Abstract: A cathode assembly includes a monolithic target having a first surface and a center region. In addition, a sculpted section is formed in the first surface, and the sculpted section is generally recessed from the first surface and extends around the center in a racetrack configuration. The racetrack has a concentric centerline, and the sculpted section preferably is generally symmetric about the centerline. A magnetic field generator is disposed adjacent to the target and produces a magnetic field having an in-plane component. The magnetic field generator is tuned so that a distribution of the magnitude of the in-plane component in a direction transverse to the centerline at a point along the racetrack is characterized by two peaks that have a generally equal magnitude.

Abstract: The invention relates to a vapor deposition coating apparatus. More particularly it relates to an apparatus in which the ion current density is carefully controlled to improve coating. This control enhances the versatility and enlarges the range of deposition conditions which can be achieved within a single apparatus, so that coatings with very different properties can be deposited in the same equipment. The vapor deposition apparatus includes a vacuum chamber, at least one coating means or ionization source disposed at or about the periphery of a coating zone, one or more internal magnetic means positioned such that the magnetic field lines are generated across the coating zone and means for altering the strength or position of the magnetic field lines to aid confinement.

Abstract: The invention relates to a vapor deposition coating apparatus. More particularly it relates to an apparatus in which the ion current density is carefully controlled to improve coating. This control enhances the versatility and enlarges the range of deposition conditions which can be achieved within a single apparatus, so that coatings with very different properties can be deposited in the same equipment. The vapor deposition apparatus includes a vacuum chamber (1), at least one coating means or ionisation source (3) disposed at or about the periphery of a coating zone (2), one or more internal magnetic means (6) positioned such that the magnetic field lines (7) are generated across the coating zone (2) and means for altering the strength or position of the magnetic field lines to aid confinement.

Abstract: The present invention relates to a system for executing a plasma-based sputtering method, such as for example a PVD (Physical Vapor Deposition) method. In a process chamber (1), a plasma (2) is produced in order to accelerate ionized particles, carried away from a sputter target (21), through the plasma (2) towards a substrate (3), using an electrical field. In the process chamber (1), between the plasma (2) and the substrate (3) a magnetic field component (6) is produced that is situated parallel to a substrate surface (5). Through the magnetic field component (6), the angular distribution of the ionized particles is deflected from its flight path perpendicular to the substrate surface, so that impact angles are produced that have a greater angular scattering.

Abstract: Disclosed is a magnetron sputtering system enabling formation of a film of a ferroelectric substance by suppressing occurrence of a magnetic field due to an eddy current. The magnetron sputtering system includes a flat target; magnetic field applying means (magnets), provided in the vicinity of a back surface of the target, for applying a magnetic field to a front surface of the target; and magnetic field rotating means (motor) for rotating the magnetic field applying means so as to rotate the magnetic field applied to the front surface of the target. The magnetic field rotating means is provided with rotational speed varying means (speed controller) for varying the rotational speed of the magnetic field applied by the magnetic field rotating means.

Abstract: A magnetron sputter reactor and its method of operation which produces a high fraction of sputtered metal ions and in which the metal ions are confined by a positively biased shield and attracted to a negatively biased pedestal electrode supporting the wafer to be sputter coated. The shield may be positively biased to between 10 and 50VDC, preferably between 15 and 40VDC while the negative self-bias on the pedestal is typical tens of volts. A grounded shield is positioned between the target and the biased shield.

Abstract: A sputtering device is provided in which at least one target is sputtered by sputtering discharge to produce a film of target material on at least the first surface of a substrate. The sputtering device has a principal rotating mechanism that rotates the at least one target about an axis of revolution coaxial with the central axis of the substrate. The target is positioned offset from and circumferential to the central axis of the substrate coaxial with the axis of revolution. A magnet mechanism for magnetron discharge of the sputtering discharge forms a magnetic field asymmetrical to a central axis of the target and is rotated by an auxiliary rotating mechanism. The principal rotating mechanism integrates rotation of the targets with the magnet mechanism.

Abstract: A magnetron sputter reactor capable of ionizing 15% or more of the metal atoms sputtered from the target. A small magnetron having closed bands of opposed magnetic polarity is rotated about the center of the target, and a large amount of power is applied to the target. Thereby the effective power density determined by the magnetron area is increased. A DC coil is wrapped around the space between the target and the substrate being sputter coated to generate an axial magnetic field to guide the metal ions towards the substrate. The pedestal electrode supporting the substrate may be negatively biased to accelerate the metal ions to deep within high aspect-ratio holes.

Abstract: The present invention provides a method and apparatus for achieving conformal step coverage of one or more materials on a substrate using sputtered ionized material. In one embodiment, a chamber having one or more current return plates, a support member, an electromagnetic field generator and a support member is provided. The target provides a source of material to be sputtered by a plasma and then ionized by an inductive coil, thereby producing electrons and ions. During processing, a bias is applied to the support member by an RF power source. The return plates are selectively energized to provide a return path for the RF currents, thereby affecting the orientation of an electric field in the chamber.

Abstract: A magnetron especially advantageous for low-pressure plasma sputtering or sustained self-sputtering having reduced area but full target coverage. The magnetron includes an outer pole face surrounding an inner pole face with a gap therebetween. The outer pole of the magnetron of the invention is smaller than that of a circular magnetron similarly extending from the center to the periphery of the target and has a substantially larger total magnetic intensity. Thereby, sputtering at low pressure and high ionization fraction is enabled.

Abstract: A magnetron especially advantageous for low-pressure plasma sputtering or sustained self-sputtering having reduced area but full target coverage. The magnetron includes an outer pole of one magnetic surrounding an inner pole of the other polarity with a gap therebetween. The magnetron is small, primarily located on one side of the central axis, about which it is rotated. The total magnetic flux of the outer pole is at least 1.5 times that of the inner pole. Different shapes include a racetrack, an ellipse, an egg shape, a triangle, and a triangle with an arc conforming to the target periphery. The invention allows increased ionization of the sputtered atoms.

Abstract: A target and magnetron for a plasma sputter reactor. The target has an annular vault facing the wafer to be sputter coated. Various types of magnetic means positioned around the vault create a magnetic field supporting a plasma extending over a large volume of the vault. An integrated copper via filling process includes a first step of highly ionized sputter deposition of copper, a second step of more neutral, lower-energy sputter deposition of copper to complete the seed layer, and electroplating copper into the hole to complete the metallization.

Abstract: A target for a magnetron plasma sputter reactor. The target has an annular vault facing the wafer to be sputter coated and has a width of preferably at least 5 cm and an aspect ratio of at least 1:2, preferably 1:1. Various types of magnetic means positioned around the walls of the vault, some of which may rotate along the vault, create a magnetic field in the vault to support a plasma extending over a large volume of the vault from its top to its bottom. The large plasma volume within the vault increases the probability that the sputtered metal atoms will become ionized and be accelerated towards an electrically biased wafer support electrode.

Abstract: The present invention provides a planar magnetron including a surface for mounting a planar substantially polygonal target (2) having a substantially central target area for sputtering onto a substrate. The magnetron comprises an array of magnets (4) defining a closed loop magnetic field for generating an elongated plasma race-track above the target (2). Means for establishing cyclical, relative, substantially translational movement between the race-track and the target support surface are provided, the substantially translational movement being substantially parallel to this surface and the trace of the substantially translational movement being a two-dimensional figure. The periphery of the race-track lies substantially within said substantially central target area throughout each cycle, the establishing means being adapted to provide a substantially uniform erosion of the target (2) at least within said substantially central target area.

Abstract: A method of depositing a thin film of metal oxide by a magnetron sputtering apparatus with a mobile magnet for creating a magnetic field reciprocating across a film deposition region, is characterized in that the magnet reciprocates no more than twice in depositing a single thin film of metal oxide.

Abstract: A magnetron especially advantageous for low-pressure plasma sputtering or sustained self-sputtering having reduced area but full target coverage. The magnetron includes an outer pole face surrounding an inner pole face with a gap therebetween. The outer pole of the magnetron of the invention is smaller than that of a circular magnetron similarly extending from the center to the periphery of the target. A preferred triangular shape having a small apex angle of 20 to 30° may be formed from outer bar magnets of one magnetic polarity enclosing an inner magnet of the other magnetic polarity. The magnetron allows the generation of plasma waves in the neighborhood of 22 MHz which interact with the 1 to 20 eV electrons of the plasma to thereby increase the plasma density.

Abstract: A cathode assembly includes a monolithic target having a first surface and a center region. In addition, a sculpted section is formed in the first surface, and the sculpted section is generally recessed from the first surface and extends around the center in a racetrack configuration. The racetrack has a concentric centerline, and the sculpted section preferably is generally symmetric about the centerline. A magnetic field generator is disposed adjacent to the target and produces a magnetic field having an in-plane component. The magnetic field generator is tuned so that a distribution of the magnitude of the in-plane component in a direction transverse to the centerline at a point along the racetrack is characterized by two peaks that have a generally equal magnitude.

Abstract: A target of an alloy of metals having different specific weights is used in a method for producing substrates that are coated with a layer comprising the same two metals by magnetron sputtering of the target. When sputtering such a target material, the metals of the alloy will sputter off with different sputtering characteristics with regard to a static angle a at which the sputtered off material leaves the target. For this reason, at the substrate to be sputter-coated, there occurs a demixing effect of these metals which will be deposited with a varying local ratio of the metals, that differs form the ratio of the metals in the alloy of the target. To counter-act this demixing phenomenon, the location of an electron trap formed by the magnetron field of the sputter source at the target with respect to the location of the substrate, is selected.

Abstract: A magnetron especially advantageous for low-pressure plasma sputtering or sustained self-sputtering having reduced area but full target coverage. The magnetron includes an outer pole face surrounding an inner pole face with a gap therebetween. The outer pole of the magnetron of the invention is smaller than that of a circular magnetron similarly extending from the center to the periphery of the target. Different shapes include a racetrack, an ellipse, an egg shape, a triangle, and a triangle with an arc conforming to the target periphery. The invention allows sustained self-sputtering of copper and allows sputtering of aluminum, titanium, and other metal at reduced pressures down to at least 0.1 milliTorr. For some metals, the pedestal bearing the wafer should be RF biased to a limited degree. The invention allows ionization fractions of the metal of 20% and greater with only the use of capacitive power coupling and can produce bottom coverage of greater than 25% in a hole having an aspect ratio of 5.

Abstract: A target and magnetron for a plasma sputter reactor. The target has an annular trough facing the wafer to be sputter coated. Various types of magnetic means positioned around the trough create a magnetic field supporting a plasma extending over a large volume of the trough. For example, the magnetic means may include magnets disposed on one side within a radially inner wall of the trough and on another side outside of a radially outer wall of the trough to create a magnetic field extending across the trough, to thereby support a high-density plasma extending from the top to the bottom of the trough. The large plasma volume increases the probability that the sputtered metal atoms will become ionized. The magnetic means may include a magnetic coil, may include additional magnets in back of the trough top wall to increase sputtering there, and may include confinement magnets near the bottom of the trough sidewalls.

Abstract: A planar-type magnetron sputtering apparatus capable of forming a uniform thin coating on the entire surface of a substrate having a large area is disclosed. This sputtering apparatus has an insulating target seat, a permanent magnet closed circuit unit consisting of at least two permanent magnet closed circuits, and used for applying an electric field to the target, and a closed circuit moving unit used for continuously moving the permanent magnet closed circuit unit in one direction along an elliptical track parallel to the surface of the target. Due to the movement of permanent magnet closed circuits in one direction, the magnetron discharge tracks continuously moves along the target surface in the same direction. This sputtering apparatus thus allows the target to be uniformly etched on its surface. It is thus possible to form a desired uniform thin coating on the entire surface of a substrate having a large area.

Abstract: A method and apparatus for generating a plasma by inductively coupling electromagnetic energy into the plasma. In one embodiment, first and second antenna coils are disposed about the circumference of the plasma containment area. The first and second antenna coils are relatively spaced along the longitudinal axis of the plasma containment area. A current is generated in the first and second antenna coils. A phase shift regulating network establishes a difference between the phase of the current in the first antenna and the phase of the current in the second antenna. The phase difference corresponds to the phase difference required to launch a helicon wave in the plasma. In a second embodiment, a chamber shield is made of a conductive material and is coupled to the RF source such that the shield functions as an RF antenna. The shield may be coupled in series to a coil surrounding the shield to increase the resultant flux density.

Abstract: A sputtering system and magnet array for depositing metal and metal-reactive gas coatings onto a substrate. The magnet array is designed for use in a rotating magnetron. The magnet array includes a plurality of magnets disposed on a plate. The plurality of magnets is arranged such that a closed-loop magnetic path is formed. The shape of the magnetic path is a double-lobe structure that includes first and second lobes that are symmetric to one another about an axis in the plane of the plate that intersects the center of rotation of the plate. The magnets are arranged in several rows. A first row of magnets has a double-lobe structure that corresponds to the first and second lobes of the magnetic path. Second and third rows of magnets are arranged in the shape of rings inside the first and second lobes of the magnetic path magnetic path. The lobe structure of the magnetic path can be circular or elliptical in shape.

Abstract: A target and magnetron for a plasma sputter reactor. The target has an annular trough facing the wafer to be sputter coated. Various types of magnetic means positioned around the trough create a magnetic field supporting a plasma extending over a large volume of the trough. For example, the magnetic means may include magnets disposed on one side within a radially inner wall of the trough and on another side outside of a radially outer wall of the trough to create a magnetic field extending across the trough, to thereby support a high-density plasma extending from the top to the bottom of the trough. The large plasma volume increases the probability that the sputtered metal atoms will become ionized. The magnetic means may include a magnetic coil, may include additional magnets in back of the trough top wall to increase sputtering there, and may include confinement magnets near the bottom of the trough sidewalls.

Abstract: A plasma chamber in a semiconductor fabrication system improves the uniformity of a high density plasma by optimizing a ratio of RF power from a first coil, surrounding and inductively coupled into the high density plasma, to RF power from a second coil, positioned above a central region and inductively coupled into the high density plasma. It has also been found that an increase in RF power supplied to the second coil positioned above the central region relative to RF power suppled to the first coil surrounding the high density plasma tends to increase the relative density of the plasma toward the center of the high density plasma. It is believed that RF power supplied to the second coil positioned above the central region substrate tends to add more electrons into the central region of the high density plasma to compensate for electrons recombining with plasma ions.

Abstract: An apparatus for sputtering material onto a workpiece, composed of: a chamber; a first target disposed in the chamber for sputtering material onto the workpiece; a holder for holding the workpiece in the chamber; a plasma generation area between the target and the holder; a coil for inductively coupling energy into the plasma generation area for generating and sustaining a plasma in the plasma generation area; and a second target disposed in the chamber below the first target and above the coil for sputtering material onto the workpiece.

Abstract: A magnetron for use in a DC magnetron sputtering reactor that can rotate at a smaller diameter during a deposition phase and at a larger diameter during a cleaning phase, whereby sputter material redeposited outside of the deposition sputtering track is removed during the cleaning phase. An embodiment for a two-diameter magnetron includes a swing arm fixed on one end to the magnetron rotation motor shaft and on the other end to a pivot shaft, pivotably coupled to the magnetron. When the magnetron is rotated in different directions, hydrodynamic forces between the magnetron and the chilling water bath cause magnetron to pivot about the pivot shaft. Two mechanical detents fix the limits of the pivoting and hence establish the two diameters of rotation.

Abstract: A method for controlling the operation of a magnetron source for sputtering a surface of a target in a vacuum chamber, the method including the steps of: during a low pressure phase of sputtering, causing a magnetic field generated by a the magnetron source to be confined primarily to an inner region of the surface of the target so as to reduce leakage of electrons away from the target during sputtering; and during a subsequent high pressure phase of sputtering, causing the magnetic field generated by the magnet assembly to extend into the outer region of the surface of the target so as to sputter material from the outer region of the surface of the target. The pressure of the high pressure phase of sputtering is higher than the pressure of the low pressure phase of sputtering.

Abstract: An apparatus and method for compensating the process-related asymmetries produced in physical vapor processing of a surface. The apparatus and method may be used on either a substrate when sputtering material from a source or when using an ionized physical vapor deposition (IPVD) apparatus to either deposit a film onto or remove material from a substrate. A compensating magnet is configured and positioned to produce a compensating magnetic field. The compensating magnetic is positioned to offset the effects of chamber and process-related asymmetries, particularly those that affect the distribution of plasma processing on a substrate where the plasma has been otherwise symmetrically produced. Assymetries about an axis of the substrate, for example, are corrected, in, for example, systems such as sputter coating machines where a rotating magnet cathode or other such technique produces an initially symmetrical plasma.

Abstract: A magnetron sputtering system is provided that uses cooling channels in the magnetron assembly to cool the target. The magnetron sputtering system also generates low pressure region in the magnetron assembly such that the backing plate sees a pressure differential much lower than atmospheric pressure. In one embodiment, the backing plate includes a center post to support the backing plate during operation. The backing plate is reduced in thickness and provides less of a barrier to the generated magnetic field.

Abstract: The present invention generally provides a vacuum processing system with a process chamber and a rotating member, such as a magnetron in a PVD chamber, disposed in a cooling cavity of the process chamber, where the rotating member includes a deflection member for deflecting cooling fluid in the cooling cavity toward interior portions of the rotating member. In one embodiment, a base plate of the rotating member defines an upper surface of the rotating member and a magnet retainer defines a lower surface of the rotating member. Magnets are mounted between the base plate and the magnet retainer. The deflection member is mounted between the magnets and can be coupled to the magnets on one or both ends. One end of the deflection member is disposed toward the outer perimeter of the magnetron and the other end of the deflection member is disposed toward the interior portions of the rotating member.

Abstract: An apparatus is disclosed for the coating of substrates (10) with thin films, having a vacuum chamber (1), a target (6) to be atomized, situated opposite the substrate (10) in the vacuum chamber (1), with magnets (19, 19′, 19″; 20, 20′, 20″) to produce a magnetic tunnel in front of the area of the target (6) to be atomized, an inlet (8) for a process gas into the process space (11), an anode (12), which is electrically insulated with respect to the vacuum chamber (1), and a current-voltage supply to produce a plasma in front of the target (6). The target (6) is shaped as a rotation-symmetrical body, which provides a ring-shaped enclosure around the substrate (10), wherein the magnets (19,19′, . . . ; 20,20′, . . . ) are supported on the side of the hollow cylindrical target (6), facing away from the substrate (10), and can move around the rotational axis (R) of the target (6).

Abstract: A magnetron especially advantageous for low-pressure plasma sputtering or sustained self-sputtering having reduced area but full target coverage. The magnetron includes an outer pole face surrounding an inner pole face with a gap therebetween. The outer pole of the magnetron of the invention is smaller than that of a circular magnetron similarly extending from the center to the periphery of the target. Different shapes include a racetrack, an ellipse, an egg shape, a triangle, and a triangle with an arc conforming to the target periphery. The small shape allows high power densities to be applied to the area of the target actually being sputtered. Preferably, the magnetic flux produced by the outer pole is greater than that produced by the inner pole. The asymmetry provides several advantages in high-density plasma sputtering. The invention allows sustained self-sputtering of copper and allows sputtering of aluminum, titanium, and other metal at reduced pressures down to at least 0.1 milliTorr.

Abstract: A plasma reactor for physical vapor deposition (PVD), also known as sputtering, which is adapted so that the atomic species sputtered from the target can self-sustain the plasma without the need of a working gas such as argon. The method is particularly useful for sputtering copper. According to the invention, a bias ring arranged around the wafer and rising somewhat above it is positively electrically biased to control the plasma potential, and hence to control the energy and directionality of the ions being sputter deposited on the wafer. The bias ring may be a separate biasing element which can be positioned at a selected height above the wafer.