Patent Application
20060027248
The present invention relates generally to systems for fabricating semiconductor devices, and is more particularly related to methods and apparatus for cleaning substrates.
Substrates may be cleaned by the use of acoustic waves. Conventional practices for acoustic cleaning include placing a substrate to be cleaned in a cleaning fluid, and using a megasonic transducer to create pressure waves within the cleaning fluid which act to remove contaminants, particulate matter, etc., from the surface of the substrate.
Interference created by intersecting pressure waves may create non-uniform cleaning. For example, constructive interference between intersecting waves (e.g., intersection of two waves simultaneously at their maxima) tends to increase cleaning power at the point of intersection. Destructive interference between intersecting waves (e.g., intersection of two waves simultaneously at their minima) tends to locally decrease cleaning power at the point of intersection. Such interference may form standing waves which do not contribute to substrate cleaning. Methods and apparatus for reducing the occurrence of and/or substantially preventing wave interference in cleaning systems are therefore desirable.
In a first aspect of the invention, a first method of cleaning a substrate is provided that includes the steps of (1) forming a layer of cleaning solution on a major surface of a substrate; and (2) cleaning the major surface of the substrate by directing sonic energy substantially parallel to the major surface of the substrate through the layer of cleaning solution.
In a second aspect of the invention, a second method is provided for cleaning a horizontally oriented substrate using acoustic waves. The second method includes the steps of (1) flowing a layer of cleaning fluid across a major surface of the substrate; (2) providing a sonic transducer adjacent the major surface of the substrate, the sonic transducer having a wave generating surface oriented substantially perpendicular to the major surface of the substrate; (3) establishing fluid communication between the major surface of the substrate and the wave generating surface of the sonic transducer through the flowing layer of cleaning fluid; and (4) energizing the sonic transducer so as to pass energy waves through the flowing layer of cleaning fluid and across at least a portion of the major surface of the substrate.
In a third aspect of the invention, a first apparatus is provided that is adapted to clean a major surface of a substrate. The first apparatus includes (1) a substrate holder adapted to support the substrate; (2) a cleaning solution supply adapted to receive cleaning solution from a source of cleaning solution and to form a layer of cleaning solution on the major surface of the substrate supported by the substrate holder; and (3) a transducer adapted to generate sonic energy, the transducer positioned so as to clean the major surface of the substrate supported by the substrate holder by directing sonic energy substantially parallel to the major surface of the substrate through the layer of cleaning solution.
In a fourth aspect of the invention, a second apparatus is provided for sonic cleaning of a substrate. The second apparatus includes (1) a substrate holder adapted to support and spin a substrate; (2) a sonic transducer adjacent the substrate holder, the sonic transducer comprising a wave generating surface oriented substantially perpendicular to a major surface of the substrate supported by the substrate holder; and (3) a fluid delivery mechanism adapted to form a flowing layer of fluid on the major surface of the substrate supported by the substrate holder and to establish fluid communication between the wave generating surface of the sonic transducer and the major surface of the substrate through the flowing layer of fluid. Numerous other aspects are provided in accordance with these and other aspects of the invention.
Other features and aspects of the present invention will become more fully apparent from the following detailed description, the appended claims and the accompanying drawings.
In accordance with the present invention, megasonic cleaning of a substrate is performed by applying a layer of cleaning fluid to a major surface of the substrate, providing a megasonic transducer oriented substantially perpendicularly to the substrate surface, establishing fluid communication between the major surface of the substrate and the megasonic transducer through the layer of cleaning fluid, and activating the megasonic transducer so as to pass waves of sonic energy through the layer of cleaning fluid and over the substrate surface. By orienting the megasonic transducer perpendicularly relative to the substrate surface, the occurrence of wave interference caused by wave reflection may be substantially reduced and/or eliminated (as described further below).
In one or more embodiments of the invention, reflective surfaces may be provided that receive pressure waves from the transducer and direct the pressure waves so as to reduce an occurrence of wave interference. For example, such reflective surfaces may comprise one or more wave guides positioned adjacent the megasonic transducer. Other reflective surfaces may be positioned outside the substrate's circumference and adapted to reflect the energy waves out of the plane of the substrate so as to reduce an occurrence of interference with subsequent energy waves progressing across the surface of the substrate. An absorber may also be provided to absorb misdirected energy from the megasonic transducer, as further described below.
The substrate cleaning apparatus 101 is adapted to megasonically clean the surface 105 of the substrate S1 by forming a layer 107 of cleaning fluid on the surface 105 and by passing waves of megasonic energy through the fluid layer 107 and over the surface 105 of the substrate S1. The megasonic energy is provided by a transducer 109. The formation of wave interference is discouraged and/or minimized via the orientation of the transducer 109 relative to the surface 105 of the substrate S1, and may be further reduced via the use of reflectors as described further below. In the embodiment of
With reference to
The substrate cleaning apparatus 101 may include one or more reflectors 113 adapted to receive waves of sonic energy generated by the megasonic transducer 109 and passed across the substrate S1, and to reflect the waves of sonic energy away from the surface 105 of the substrate S1. As is illustrated in the top plan view of
In a preferred aspect, the layer of cleaning fluid 107 is formed by continuously flowing cleaning fluid to a central region of the substrate S1 (e.g., via a centrally disposed fluid dispenser 117 as shown in
Either or both of the megasonic transducer 109 and the reflector 113 may be mounted on a support 115 positioned adjacent the substrate holder 103. For example, the support 115 may be an annular support positioned so as to surround the substrate holder 103 and permit the megasonic transducer 109 and the reflector 113 to be disposed beyond, but still adjacent to, the periphery of the substrate S1 so as to encourage fluid communication among the megasonic transducer 109, the reflector 113 and the layer 107 of cleaning fluid formed on the surface 105 of the substrate S1.
The substrate holder 103 may be adapted to keep the substrate S1 motionless during megasonic cleaning. Alternatively, the substrate holder 103 may be adapted to spin the substrate S1. The substrate S1 may be spun at any time before, during, and/or after megasonic cleaning of the substrate S1.
In one embodiment, cleaning fluid such as SC1 (e.g., hydrogen peroxide and ammonium hydroxide) or any other suitable cleaning solution may be dispensed from the first dispenser 117 at a rate of about 200 milliliters/minute to about 1 liter/minute. Such an arrangement, when combined with substrate rotation of about 0-30 RPM, may provide a flowing layer 107 of cleaning fluid approximately 0.5-3 mm in thickness, which may be sufficiently thick to permit effective megasonic cleaning via a progression of megasonic waves across the surface 105 from the megasonic transducer 109 to the reflector 113. Such a layer of cleaning fluid is sufficiently thin to minimize and/or reduce the occurrence of (and/or the degree of) wave interference arising from wave reflection off of the surface of the flowing layer 107 or off of the surface 105 of the substrate S1. Other cleaning fluids, cleaning fluid flow rates, rotation rates, and/or layer thicknesses may be employed.
The substrate cleaning apparatus 101 may further include a second dispenser 119 (positioned near the megasonic transducer 109 in the embodiment of
As shown in
As shown in
The substrate cleaning apparatus 127 may further comprise one or more absorbers 139 disposed between the megasonic transducer 109a and the layer 107a of cleaning fluid formed on the surface 105 of the substrate S1. Such absorbers may be positioned and/or configured so as to reduce and/or eliminate a potential source of wave interference. For example, an absorber may absorb energy that emanates from an end of the megasonic transducer 109a (e.g., from an end 137 positioned near the layer 107a of cleaning fluid formed on the surface 105 of the substrate S1). Absent the absorber, energy emanating from the end 137 of the transducer 109a may travel toward the surface 105 of the substrate S1 and reflect back toward the transducer 109, causing wave interference. The absorbers 139 may comprise plastic (e.g., polyethylene, PTFE, etc.), for example, or another suitable absorbing material.
As shown in
In operation, the substrate holder 103a of the substrate cleaning apparatus is rotated (see
The megasonic transducer 109a is energized, and waves of megasonic energy pass out of the channel 131, and across the surface 105 of the substrate S1 through the layer 107a, for purposes of megasonic cleaning thereof. Cleaning fluid that reaches an edge of the substrate S1 may be permitted to flow downward and away from the surface 105 of the substrate S1. (The substrate cleaning apparatus 127 preferably is configured to be relatively free of surfaces that cause megasonic energy to reflect back onto the surface 105 of the substrate S3 and/or wave interference).
As shown in
The foregoing description discloses only exemplary embodiments of the invention. Modifications of the above disclosed apparatus and methods which fall within the scope of the invention will be readily apparent to those of ordinary skill in the art. For instance, the layers 107, 107a, 107b of cleaning fluid may be stationery layers of cleaning fluid, and/or need not cover the entire surface 105, 105′ of the substrate S1 at any given time. More than one transducer 109, 109a may be employed to increase the amount of the surface 105, 105′ exposed to megasonic energy. Transducers that are not oriented perpendicularly to the surface 105, 105′ of the substrate S1, but that nonetheless emit sonic energy substantially parallel to the surface 105, 105′ of the substrate S1 also may be employed.
Accordingly, while the present invention has been disclosed in connection with exemplary embodiments thereof, it should be understood that other embodiments may fall within the spirit and scope of the invention, as defined by the following claims.
