Cleaning and liquid contact with solids – Apparatus – With movable means to cause fluid motion
Reexamination Certificate
2002-06-28
2004-05-04
Kornakov, M. (Department: 1746)
Cleaning and liquid contact with solids
Apparatus
With movable means to cause fluid motion
C134S137000, C134S147000, C134S148000, C134S149000, C134S172000, C134S174000, C134S187000, C134S190000, C134S191000, C134S193000, C134S192000, C134S199000, C134S902000, C366S113000, C366S127000
Reexamination Certificate
active
06729339
ABSTRACT:
BACKGROUND OF THE INVENTION
The present invention relates generally to surface cleaning and, more particularly, to a method and apparatus for megasonic cleaning of a semiconductor substrate following fabrication processes.
Megasonic cleaning is widely used in semiconductor manufacturing operations and can be employed in a batch cleaning process or a single wafer cleaning process. For a batch cleaning process, the vibrations of a megasonic transducer creates sonic pressure waves in the liquid of the cleaning tank which contains a batch of semiconductor substrates. A single wafer megasonic cleaning process often uses a relatively small transducer above a rotating wafer, wherein the transducer is scanned across the wafer using a liquid stream coupling, or in the case of full immersion in a single wafer tank system a larger transducer which can couple to a larger portion of the wafer. In each case, the primary particle removal mechanism from megasonic cleaning is by cavitation and acoustic streaming. Cavitation is the rapid forming and collapsing of microscopic bubbles in a liquid medium under the action of sonic agitation. Upon collapse, the bubbles release energy which assists in particle removal by breakling the various adhesion forces which cause the particles to adhere to the substrate. Sonic agitation involves subjecting the liquid to acoustic energy waves. Under megasonic cleaning, these acoustic waves occur at frequencies between 0.4 and 1.5 Megahertz (MHz), inclusive. Lower frequencies have been used for other cleaning applications in the ultrasonic range, but these applications are used primarly for part cleaning, and not semiconductor substrate cleaning, due to the potential for damage to the substrates at the lower frequencies.
FIG. 1A
is a schematic diagram of a batch megasonic cleaning system. Tank
100
is filled with a cleaning solution. Wafer holder
102
includes a batch of wafers to be cleaned. Transducer
104
creates pressure waves through sonic energy with frequencies near 1 Megahertz. These pressure waves act in concert with the appropriate chemistry to control particle re-adhesion and provide the cleaning action. Because of the long cleaning times and chemical usage required for batch cleaning systems, efforts have been focused on single wafer cleaning systems in order to decrease chemical usage, increase wafer-to-wafer control, and decrease defects in accordance with the International Technology Roadmap for Semiconductors (ITRS) requirements. Batch systems suffer from another disadvantage in that the delivery of megasonic energy to the multiple wafers in the tank is non-uniform and can result in ‘hot spots’ due to constructive interference, or ‘cold spots’ due to destructive interference, each being caused by reflection of the megasonic waves from both the multiple wafers and from the megasonic tank walls. Therefore, a higher megasonic energy as well as multiple transducer arrays must be applied in order to reach all regions of the wafers in wafer holder
102
. Single wafer megasonic which couple to the wafer through a meniscus also suffer from reflected power reducing the cleaning efficiency.
FIG. 1B
is a schematic diagram of a single wafer cleaning tank. Here, tank
106
is filled with a cleaning solution. Wafer
108
is submerged in the cleaning solution of tank
106
. Transducer
110
supplies the energy to clean the wafer. One shortcoming of the single wafer cleaning tank is that particles remain inside the tank requiring that the cleaning fluid be replaced or re-circulated and filtered regularly. Furthermore, removal of the wafer from the tank after megasonic cleaning also runs the risk of particle re-attachment.
FIG. 1C
is a schematic diagram of nozzle-type megasonic cleaning configuration for a single wafer. Nozzle
112
provides fluid stream
114
through which the megasonic energy is coupled. Transducer
116
, which is connected to power supply
118
, provides the megasonic energy through the fluid stream
114
to the substrate as the fluid stream flows through the nozzle. Megasonic energy supplied through fluid stream
114
provides the cleaning mechanism to clean wafer
120
. One shortcoming of the nozzle cleaning configuration includes requiring a high flow rate of fluid stream
114
to cool the transducer
116
. Fluid stream
114
generated through nozzle
112
covers a small area, therefore, a fairly high megasonic energy is needed to clean the wafer in a reasonable time. The high energy required here necessitates cooling of the transducer. Consequently, the high flow rate of fluid stream
114
is due in good part to the cooling requirements, which are driven by the high energy requirements. This makes cleaning using a cleaning chemistry other than deionized water less desirable, due to cost associated with the high flow rates and effluent handling requirements.
In view of the foregoing, there is a need for a method and apparatus to provide a single wafer megasonic cleaning configuration that is capable of cooling the transducer or resonator while limiting the volume of cleaning chemistry consumed.
SUMMARY OF THE INVENTION
Broadly speaking, the present invention fills this need by providing a megasonic cleaner that is configured to provide cooling to the resonator with a fluid stream separate from the cleaning chemistry fluid stream. It should be appreciated that the present invention can be implemented in numerous ways, including as an apparatus, a system, a device, or a method. Several inventive embodiments of the present invention are described below.
In accordance with one aspect of the present invention, a device for cleaning a semiconductor substrate is provided. The device includes a resonator for propagating megasonic energy. The device has a double jacketed housing having an inner jacket and an outer jacket. The double jacketed housing includes an inner jacket region defined within the inner jacket. The inner jacket region at least partially encloses the resonator. The inner jacket region includes a bottom outlet, a cooling fluid inlet and a cooling fluid outlet. The bottom outlet is located so that energy propagated through a cooling fluid in contact with the resonator can pass through the bottom outlet. An outer jacket region defined between the outer jacket and the inner jacket is included. The outer jacket region includes a cleaning agent inlet and a cleaning agent outlet. The cleaning agent outlet is substantially aligned with the bottom outlet. A cylindrical arm having a first end and a second end is included. The first end of the cylindrical arm extends from the cleaning agent outlet, the second end of the cylindrical arm has a nozzle disposed thereon.
In accordance with another aspect of the invention, a system for cleaning a semiconductor substrate is provided. The system includes a substrate support configured to support and rotate a semiconductor substrate about an axis of the semiconductor substrate. A megasonic cleaner configured to move radialy above a top surface of the semiconductor substrate is included. The megasonic cleaner includes a transducer and a resonator affixed to the transducer. The megasonic cleaner has a double jacketed housing having an inner jacket and an outer jacket. The double jacketed housing includes an inner jacket region defined within the inner jacket. The inner jacket region is at least partially enclosed by the resonator. The inner jacket region has a bottom outlet, a cooling fluid inlet and a cooling fluid outlet. The bottom outlet is located so that energy propagated through a cooling fluid in contact with the resonator can pass through the bottom outlet. The double jacketed housing includes an outer jacket region defined between the outer jacket and the inner jacket. The outer jacket region has a cleaning agent inlet and a cleaning agent outlet. The cleaning agent outlet is substantially aligned with the bottom outlet. The megasonic cleaner includes a cylindrical arm having a first end and a second end. The first end of the cylindrical arm is attached to the cleaning outlet and the s
Boyd John M.
deLarios John
Woods Carl
Kornakov M.
Lam Research Corporation
Martine & Penilla LLP
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