradiated light is non-resonant light, the reactive gas does not react at a flat portion on the surface of the substrate 12 where the near-field light is not generated, and the local area of the convex portion 21 where the near-field light is generated. Reacts only in the area.

  In this case, as shown in FIG. 6, the reactive gas G10 is dissociated through the non-resonant process as described above to generate the active species G11, and the active species G11 and the atoms and molecules 21a of the convex portions 21 Chemically reacts to produce a volatile reaction product G12. This reaction product G12 is discharged out of the chamber 11 by a vacuum pump (not shown) connected to the exhaust port 19.

  Here, as the reaction proceeds, the size of the convex portion 21 is gradually miniaturized, so that the thickness of the near-field light generated around the convex portion 21 is also reduced. Eventually, when the level of the atomic layer constituting the substrate 12 around the convex portion 21 becomes substantially the same level, that is, when the convex portion 21 is almost completely removed, the region where the near-field light is generated disappears. As a result, the etching reaction does not occur. As described above, in the planarization method to which the present invention is applied, the etching reaction of the convex portion proceeds in a self-organizing manner without special control from others, and finally, as shown in FIG. Further, planarization is performed until the surface of the substrate 12 reaches the atomic level, and the planarization process is completed.

  Next, the case where the board | substrate 12 with the recessed part 22 formed in the surface is planarized is demonstrated. In the case where the object to be planarized is the base 12 having the recesses 22, the raw material gas is introduced into the chamber 11 and planarization is performed using the deposition of the raw material gas.

  First, as shown in FIG. 7A, the substrate 12 is placed on the stage 13 in the chamber 11. In this case, the source gas may be introduced in advance or may be introduced after the substrate 12 is arranged.

  Next, as shown in FIG. 7B, the light source 14 irradiates the substrate 12 with light through the reflection mirror 15 and the like. As a result, near-field light is generated in the local region of the recess 22. In this case, since the irradiated light is non-resonant light, the source gas does not react at a flat portion on the surface of the substrate 12 where no near-field light is generated, but in a local region of the recess 22 where the near-field light is generated. Only react.

  In this case, as shown in FIG. 8, the source gas G20 is dissociated through the non-resonant process as described above, and a decomposition product G21 and a byproduct G22 are generated. This decomposition product G21 is deposited in the recess 22. In this case, the degradable organism G21 is preferably composed of atoms of the recesses 22a of the substrate 12 and constituent elements of the molecules 22a.

  Here, since the dimension of the recess 21 is gradually miniaturized as the reaction proceeds, the thickness of the near-field light generated around the recess 21 is also reduced. Eventually, when the level of the atomic layer constituting the substrate 12 around the recess 22 becomes substantially the same level, that is, when the recess 22 is almost completely removed, the region where the near-field light is generated disappears, The deposition reaction is also terminated. As described above, in the planarization method to which the present invention is applied, the deposition reaction proceeds in the recesses in a self-organized manner without special control from others, and finally, as shown in FIG. Then, planarization is performed until the surface of the substrate 12 reaches the atomic level, and the planarization process is completed.

  Thus, when planarizing the board | substrate 12 with which the convex part 21 is formed in the surface in this invention, the board | substrate 12 with which the concave part 22 is formed in the surface is performed by etching with respect to the convex part 21. In the case of flattening, the substrate 12 is flattened by depositing in the concave portion 22 decomposition products generated by dissociating reactive gas in the concave portion 22.

  By the surface flattening method to which the present invention is applied, it is possible to flatten even a concavo-convex portion of several nm size, which could not be polished by conventional CMP, and has a surface property flat to the atomic level. I can get it. Further, in the present invention, since the planarization is performed using non-resonant light, the reaction proceeds only at the uneven portion of several nm size on the surface of the substrate 12, thereby Flattening can be performed without forming scratches or the like on the flat portion.

  Further, according to the surface planarization method to which the present invention is applied, as the reaction proceeds, the unevenness of the substrate surface where near-field light is generated is removed, and the planarization process is automatically terminated. For this reason, planarization is performed in a self-organized manner without performing special control from others, and the process in the planarization becomes very simple.

  The surface flattening apparatus 1 includes, for example, a gas supply unit 17 used in a photo CVD (Chemical Vapor Deposition) apparatus, a sputtering apparatus, a photo-excited etching apparatus, a reactive ion etching apparatus, an inductively coupled plasma etching apparatus, and the like. The light source 14 and the chamber 11 may be used as they are. In this case, the surface planarization method to which the present invention is applied can be realized only by changing only the wavelength of the light source of the photo-CVD apparatus. When the wavelength of the light source is changed, white light may be emitted from the light source and passed through a color filter through the aperture window 18 or the like, and monochromatic light may be emitted.

  Moreover, when the convex part 21 and the concave part 22 are too large, such as the size is 1 mm or more, the time required for reaction becomes enormous. For this reason, in this case, the surface of the substrate 12 may be polished to some extent by using a CMP apparatus or the like in advance, and the present invention may be applied as a subsequent finishing process.

  Also, for example, when a silicon wafer is applied as the substrate 12 and the recess is planarized, a silane-based gas having an absorption edge wavelength of 160 nm is introduced as a source gas, and light having a wavelength of about 325 nm is irradiated. Thus, the recess can be flattened.

  Further, for example, when a Cr thin film laminated on the substrate is applied as the substrate 12 and the recess is flattened, chromocene or hexacarbonyl chromium is introduced as a source gas, and the wavelength is about 488 to 688 nm. Irradiation with light makes it possible to flatten the recess.

  As described above, when planarizing a substrate having a recess, it is desirable to use a source gas containing molecules and compounds consisting of the constituent elements of the substrate, but a raw material containing molecules other than the constituent elements of the substrate. Even if gas is applied, there is no particular problem in flattening.

It is a figure for demonstrating the shape of the board | substrate used as the object of this invention. 1 is a schematic diagram showing the configuration of a surface flattening device used for realizing the present invention. It is a figure for demonstrating resonant light and non-resonant light. It is a figure for demonstrating a non-resonance process. It is a figure for demonstrating the process of planarizing the board | substrate which has a convex part. It is a figure for demonstrating reaction which generate | occur | produces in the local area | region of a convex part. It is a figure for demonstrating the process of planarizing the base | substrate which has a recessed part. It is a figure for demonstrating reaction which generate | occur | produces in the local area | region of a recessed part.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Surface planarization apparatus 11 Chamber 12 Board | substrate 13 Stage 14 Light source 15 Reflection mirror 16 Illumination optical system 17 Gas supply part 18 Opening window 19 Exhaust port 21 Convex part 22 Concave part

Claims (4)

In a surface flattening method for flattening a recess formed on a substrate surface or a thin film surface laminated on the substrate,
Placing the substrate in a chamber into which the source gas is introduced,
By irradiating the concave portion with light having a wavelength longer than the absorption edge wavelength of the gas molecules of the source gas, near-field light is generated in the local region of the concave portion,
Based on the near-field light generated in the recess, the source gas is dissociated through a non-resonant process to generate a decomposition product,
A method of planarizing a surface, comprising depositing the generated decomposition product in the recess to flatten the recess. The surface planarization method according to claim 1, wherein the source gas is a molecule or a compound composed of a constituent element of the substrate or the thin film. In a surface flattening method for flattening a convex portion formed on a substrate surface or a thin film surface laminated on the substrate,
Placing the substrate in a chamber into which a reactive gas is introduced;
By irradiating the convex part with light having a wavelength longer than the absorption edge wavelength of the gas molecules of the reactive gas, near field light is generated in a local region of the convex part,
Based on the near-field light generated in the local region of the convex part, the reactive gas is dissociated through a non-resonant process to generate active species,
A surface flattening method comprising removing the protrusions by chemically reacting the generated active species with the protrusions to generate a reaction product. The surface flattening method according to claim 3, wherein the reactive gas is composed of a fluorine-based gas.