Abstract
In a processing reactor having a microwave plasma source, the microwave radiator is mounted on a rotary microwave coupling for continuous rotation.
Claims
1. A reactor for processing a workpiece, comprising: a chamber and a workpiece support in the chamber, the chamber comprising a side wall and a ceiling having a microwave transmissive window; a rotatable microwave radiator overlying the microwave transmissive window and fluidically separated from the chamber by the window, the rotatable microwave radiator comprising a rotatable hollow conductive housing having a top, a side wall, and a bottom floor positioned above the window, a plurality of openings in the bottom floor, and a microwave input port; a rotary waveguide coupling comprising (A) a stationary member comprising a microwave power port and a first hollow microwave waveguide coupled to the microwave power port, and (B) a rotatable member comprising a second hollow microwave waveguide coupled between the first hollow microwave waveguide and the input port of the rotatable microwave radiator; and a rotation actuator coupled to the rotatable member.
2. The reactor of claim 1, comprising a gas distribution plate below the microwave transmissive window.
3. The reactor of claim 1, wherein the rotation actuator comprises a motor and a rotatable drive gear coupled to the motor, and the rotatable member comprises a driven gear fastened to the rotatable member and engaged with the rotatable drive gear.
4. The reactor of claim 1, further comprising a microwave generator and a flexible waveguide conduit connected between the microwave generator and the microwave power port of the stationary member.
5. The reactor of claim 1, wherein the microwave radiator is configured to radiate at frequency not less than 2.45 GHz.
6. The reactor of claim 1, wherein the plurality of openings in the bottom floor of the microwave radiator are arranged in an array having a periodic spacing corresponding to a function of a microwave wavelength.
7. The reactor of claim 6, wherein the periodic spacing of the plurality of openings is such that in operation the microwave radiator generates a radiation pattern with a periodic non-uniformity corresponding to the spacing, which is averaged out on a workpiece on the workpiece support by rotation of the microwave radiator.
8. The reactor of claim 1, further comprising an inductively coupled RF power applicator adjacent the microwave transmissive window to couple RF power through the microwave transmissive window. and an RF power generator coupled to the inductively coupled RF power applicator.
9. The reactor of claim 8, further comprising a controller governing an output power level of the RF power generator.
10. The reactor of claim 8, wherein the inductively coupled RF power applicator comprises a coil antenna.
11. The reactor of claim 10, wherein the window comprises a planar portion and a cylindrical portion extending downwardly from the planar portion.
12. The reactor of claim 11, wherein the coil antenna surrounds the cylindrical portion.
13. The reactor of claim 11, comprising a heat exchanger configured to flow a coolant through a channel in the window having a first portion in the cylindrical portion and a second portion in the planar portion.
14. The reactor of claim 1, comprising a heat exchanger configured to flow a coolant through the rotatable microwave radiator.
15. The reactor of claim 14, comprising a cover extending over the rotatable microwave radiator to form a volume around the rotatable microwave radiator that includes a gap between the bottom floor and the window.
16. The reactor of claim 15, wherein the heat exchanger is coupled between the second hollow microwave waveguide and the volume around the rotatable microwave radiator such that the coolant flows through the plurality of openings.
17. The reactor of claim 1, comprising a heat exchanger configured to flow a coolant through the window.
18. The reactor of claim 17, wherein the microwave transmissive window includes a pair of parallel dielectric windows forming a channel therebetween.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
[0019] So that the manner in which the exemplary embodiments of the present invention are attained can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to the embodiments thereof which are illustrated in the appended drawings. It is to be appreciated that certain well known processes are not discussed herein in order to not obscure the invention.
[0020] FIG. 1 is a cut-away elevational view of a first embodiment.
[0021] FIG. 2 is a partially cut-away perspective view of a microwave antenna in the embodiment of FIG. 1.
[0022] FIG. 2A is a bottom view corresponding to FIG. 2.
[0023] FIG. 3 is a cut-away elevational view of a first modification of the embodiment of FIG. 1.
[0024] FIG. 4 is a cut-away elevational view of a second modification of the embodiment of FIG. 1.
[0025] FIG. 5 is a partially cut-away elevational view of a second embodiment.
[0026] FIG. 6 is partially cut-away top view in accordance with a third embodiment including a temperature controlled microwave window.
[0027] FIG. 7 is partially cut-away elevational view in accordance with a fourth embodiment, including an inductively coupled RF power applicator.
[0028] To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements and features of one embodiment may be beneficially incorporated in other embodiments without further recitation. It is to be noted, however, that the appended drawings illustrate only exemplary embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
DETAILED DESCRIPTION
[0029] The problem of process non-uniformity attributable to the periodic power deposition pattern of the microwave antenna is solved in one embodiment by continuously rotating the microwave antenna relative to the workpiece. The rotation is performed during or contemporaneously with application of microwave power. The rotation may be about an axis of symmetry. This axis of symmetry may be the axis of symmetry of the process chamber, the workpiece and/or the antenna.
[0030] The problem of having to limit microwave power to avoid damaging the microwave window is solved by providing a channel through the window and flowing a coolant through the channel. In one embodiment, the coolant is a liquid that does not absorb microwave power (or absorbs very little). In one embodiment, the microwave window is provided as a pair of window layers separated by the channel.
[0031] An advantage of the microwave plasma source is that it efficiently generates plasma in a wide range of chamber pressures, generally from above atmospheric pressure down to 10.sup.6 Torr or below. This enables its use across a very wide range of processing applications. In contrast, other plasma sources, such as inductively coupled plasma sources or capacitively coupled plasma sources, can only be used in much more narrow ranges of chamber pressures, and are therefore useful in correspondingly limited sets of processing applications.
Rotating Microwave Source:
[0032] Referring now to FIG. 1, a workpiece processing reactor includes a chamber 100 containing a workpiece support 102. The chamber 100 is enclosed by a side wall 104 and a ceiling 106 formed of a microwave transparent material such as a dielectric material. The ceiling 106 may be implemented as a pair of dielectric windows 108 and 110 formed in the shape of parallel plates. A microwave antenna 114 overlies the pair of dielectric windows 108, 110. The microwave antenna 114 is enclosed by a conductive shield 122 consisting of a cylindrical side wall 124 and a disk-shaped cap 126. In one embodiment depicted in FIG. 2, the microwave antenna 114 is disk-shaped.
[0033] As shown in FIG. 1, the microwave antenna 114 is fed by an axial waveguide 116. The axial waveguide 116 is coupled through an overlying rotary microwave coupling 118 to a microwave feed 120. The rotary coupling 118 includes a stationary member 118-1 and a rotatable member 118-2. The stationary member 118-1 is stationary relative to the chamber 100 and is connected to the microwave feed 120. The rotatable member 118-2 is connected to the axial waveguide 116 and has an axis of rotation coinciding with the axis of symmetry 114a of the microwave antenna 114. The rotary microwave coupling 118 permits microwave energy to flow from the stationary member 118-1 to the rotatable member 118-2 with negligible loss or leakage. As one possible example, a slip-ring RF seal (not shown) may be placed at the interface between the stationary and rotatable members 118-1 and 118-2.
[0034] A rotation actuator 140 is stationary relative to the chamber 100 and includes a rotation motor 140-1 and a rotating drive gear 140-2 driven by the rotation motor 140-1. A driven gear 118-3 bonded or fastened to the rotatable member 118-2 is engaged with the drive gear 140-2, so that the motor 140-1 causes rotation of the rotatable member 118-2 about the axis of symmetry 114a. The driven gear 118-3 may be implemented, for example, as a circular array of teeth on the bottom surface of the rotatable member 118-2.
[0035] In the embodiment of FIGS. 1 and 2, the microwave antenna 114 is a hollow conductive waveguide including a disk-shaped floor 130, a disk-shaped ceiling 132 and a cylindrical side wall 134. The floor 130 faces the ceiling 106 and has an array of slots 136, best seen in FIG. 2A, affecting the antenna radiation pattern. The ceiling 132 includes a central opening 132a into which the axial waveguide 116 extends. The spacing between slots may be selected as a function of the wavelength of the microwave power fed to the microwave antenna 114, and the slot pattern and shape may not necessarily conform with the pattern depicted in FIG. 2A.
[0036] In one embodiment depicted in FIGS. 1 and 3, a gas distribution plate (GDP) 144 is disposed beneath the ceiling 106, and has an array of gas injection orifices 145 extending through it to provide a gas flow path to the interior of the chamber 100. A gas supply plenum 146 overlies the GDP 144 and receives process gas from a process gas supply 147. In a further embodiment depicted in FIG. 4, the GDP 144 consists of an upper GDP 144-1 and a lower GDP 144-2 fed with respective process gases by respective upper and lower gas supply plenums 146-1 and 146-2 that receive process gases from respective upper and lower gas supplies 147-1 and 147-2. For example, the upper gas supply 147-1 may furnish a non-reactive or inert gas, while the lower gas supply 147-2 may furnish a reactive process gas (such as a fluorine-containing gas).
[0037] As shown in FIG. 5, a remote microwave generator 150 is coupled to the rotary coupling 118 by the microwave feed 120. In the embodiment of FIG. 5, the microwave feed 120 is in the form of a long flexible waveguide. The microwave feed 120 may be of sufficient length to accommodate a separation between the remote microwave generator 150 and the chamber 100 of several meters or more, for example. Such a separation between the chamber 100 and the microwave generator 150 permits the microwave generator 150 to be of a large size for high power without affecting the size or footprint of the chamber 100. The flexible waveguide 120 may be of a commercially available type formed of corrugated metal which enables it to be bent while maintaining its cross-sectional shape and waveguide characteristics.
Thermally Controlled Window:
[0038] Referring again to FIG. 1, the ceiling 106 may consist of a pair of dielectric windows 108, 110 generally parallel to one another and enclosing a void or channel 112 between them. The channel 112 lies along a radial plane orthogonal to an axis of symmetry 114a of the microwave transmission antenna. A coolant circulation source 160 pumps a heat exchange medium, such as a liquid or gas coolant, through the channel 112 between the dielectric windows 108 and 110. The coolant circulation source may be a heat exchanger for cooling the heat exchange medium. In one embodiment, the heat exchange medium is a liquid that does not absorb microwave energy. Such a fluid is disclosed in U.S. Pat. No. 5,235,251. In this manner, the microwave windows 108 and 110 are cooled so as to withstand very high microwave power levels. This in turn removes a limitation on microwave power, enabling the use of high microwave power levels to provide high processing rates. For example, in the PECVD formation of DLC films, a very high deposition rate may be realized that shortens the process time to a fraction of currently required process times, using microwave power in the kiloWatt range for continuous wave mode or in the megaWatt range for pulsed mode.
[0039] Referring to FIG. 6, in one embodiment a half-circular array of radial inlets 112a to the channel 112 are fed by an inlet plenum 113a. The radial inlets 112a are formed through an inner annular barrier 125a. Further, a half-circular array of outlets 112b from the channel 112 are drained by an outlet plenum 113b. The inlet and outlet plenums 113a, 113b are coupled to an output and a return port, respectively, of the coolant circulation source 160 through respective ports 115a, 115b. The respective ports 115a and 115b are formed in an outer annular barrier 125b.
[0040] As depicted in dashed line in FIG. 7, in one embodiment a cooling source 162 injects a heat exchange medium such as a cooled gas (cooled air or nitrogen, for example) through the axial waveguide 116 into the interior of the microwave antenna 114. This gas exits the microwave antenna 114 through the waveguide slots 136 (FIGS. 2 and 2A) toward the dielectric window 108. For this purpose, the cooling source 162 is coupled to the interior of the axial waveguide 116 through the rotary coupling 118, for example. A gas return conduit 164 may be coupled to a return port of the cooling source 162 through the shield 122 so as to return the gas to the cooling source for cooling and recirculation. The cooling source 162 may include a refrigeration unit to re-cool the gas received from the gas return conduit.
Microwave Source with Controllable Ion Energy for Lattice Defect Repair During Film Deposition:
[0041] During deposition of a film in a PECVD process, the layer being deposited may have some empty atomic lattice sites. As additional layers are deposited, the additional layers cover the empty lattice sites, thus forming voids in the crystalline structure of the deposited material. Such voids are lattice defects and impair the quality of the deposited material. A microwave source such as that employed in the embodiment of FIG. 1 generates a plasma with very low ion energy, so that it does not disturb the lattice structure of the deposited material, including the lattice defects. Such a microwave source may have a frequency of 2.45 GHz, which generates a plasma having a negligible ion energy level. In one embodiment, the problem of lattice defects is solved by supplementing the microwave source with an inductively coupled plasma (ICP) source. Such a combination is depicted in FIG. 7 in which the ICP source is an overhead coil antenna 170. Power is applied from an RF generator 172 through an RF impedance match 174 to the coil antenna 170 during the time that the microwave source generates a plasma perform a PECVD process. The level of RF power from the RF generator 172 is selected to be at a minimum level required to remove (sputter) small amounts of atoms deposited during the PECVD process. The level of RF power from the RF generator 172 may be set slightly above this minimum level. A fraction of such sputtered atoms tend to redeposit in the voids referred to above during the PECVD process. As a result, the formation of lattice defects or voids in the deposited material is prevented. For this purpose, a controller 176 is provided that enables the user (or a process management system) to select an ideal power level of the RF generator 172.
[0042] In the embodiment of FIG. 7, each of dielectric windows 108 and 110 has a recessed annulus at its edge to form an annular pocket 600 into which the coil antenna 170 is received below the plane of the microwave antenna 114. For this purpose, the dielectric window 108 has a disk-shaped major portion 108a, an annular recessed edge portion 108b and an axial cylindrical portion 108c joining the major portion 108a and the recessed edge portion 108b. Similarly, the dielectric window 110 has a disk-shaped major portion 110a, an annular recessed edge portion 110b and an axial cylindrical portion 110c joining the major portion 110a and the recessed edge portion 110b. The annular pocket 600 is defined between the axial cylindrical portion 108c and the side wall 124 of the shield 122. The annular pocket 600 is sufficiently deep to hold the entire coil antenna 170 below the plane of the microwave antenna 114.
[0043] While the foregoing is directed to embodiments of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
