KR102374073B1 - Wafer processing deposition shielding components - Google Patents

Abstract

SUMMARY Embodiments described herein relate generally to an apparatus and method for uniformly sputter depositing materials to the bottom and sidewalls of a high aspect ratio feature on a substrate. In one embodiment, a collimator is provided for mechanical and electrical coupling with a shield member positioned between a substrate support pedestal and a sputtering target. The collimator includes a central region and a peripheral region and has a plurality of openings extending therethrough, wherein the openings disposed in the central region have a greater aspect ratio than the openings disposed in the peripheral region.

Description

Wafer Processing Deposition Shielding Components {WAFER PROCESSING DEPOSITION SHIELDING COMPONENTS}

Embodiments of the present invention relate generally to a method and apparatus for uniformly sputter depositing material to the bottom and sidewalls of high aspect ratio features in a substrate.

BACKGROUND Sputtering, or physical vapor deposition (PVD), is a widely used technique for depositing thin metal layers on a substrate in the manufacture of integrated circuits. PVD is used to deposit layers for use as diffusion barriers, seed layers, primary conductors, antireflection coatings, and etch stops. However, with PVD, it is difficult to form a uniform thin film conforming to the shape of the substrate on which the step occurs, such as vias or trenches formed in the substrate. In particular, depositing sputtered atoms with a wide angular distribution results in poor coverage on the bottom and sidewalls of high aspect ratio features, such as vias and trenches.

One technique that has been developed to allow PVD to be used to deposit thin films on the bottom of high aspect ratio features is collimator sputtering. The collimator is a filtering plate positioned between the substrate and the sputtering source. The collimator is generally uniform in thickness and has a plurality of passages formed through the thickness. The sputtered material must pass through the collimator on its path from the sputtering source to the substrate. The collimator filters out material that could have collided with the material at an acute angle beyond the required angle.

The actual amount of filtering done by a given collimator depends on the aspect ratio of the passage through the collimator. In this way, particles traveling in a path perpendicular to the substrate pass through the collimator and are deposited on the substrate. This can improve the coverage of the floor in high aspect ratio features.

However, there are certain problems in using the prior art collimator with a small magnet magnetron. The use of a magnetron of a small magnet can produce a highly ionized metal flux, which can be advantageous for filling high aspect ratio features. Unfortunately, however, PVD using a prior art collimator with a magnetron of a small magnet results in non-uniform deposition across the substrate. Thicker layers of source material may be deposited in one region of the substrate than in another region of the substrate. For example, depending on the radial position of the miniature magnet, thicker layers may be deposited near the center or edge of the substrate. This phenomenon not only results in non-uniform deposition across the substrate, but also non-uniform deposition across high aspect ratio feature sidewalls in certain areas of the substrate. For example, feature sidewalls facing the center of the substrate rather than feature sidewalls facing the perimeter of the substrate when small magnets are radially disposed to provide optimal field uniformity in an area near the perimeter of the substrate. More source material is deposited on the fields.

Therefore, there is a need to improve the uniformity in depositing a source material on a substrate with PVD technology.

In one embodiment described herein, the deposition apparatus is an electrically grounded chamber, a sputtering target supported by the chamber and electrically isolated from the chamber, located below the sputtering target and substantially coextensive with the sputtering surface of the sputtering target. a substrate support pedestal having a substrate support surface parallel to the substrate, a shield member supported by and electrically coupled to the chamber, mechanically and electrically coupled to the shield member, the sputtering target and the and a collimator positioned between the substrate support pedestals. In one embodiment, the collimator has a plurality of apertures therethrough. In one embodiment, the openings disposed in the central region have a greater aspect ratio than the openings disposed in the peripheral region.

In another embodiment, a deposition apparatus includes an electrically grounded chamber, a sputtering target supported by and electrically isolated from the chamber, a substrate positioned below the sputtering target and substantially parallel to a sputtering surface of the sputtering target. a substrate support pedestal having a support surface, a shield member supported by the chamber and electrically coupled to the chamber, a collimator mechanically and electrically coupled to the shield member and positioned between the sputtering target and the substrate support pedestal, a gas source; , and a controller. In one embodiment, the sputtering target is electrically coupled to a DC power source. In one embodiment, the substrate support pedestal is electrically coupled to an RF power source. In one embodiment, the controller is programmed to provide signals for controlling the gas source, the DC power source, and the RF power source. In one embodiment, the collimator has a plurality of apertures extending therethrough. In one embodiment, the openings disposed in the central region of the collimator have a greater aspect ratio than the openings disposed in the peripheral region of the collimator. In one embodiment, the controller is programmed to provide a high bias to the substrate support pedestal.

In yet another embodiment, a method for depositing material onto a substrate comprises applying a DC bias to a sputtering target in a chamber having a collimator positioned between a substrate support pedestal and a sputtering target, in a region adjacent to the sputtering target within the chamber. The method includes providing a processing gas, applying a bias to the substrate support pedestal, and pulsing a bias applied to the substrate support pedestal between a high bias and a low bias. In one embodiment, the collimator has a plurality of apertures extending therethrough. In one embodiment, the openings disposed in the central region of the collimator have a greater aspect ratio than the openings disposed in the peripheral region of the collimator.

In yet another embodiment, a collimator for mechanical and electrical coupling with a shield member positioned between a substrate support pedestal and a sputtering target is provided. The collimator includes a central region and a peripheral region and has a plurality of openings extending therethrough, wherein the openings disposed in the central region have a greater aspect ratio than the openings disposed in the peripheral region.

In yet another embodiment, a lower shield is provided for enclosing a substrate support pedestal facing a target within a substrate processing chamber. the lower shield comprises a cylindrical outer band having a first diameter dimensioned to surround the substrate support pedestal and a sputtering surface of the sputtering target, the cylindrical outer band comprising an upper portion surrounding the sputtering surface of the sputtering target; a support flange comprising a middle portion and a lower portion surrounding the substrate support pedestal, the lower shield also extending radially outwardly from the cylindrical outer band and having a resting surface; a base plate extending radially inwardly from a lower portion of the cylindrical outer band; and a cylindrical inner band engaging the base plate and partially surrounding a peripheral edge of the substrate support pedestal.

In yet another embodiment, an upper shield is provided for enclosing a sputtering target facing a support pedestal within a substrate processing chamber. The upper shield includes a shield portion and an integrated flux optimizer for directional sputtering.

In order that the foregoing features of the invention may be understood in detail, a more detailed description of the invention, briefly summarized above, may be made with reference to embodiments, some of which are illustrated in the accompanying drawings, in which there is. However, the accompanying drawings merely illustrate exemplary embodiments of the present invention, and are not intended to limit the scope of the present invention, and the present invention may include other equally effective embodiments.
1 shows a schematic cross-sectional view of a semiconductor processing system having one embodiment of a process kit described herein;
2 shows a top view of a collimator according to an embodiment described herein;
3 shows a schematic cross-sectional view of a collimator according to an embodiment described herein;
4 shows a schematic cross-sectional view of a collimator according to an embodiment described herein;
5 shows a schematic cross-sectional view of a collimator according to an embodiment described herein;
6 shows an enlarged partial cross-sectional view of a bracket for attaching a collimator to an upper shield of a PVD chamber according to an embodiment described herein;
7 shows a partial cross-sectional view of a bracket for attaching a collimator to an upper shield of a PVD chamber according to one embodiment described herein;
8 shows a schematic cross-sectional view of a semiconductor processing system having another embodiment of a process kit described herein;
9A shows a partial cross-sectional view of a monolithic upper shield according to an embodiment described herein;
9B shows a top view of the monolithic upper shield of FIG. 9A in accordance with one embodiment described herein;
10A shows a cross-sectional view of a lower shield according to an embodiment described herein;
10C shows a top view of one embodiment of the lower shield of FIG. 10A.

Embodiments described herein provide an apparatus and method for uniformly depositing sputtered material across high aspect ratio features of a substrate during integrated circuit fabrication on the substrate.

1 shows an exemplary embodiment of a processing chamber 100 having a process kit 140 of one embodiment capable of processing a substrate 154 . The process kit 140 includes a one-piece lower shield 180 , a one-piece upper shield 186 , and a collimator 110 . The processing chamber 100 in the illustrated embodiment is also referred to as a physical vapor deposition (PVD) chamber, capable of depositing, for example, titanium, aluminum oxide, aluminum, copper, tantalum, tantalum nitride, tungsten, or tungsten nitride onto a substrate. It includes a so-called sputtering chamber. Examples of suitable PVD chambers include the ALPS ^® Plus and SIP ENCORE ^® PVD processing chambers, both of which are manufactured by Applied Materials, Inc. of Santa Clara, CA. can be purchased from In practicing the embodiments described herein, processing chambers available from other manufacturers may also be used.

The chamber 100 includes a sputtering source, such as a target 142 having a sputtering surface 145 , and a substrate support pedestal 152 for receiving thereon a semiconductor substrate 154 , having a peripheral edge 153 . include A substrate support pedestal may be disposed within the grounded chamber wall 150 .

In one embodiment, chamber 100 includes a target 142 supported by a conductive adapter 144 grounded through a dielectric isolator 146 . The target 142 includes material to be deposited on the surface of the substrate 154 during sputtering, and may include copper to deposit as a seed layer in high aspect ratio features formed in the substrate 154 . In one embodiment, the target 142 may also include a bonded composite in which a backing layer of a structural material, such as aluminum, and a metallic surface layer, of a sputterable material, such as copper, are bonded.

In one embodiment, the pedestal 152 supports a substrate 154 having high aspect ratio features to be sputter coated, the bottom of which is in planar opposition to a major surface of the target 142 . ). The substrate support pedestal 152 has a flat substrate receiving surface disposed generally parallel to the sputtering surface of the target 142 . The pedestal 152 may be vertically movable through a bellows 158 connected to the bottom chamber wall 160 such that the substrate 154 may be moved through a load lock valve (not shown) in the lower portion of the chamber 100 . Allows it to be carried on a pedestal 152 . The pedestal 152 may then be raised to the deposition position as shown.

In one embodiment, processing gas may be supplied from a gas source 162 through a mass flow controller 164 to the lower portion of the chamber 100 . In one embodiment, a controllable direct current (DC) power source 148 coupled to chamber 100 may be used to apply a bias or negative voltage to target 142 . A radio frequency (RF) power source 156 may be coupled to the pedestal 152 to induce DC self-bias with respect to the substrate 154 . In one embodiment, pedestal 152 is grounded. In one embodiment, pedestal 152 is electrically floated.

In one embodiment, the magnetron 170 is positioned above the target 142 . The magnetron 170 may include a plurality of magnets 172 supported by a base plate 174 coupled to a shaft 176 , wherein the shaft is the central axis and axis of the substrate 154 and the chamber 100 . direction can be aligned. In one embodiment, the magnets are arranged in a kidney-shaped pattern. A magnet 172 is placed in the chamber 100 near the front face of the target 142 to generate a plasma such that a significant ion flux strikes the target 142 causing sputter emission of the target material. create a magnetic field The magnet 172 may be rotated about the shaft 176 to increase the uniformity of the magnetic field across the surface of the target 142 . In one embodiment, the magnetron 170 is a magnetron of small magnets. In one embodiment, the magnets 172 may be reciprocally moved and rotated along a linear direction substantially parallel to the face of the target 142 to create a helical motion. In one embodiment, the magnets 172 may be rotated about both a central axis and an independently controlled second axis to control both their radial and angular positions.

In one embodiment, chamber 100 includes a grounded lower shield 180 having a support flange 182 electrically coupled to and supported by chamber sidewall 150 . The upper shield 186 is electrically coupled to and supported by the flange 184 of the adapter 144 . Upper shield 186 and lower shield 180 are electrically coupled, as are chamber wall 150 and adapter 144 . In one embodiment, both upper shield 186 and lower shield 180 are constructed of stainless steel. In one embodiment, chamber 100 includes an intermediate shield (not shown) coupled to upper shield 186 . In one embodiment, upper shield 186 and lower shield 180 are electrically suspended within chamber 100 . In one embodiment, upper shield 186 and lower shield 180 may be coupled to an electrical power source.

In one embodiment the upper shield 186 is assembled closely with an annular side recess of the target 142 with a narrow gap 188 between the target 142 and the upper shield 186 . This gap is narrow enough to prevent the plasma from passing through and sputter coating the dielectric insulator 146 . The upper shield 186 may also include a downwardly projecting tip 190, which covers the interface between the upper shield 186 and the lower shield 180 so that the upper and lower shields are joined by sputter deposited material. prevent it from becoming

In one embodiment, the lower shield 180 extends downwardly into a cylindrical outer band 196 , which extends generally along the chamber wall 150 to below the upper surface of the pedestal 152 . The lower shield 180 may have a base plate 198 extending radially inward from this cylindrical outer band 196 . Base plate 198 may include an upwardly extending cylindrical inner band 103 that surrounds a perimeter of pedestal 152 . In one embodiment, to protect the pedestal 152 from sputter deposition, a covering 102 overlies the cylindrical inner band 103 when the pedestal 152 is in a lower loading position and , rests on the outer perimeter of the pedestal 152 when the pedestal is in the upper deposition position.

The lower shield 180 surrounds the sputtering surface 145 of the sputtering target 142 facing the support pedestal 152 , and also surrounds the peripheral wall of the support pedestal 152 . The lower shield 180 is a chamber wall of the chamber 100 to reduce sputtering deposits generated from the sputtering surface 145 of the sputtering target 142 from depositing on the surfaces and components behind the lower shield 180 . Cover and shadow (150). For example, the lower shield 180 may protect the bottom wall 160 of the chamber 100 , the chamber wall 150 , portions of the substrate 154 , and the surfaces of the support pedestal 152 .

In one embodiment, directional sputtering may be achieved by disposing the collimator 110 between the substrate support pedestal 152 and the target 142 . The collimator 110 may be mechanically and electrically coupled to the upper shield 186 . In an embodiment, the collimator 110 may be coupled to an intermediate shield (not shown) positioned at a lower portion of the chamber 100 . In one embodiment, the collimator 110 is integral with the upper shield 186 as shown in FIG. 8 . In one embodiment, the collimator 110 is welded to the upper shield 186 . In one embodiment, the collimator 110 may be electrically floating within the chamber 100 . In one embodiment, the collimator 110 may be coupled to an electrical power source. Collimator 110 includes a plurality of openings (not shown in FIG. 1 ) for directing gas and/or material flux into the chamber.

2 shows a plan view of one embodiment of the collimator 110 . Collimator 110 is generally a honeycomb structure having hexagonal walls 126 that separate hexagonal openings 128 in a close-packed arrangement. The aspect ratio of the hexagonal openings 128 may be defined as the depth of the opening 128 (equal to the thickness of the collimator) divided by the width 129 of the opening 128 . In one embodiment, the thickness of the wall 126 is between about 0.06 inches and about 0.18 inches. In one embodiment, the thickness of the wall 126 is between about 0.12 inches and about 0.15 inches. In one embodiment, the collimator 110 is constructed of a material selected from aluminum, copper, and stainless steel.

3 is a schematic cross-sectional view of a collimator 310 according to an embodiment described herein. Collimator 310 includes a central region having a high aspect ratio, such as from about 1.5:1 to about 3:1. In one embodiment, the aspect ratio of the central region 320 is about 2.5:1. The aspect ratio of the collimator 310 decreases with a radial distance from the central region 320 to the outer peripheral region 340 . In one embodiment, the aspect ratio of the collimator 310 decreases from a central region 320 aspect ratio of about 2.5:1 to a peripheral region 340 aspect ratio of about 1:1. In another embodiment, the aspect ratio of the collimator 310 decreases from a central region 320 aspect ratio of about 3:1 to a peripheral region 340 aspect ratio of about 1:1. In one embodiment, the aspect ratio of the collimator 310 decreases from a central region 320 aspect ratio of about 1.5:1 to a peripheral region 340 aspect ratio of about 1:1.

In one embodiment, the radial aperture reduction of the collimator 310 is achieved by varying the thickness of the collimator 310 . In one embodiment, the central region 320 of the collimator 310 has an increased thickness, such as from about 3 inches to about 6 inches. In one embodiment, the thickness of the central region 320 of the collimator 310 is about 5 inches. In one embodiment, the thickness of the collimator 310 decreases from the central region 320 to the outer peripheral region 320 . In one embodiment, the thickness of the collimator 310 decreases radially from a central region 320 thickness of about 5 inches to a peripheral region 340 thickness of about 2 inches. In one embodiment, the thickness of the collimator 310 decreases radially from a central region 320 thickness of about 6 inches to a peripheral region 340 thickness of about 2 inches. In one embodiment, the thickness of the collimator 310 decreases radially from a central region 320 thickness of about 2.5 inches to about 2 inches.

Although the aspect ratio variation of the collimator 310 embodiment shown in FIG. 3 shows a radially decreasing thickness, the aspect ratio increases the width of the openings of the collimator 310 from the central region 320 to the peripheral region 340. can also be reduced by In another embodiment, the width of the openings of the collimator 310 from the central region 320 to the peripheral region 340 increases and the thickness of the collimator 310 decreases.

Broadly, the embodiment of FIG. 3 shows a linear, radially decreasing aspect ratio, resulting in an inverted cone shape. Other embodiments of the present invention may include non-linear reductions in aspect ratio.

4 shows a schematic cross-sectional view of a collimator 410 according to an embodiment of the present invention. The collimator 410 has a thickness that decreases non-linearly from the central region 420 to the peripheral region 440 such that it has a convex shape.

5 shows a schematic cross-sectional view of a collimator 510 according to an embodiment of the present invention. The collimator 510 has a thickness that decreases non-linearly from the central region 520 to the peripheral region 540 such that it has a concave shape.

In some embodiments, the area of the central regions 320 , 420 , 520 approaches zero such that the central regions 320 , 420 , 520 appear as a point at the bottom of the collimator 310 , 410 , 510 . .

Referring back to FIG. 1 , the operation of the PVD process chamber 100 and the function of the collimator 110 are the same regardless of the exact shape of the radially decreasing collimator 110 aspect ratio. A system controller 101 is provided outside the chamber 100 to enable overall system control and automation. The system controller 101 may include a central processing unit (CPU) (not shown), a memory (not shown), and support circuits (not shown). The CPU is for controlling various system functions and chamber processes, and may be one of all computer processors used in industrial sites.

In one embodiment, the system controller 101 places the substrate 154 on the substrate support pedestal 152 and provides signals to generate a plasma within the chamber 100 . System controller 101 sends signals to apply a voltage through DC power source 148 to bias a target 142 and excite a processing gas, such as argon, into a plasma. The system controller 101 may further provide signals that cause the RF power source 156 to DC self-bias the pedestal 152 . DC self bias helps to draw positively charged ions generated in the plasma deep into the high aspect ratio vias and trenches on the surface of the substrate.

The collimator 110 acts as a filter to trap neutrals and ions emitted from the target 142 at an angle beyond a selected angle, approximately perpendicular to the substrate 154 . The collimator 110 may be one of the collimators 310 , 410 , or 510 illustrated in FIGS. 3 , 4 , or 5 , respectively. The nature of the collimator 110 having an aspect ratio that decreases radially from the center allows a greater proportion of the ions emitted from the peripheral region of the target 142 to pass through the collimator 110 . As a result, both the angle of arrival of the ions deposited on the peripheral region of the substrate 154 and the number of ions are increased. Accordingly, according to embodiments of the present invention, the material may be more uniformly sputter deposited over the surface of the substrate 154 . In addition, material may be more uniformly deposited on the bottom and sidewalls of high aspect ratio features, particularly high aspect ratio vias and trenches located near the perimeter of the substrate 154 .

Further, to further increase the coverage of the sputter deposited material on the bottom and sidewalls of the high aspect ratio features, the sputter deposited material onto the field and bottom area of the features may be sputter etched. In one embodiment, the system controller 101 applies a high bias to the pedestal 152 such that the target ions 142 etch a film already deposited on the substrate 154 . As a result, the field deposition rate onto the substrate 154 decreases and the sputtered material redeposits on the bottom or sidewalls of the high aspect ratio features. In one embodiment, the system controller 101 applies a high and low bias to the pedestal 152 in a pulsed or alternating fashion such that the process is a pulsing deposit/etch process. In one embodiment, the collimator 110 cells, particularly located below the magnets 172 , direct most of the deposition material towards the substrate 154 . Thus, at any particular point in time, material may be deposited in one area of the substrate 154 while material already deposited in another area of the substrate 154 may be etched.

In one embodiment, to further increase the coverage of sputter deposited material onto the sidewalls of high aspect ratio features, a secondary plasma, such as argon plasma, is used, generated in the chamber 100 region proximate the substrate 154 . to sputter etch the sputter deposited material onto the bottom of the features. In one embodiment, chamber 100 includes an RF coil 141 attached to a lower shield 180 by a plurality of coil standoffs 143 , wherein the coil standoffs are coil 141 . ) is electrically insulated from the lower shield 180 . The system controller 101 transmits signals for applying RF power to the coil 141 via the shield 180 via feedthrough standoffs (not shown). In one embodiment, an RF coil inductively couples RF energy into the interior of the chamber 100 to ionize a precursor gas, such as argon, to maintain a secondary plasma in the vicinity of the substrate 154 . . The secondary plasma resutters the deposited layer from the bottom of the high aspect ratio feature and redeposits this material onto the sidewalls of the feature.

Still referring to FIG. 1 , the collimator 110 may be attached to the upper shield 186 by a plurality of radial brackets 111 .

6 shows an enlarged cross-sectional view of a bracket 611 for attaching the collimator 110 to the upper shield 186 in accordance with one embodiment of the present invention. Bracket 611 includes an internally threaded tube 613 welded to and extending radially outwardly from collimator 110 . A fastening member 615 , such as a screw, is inserted through the opening in the upper shield 186 and screwed into the tube 613 , such that material is deposited onto the fastening member 615 or the threaded portion of the tube 613 . It is possible to attach the collimator 110 to the upper shield 186 while minimizing .

7 shows an enlarged cross-sectional view of a bracket 711 for attaching the collimator 110 to the upper shield 186 in accordance with another embodiment of the present invention. Bracket 711 includes studs 713 welded to and extending radially outwardly from collimator 110 . An internally threaded fastening member 715 is inserted through the opening in the upper shield 186 and threaded onto the stud 713 , such that material is deposited onto the fastening member 715 or threaded portion of the stud 713 . It is possible to attach the collimator 110 to the upper shield 186 while minimizing .

8 is a schematic cross-sectional view of a semiconductor processing system 800 having another embodiment process kit 840 described herein. Similar to process kit 140 , process kit 840 includes a one-piece lower shield 180 . However, unlike process kit 140 which includes a separate collimator 110 coupled to upper shield 186 by radial bracket 111 , process kit 840 is flux optimized integral with shield portion 892 . and a monolithic upper shield 886 including an integrated flux optimizer portion 810 . The integral structure of the monolithic upper shield 886 enables maximization of cooling efficiency. The integral flux optimizer 810 includes a plurality of apertures (not shown in FIG. 8 ) for directing gas and/or material fluxes into the chamber as discussed above.

9A shows a partial cross-sectional view of a monolithic upper shield 886 in accordance with one embodiment described herein. 9B shows a top view of the monolithic upper shield 886 of FIG. 9A in accordance with one embodiment described herein. The monolithic upper shield 886 is sized to enclose the sputtering surface 145 of the sputtering target 142 facing the support pedestal 152 . The monolithic upper shield 886 obscures the adapter 144 of the chamber 100 to reduce deposition of sputtering deposits occurring on the sputtering surface 145 of the sputtering target 142 .

8 , 9A , and 9B , the monolithic upper shield 886 is of a unitary construction and includes a shield portion 892 and an integral flux optimizer 810 . For example, shield portion 892 and integral flux optimizer 810 may be fabricated from a single mass of material. The shield portion 892 includes a cylindrical band 902 . The cylindrical band 902 includes an upper wall 904 and a lower wall 906 . A support flange 908 extends radially outward from the top wall 904 of the cylindrical band 902 . The support flange 908 includes a support surface 910 for resting on the adapter 144 of the chamber 800 . In one embodiment, the support surface 910 intersects the lower wall 906 to form a 90 degree angle. In one embodiment, the support flange 908 has a plurality of slots configured to receive pins for aligning the upper shield 892 with the adapter 144 . In one embodiment, the support flange 908 has one or a plurality of notches 940 disposed periodically around the cylindrical band 902 .

As shown in FIG. 9A , the upper wall 904 further includes an upper surface 925 , an inner perimeter 926 , and an outer perimeter 928 . An outer perimeter 928 of the upper wall 904 intersects the support flange 908 to form a stepped portion 932 .

In one embodiment, as shown in FIG. 8 , lower wall 906 of cylindrical band 902 is assembled into adapter 144 and stepped portion 1032 of lower shield 180 (shown in FIG. 10B ). has an outer diameter, indicated by arrow "A", dimensioned to be supported on In one embodiment, the outer diameter “A” of the lower wall 906 is from about 18 inches (45.7 cm) to about 18.5 inches (47 cm). In another embodiment, the outer diameter “A” of the lower wall 906 is from about 18.1 inches (46 cm) to about 18.2 inches (46.2 cm). In one embodiment, the cylindrical band 902 has an inner diameter indicated by arrow “B”. In one embodiment, the inner diameter “B” of the cylindrical band 902 is between about 17.2 inches (43.7 cm) and about 17.9 inches (45.5 cm). In another embodiment, the inner diameter “B” of the cylindrical band 902 is between about 17.5 inches (44.5 cm) and about 17.7 inches (45 cm). In one embodiment, the top wall 904 has an outer diameter indicated by arrow “C”. In one embodiment, upper wall 904 and lower wall 906 have the same inner diameter “B”.

In one embodiment, the outer diameter “C” of the top wall 904 is from about 18 inches (45.7 cm) to about 18.5 inches (47 cm). In another embodiment, the outer diameter “C” of the top wall 904 is between about 18.3 inches (46.5 cm) and about 18.4 inches (46.7 cm). In one embodiment, the outer diameter “C” of the upper wall 904 is greater than the outer diameter “A” of the lower wall 906 .

The integral flux optimizer 810 may be designed similarly to one of the collimators 310, 410, and 510 shown in FIGS. 3, 4, and 5, respectively. As shown in FIG. 9B , the integral flux optimizer 810 is a honeycomb structure having a hexagonal wall 942 that separates the hexagonal openings 944 in a generally close-packed arrangement. The aspect ratio of the hexagonal opening 944 may be defined as the depth of the opening 944 (equivalent to the thickness of the integral flux optimizer 810 ) divided by the width 946 of the opening. In one embodiment, the hexagonal wall 942 adjacent the shield portion 892 has a chamfer 950 and a radius.

In one embodiment, the monolithic upper shield 886 may be machined from a single piece of aluminum. The monolithic upper shield 886 may optionally be coated or anodized. Alternatively, the monolithic upper shield 886 may be fabricated from other materials suitable for the processing environment, and may consist of one or multiple sections. Alternatively, the integral flux optimizer 810 and shield portion 892 of the upper shield may be formed as separate parts and joined together using a suitable attachment method, such as welding.

10A and 10B show partial cross-sectional views of a lower shield in accordance with embodiments described herein. 10C is a plan view of an embodiment of the lower shield shown in FIG. 10A . 1 and 10A-C , the lower shield 180 is of a unitary structure and includes a cylindrical outer band 196 , a base plate 198 , and an inner cylindrical band 103 . The cylindrical outer band 196 has a diameter sized to surround the peripheral edge 153 of the pedestal 152 and the sputtering surface 145 of the sputtering target 142 . The cylindrical outer band 196 includes an upper portion 1012 , a middle portion 1014 , and a lower portion 1016 . The upper portion 1012 is sized to surround the sputtering surface 145 of the sputtering target 142 . A support flange 182 extends radially outward from the upper portion 1012 of the cylindrical outer band 196 . The support flange 182 includes a support surface 1024 for resting on the chamber walls 150 of the chamber 100 . The support surface 1024 has a plurality of slots formed to receive pins for aligning the lower shield 180 with the chamber walls 150 or any adapters located between the chamber walls 150 and the lower shield 180 . can In one embodiment, the support surface 1024 has a surface roughness of between about 10 and about 80 microinches, or between about 16 and about 63 microinches, or in one embodiment an average surface roughness of about 32 microinches. have

As shown in FIG. 10B , upper portion 1012 includes an upper surface 1025 , an inner perimeter 1026 , and an outer perimeter 1028 . The outer perimeter 1028 extends above the upper surface 1025 to form an annular lip 1030 . The annular lip 1030 forms a stepped portion 1032 with the upper surface 1025 . In one embodiment, the annular lip 1030 is disposed perpendicular to the upper surface 1025 to form a stepped portion 1032 . Stepped portion 1032 provides a support surface for interfacing with upper shield 186 .

In one embodiment, the annular lip 1030 has an outer diameter indicated by arrow “D”. In one embodiment, the outer diameter “D” of the annular lip 1030 is from about 18.4 inches (46.7 cm) to about 18.7 inches (47.5 cm). In another embodiment, the outer diameter “D” of the annular lip 1030 is from about 18.5 inches (47 cm) to about 18.6 inches (47.2 cm). In one embodiment, the annular lip 1030 has an inner diameter shown by arrow “E”. In one embodiment, the inner diameter “E” of the annular lip 1030 is from about 18.2 inches (46.2 cm) to about 18.5 inches (47 cm). In another embodiment, the inner diameter “E” of the annular lip 1030 is from about 18.3 inches (46.5 cm) to about 18.4 inches (46.7 cm).

In one embodiment, the outer diameter of the upper surface 1025 is equal to the inner diameter “E” of the annular lip 1030 . In one embodiment, the upper surface has an inner diameter indicated by arrow “F”. In one embodiment, the inner diameter “F” of the top surface 1025 is from about 17.2 inches (43.7 cm) to about 18 inches (45.7 cm). In another embodiment, the inner diameter “F” of the top surface 1025 is between about 17.5 inches (44.5 cm) and about 17.6 inches (44.7 cm).

In one embodiment, the inner perimeter 1026 of the upper portion 1012 slopes radially outward at an angle α from vertical. In one embodiment, the angle α is from about 2 degrees to about 10 degrees from vertical. In one embodiment, the angle α is about 4 degrees from vertical.

The lower portion 1016 is sized to surround the pedestal 152 . Base plate 198 extends radially inward from lower portion 1016 of cylindrical outer band 196 . The cylindrical inner band 103 engages the base plate 198 and is sized to surround the pedestal 152 . Cylindrical inner band 103, base plate 198, and cylindrical outer band 196 form a U-shaped channel. Cylindrical inner band 103 has a height less than the height of cylindrical outer band 196. One In an embodiment, the height of the inner cylindrical band 103 is about one-fifth the height of the cylindrical outer band 196. In one embodiment, the middle portion 1014 has a notch 1040. In one embodiment, the cylindrical The outer band 196 has a plurality of gas apertures 1042 .

In one embodiment, base plate 198 has an outer diameter indicated by arrow “G”. In one embodiment, the outer diameter “G” of the base plate 198 is from about 17 inches (43.2 cm) to about 17.4 inches (44.2 cm). In another embodiment, the outer diameter “G” of the base plate 198 is from about 17.1 inches (43.4 cm) to about 17.2 inches (43.7 cm). In one embodiment, base plate 198 has an inner diameter indicated by arrow “I”. In one embodiment, the inner diameter “I” of the base plate 198 is from about 13.9 inches (35.3 cm) to about 14.4 inches (36.6 cm). In another embodiment, the inner diameter “I” of the base plate 198 is from about 14 inches (35.6 cm) to about 14.1 inches (35.8 cm).

In one embodiment, the inner cylindrical band 103 has an outer diameter indicated by arrow “H”. In one embodiment, the outer diameter “H” of the inner cylindrical band is from about 14.0 inches (35.6 cm) to about 14.3 inches (36.3 cm). In another embodiment, the outer diameter “H” of the inner cylindrical band 103 is from about 14.2 inches (36.1 cm) to about 14.3 inches (36.3 cm).

In one embodiment, the outer cylindrical band 196, the base plate 198, and the inner cylindrical band 103 are of a single structure. The unitary lower shield 180 has advantages over conventional shields that have included multiple parts, often two or three separate parts, to form the entire lower shield. For example, a single piece shield is more thermally uniform than a multi-piece shield. For example, the single-piece lower shield 180 has only one thermal interface to the chamber wall 150 , allowing better control over heat exchange between the shield 180 and the chamber wall 150 . make it A shield 180 having multiple parts is more difficult and laborious to remove the shield for cleaning. The single shield 180 has a continuous surface that is exposed to sputtering deposits, with no connections or corners that are more difficult to clean. The single shield 180 also more effectively shields the chamber walls 150 from sputter deposition during the process cycle.

In one embodiment, the upper shields 186 , 886 and/or the lower shield 180 may be made from 300 series stainless steel, or, in another embodiment, from aluminum. In one embodiment, the exposed surfaces of the upper shields 186, 886 and/or the lower shield 180 are treated with CLEANCOAT ^™ , which is manufactured by Applied Materials, Inc. of Santa Clara, CA. can be purchased from CLEANCOAT ^™ is applied to substrate processing chamber components, such as upper shield 186, 886 and/or lower shield 180, to reduce particle shedding of deposits to the shields to reduce the amount of substrate in the chamber. It is a twin-wire aluminum arc spray coating that prevents contamination. In one embodiment, the twin-wire aluminum arc spray coating on the upper shields 186 , 886 and/or the lower shield 180 has a surface roughness of about 600 to about 2300 microinches.

Upper shield 186 , 886 and/or lower shield 180 have exposed surfaces facing the interior volume within chamber 100 , 800 . In one embodiment, the exposed surfaces are bead blasted to have a surface finish of 175±75 microinches. The textured bead blast treated surfaces serve to reduce particle shedding and prevent contamination within the chambers 100 , 800 . The surface roughness mean is the mean of the absolute values of displacements from the mean line of peaks and valleys of roughness features along the exposed surface. Roughness mean, skewness, or other properties are measured by passing a needle over an exposed surface to produce a trace of fluctuations in the height of asperities on the surface. (profilometer), or by scanning electron microscopy, which uses a beam of electrons reflected from the surface to create an image of the surface.

Although the foregoing relates to embodiments of the present invention, other and further embodiments of the present invention may be devised within the basic scope of the present invention, the scope of the present invention being as determined by the claims.

Claims (20)

A monolithic collimator assembly comprising:
an upper shield portion having a cylindrical band; and
a collimator part; including;
The upper shield part
an upper wall having a first outer diameter and a support flange, the support flange extending radially outwardly from the upper wall; and
a lower wall having a second outer diameter, wherein the first outer diameter is greater than the second outer diameter;
The collimator part is
a body structure having walls separating and defining respective openings of the plurality of first openings and the plurality of second openings;
The body structure is
a first region having the plurality of first openings in a first aspect ratio defined by a depth and a width; and
a second region disposed radially outwardly of the first region; and
wherein the second region has the plurality of second openings in a second aspect ratio defined by a depth and a width, the first aspect ratio being different from the second aspect ratio;
Monolithic collimator assembly.
According to claim 1,
wherein a first aspect ratio of the plurality of first openings in the first region is between 1.5:1 and 3:1;
Monolithic collimator assembly.
3. The method of claim 1 or 2,
wherein the second region having the plurality of second openings comprises a honeycomb structure having an inverted conical shape from an outward edge of the first region to a peripheral region of the collimator portion;
Monolithic collimator assembly.
3. The method of claim 1 or 2,
a material selected from the group consisting of aluminum, copper and stainless steel;
Monolithic collimator assembly.
3. The method of claim 1 or 2,
wherein the walls have a thickness of 0.06 inches to 0.18 inches;
Monolithic collimator assembly.
6. The method of claim 5,
wherein the walls have a thickness of 0.12 inches to 0.15 inches;
Monolithic collimator assembly.
4. The method of claim 3,
there are non-hexagonal openings around the outer perimeter of the honeycomb structure;
Monolithic collimator assembly.
8. The method of claim 7,
at least six of the non-hexagonal openings have the same width dimension;
Monolithic collimator assembly.
9. The method of claim 8,
wherein the six or more non-hexagonal openings are symmetrically distributed about the outer perimeter of the honeycomb structure.
Monolithic collimator assembly.
According to claim 1,
wherein the upper shield portion is configured to be coupled with an electrical power source;
Monolithic collimator assembly.
According to claim 1,
the collimator portion is electrically coupled to the upper shield portion;
Monolithic collimator assembly.
According to claim 1,
wherein the monolithic collimator assembly is configured to be electrically coupled to a power source;
Monolithic collimator assembly. A collimator assembly comprising:
a collimator portion comprising a body structure having walls separating and defining respective openings of the plurality of first openings and the plurality of second openings;
an upper shield electrically coupled to the collimator portion; and
a plurality of brackets coupled to the body structure and configured to be attached to the upper shield;
The body structure is
a first region having the plurality of first openings in a first aspect ratio defined by a depth and a width; and
a second region disposed radially outwardly of the first region; and
the second region has the plurality of second openings in a second aspect ratio defined by a depth and a width, the first aspect ratio being different from the second aspect ratio;
the upper shield
support flange;
an upper portion extending over the support flange, the upper portion having a first outer diameter and a first inner diameter; and
a lower portion extending below the support flange, the lower portion having a second outer diameter and a second inner diameter, the first outer diameter being greater than the second outer diameter, the first inner diameter and the second inner diameter The diameter is the same, including -;
each of the plurality of brackets extends radially outwardly from the second region toward an orifice disposed in the upper shield;
each of the plurality of brackets comprising an internally threaded tube;
Collimator assembly.
14. The method of claim 13,
wherein a first aspect ratio of the plurality of first openings in the first region is between 1.5:1 and 3:1;
Collimator assembly.
15. The method of claim 13 or 14,
wherein a second region having a plurality of second openings comprises a honeycomb structure having an inverted conical shape from an outward edge of the first region to a peripheral region of the collimator portion;
Collimator assembly.
15. The method of claim 13 or 14,
a material selected from the group consisting of aluminum, copper and stainless steel;
Collimator assembly.
15. The method of claim 13 or 14,
wherein the walls have a thickness of 0.06 inches to 0.18 inches;
Collimator assembly.
16. The method of claim 15,
there are non-hexagonal openings around the outer perimeter of the honeycomb structure;
Collimator assembly.
14. The method of claim 13,
wherein the upper shield is configured to be coupled to an electrical power source;
Collimator assembly.
14. The method of claim 13,
wherein the collimator assembly is configured to be electrically coupled to a power source;
Collimator assembly.

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