Patent Grant
6897615
The present disclosure relates generally to fabrication of integrated circuits, and more particularly, to plasma mediated processing and apparatuses employed for fabricating the integrated circuit.
In the process of fabricating integrated circuits (IC's) on wafers, the wafers are subjected to many process steps before a finished IC is produced. The wafers are typically processed with a myriad of specialized tools for forming the various features of the IC, with many of the steps repeated several times. Specialized tools utilized in the IC fabrication process include, but are not limited to, photolithography tools, etchers, ashers, photostabilizers, ion implantation equipment and the like. A significant number of these tools expose the wafer or selected portions of the wafer to a plasma.
Typically, the tools that employ a plasma generate the plasma in close proximity to the wafer surface or produce reactants that interact with the wafer, such as for etching of materials, ashing of photoresist, deposition of materials or the like. Plasma tools are also employed for generating light, such as for example, during photostabilization processes, curing processes, charge erasure processes, and the like. Some plasma-mediated processes employ plasma discharges that are either difficult to ignite, or ignite, but do so irreproducibly with variable delays before ignition is achieved. Once ignited, these discharges are typically sustained with lower required voltages or reduced electric fields. Unfortunately, variability in ignition can lead to variability in processing, inefficiencies, and reduced throughput.
In the semiconductor industry, throughput is often a very important issue. With large volumes and low profit margins in the more competitive areas, incremental improvements in throughput can provide the necessary edge to compete successfully. Variability associated with plasma ignition is often a cause for decreased throughput since process times have to be adjusted to account for the variability.
One causal factor for the difficulty in igniting a gas to form a plasma is due to the relatively high pressures of the working gas. Gases generally have a minimum breakdown voltage operating point that corresponds to relatively low pressures, pressures generally less than about 400 torr and more typically about less than 200 torr. As the gas pressure increases, the required voltage, or electric field, needed to break down the gas increases monotonically. This behavior is problematic since some processes benefit from operation at relatively high pressures, even up to atmospheric-type pressure ranges, at which point very high voltages are required to break down the gas.
Another causal factor for difficulty in plasma ignition is the use of electronegative gases or gas mixtures. Electronegative gases are gases that have a high affinity for electron capture, so that it is very difficult for electrons, once generated, to accelerate and create more free electrons from collision to cause the gas to break down. As a result, establishing a well behaved, steady state plasma can be difficult since the electronegative gas atoms or molecules recapture the electrons. Unfortunately, electronegative gases are frequently the gases of choice for plasma mediated processing of semiconductor wafers for the manufacture of IC's.
The specialized tools that utilize plasmas are driven by energy sources such as microwaves, radiofrequency (RF), other high frequency sources, or the like. Ignition efficiency with these energy sources is generally poor. For example, in the case of a microwave driven plasma, microwave power supplied by a magnetron can be reflected back into the magnetrons. The power supplied by a magnetron is coupled to a microwave cavity for generating the plasma. For most plasma processes, the microwave power can range up to 5,000 watts (W) with gas pressures ranging from 0.5 torr to greater than 5 torr. A common microwave operating frequency is 2.45 gigahertz (GHz). Through the center of the microwave cavity is a plasma tube running lengthwise. The tube is open ended so that it has a gas feed port on top and a gas/plasma exhaust opening at the bottom, leading into a wafer-processing chamber. It is through this tube that various processing gases are passed. Typical gases can include oxygen, nitrogen, hydrogen, helium, and mixtures of these, as well as electronegative gases such as CF4, NF3, and CHF3. Water vapor can also be added. The combined flow rates for the process gases can be as high as 5000 standard cubic centimeters per minute (sccm) or higher. After power is supplied to the magnetrons but prior to ignition, there is no plasma load to absorb the power and power is reflected back into the magnetrons. Reflected power results in a reduced efficiency of the tool and also results in potential damage to the magnetron source. Moreover, once ignited, improper tuning of the microwave driven plasma can further exacerbate the problem of reflected power.
Many plasma tools include tuning hardware to optimize ignition of the gas to form the plasma as well as provide optimization of the breakdown voltage during steady state operation. The ability to ignite the gas mixture depends on the multi-dimensional space defined by all of these variables: gas, pressure, flow rate, electric field provided by the microwave power, and tuning of the cavity. The tuning hardware generally includes an adjustable antenna and an adjustable short. The tuning of the microwave cavity is achieved by moving the antenna position into and out of the microwave cavity, and moving the adjustable short (i.e., a conducting end-plate) up and down to define the length of the cavity. Tuning further adds to the delays associated with operating the plasma tool and as a result, affects throughput.
Once ignited, the reflected power depends on the same variables. That is, without the cavity tuned properly for the given load, some portion of the microwave energy generated from the magnetron is reflected from the load and returned to the microwave source. This reflected power occurs because the presence or absence of the plasma changes the load as seen by the microwave circuit, and changes the tuning of the resonant microwave cavity since the material within the microwave cavity (plasma versus no plasma) affects the resonant wavelength for the cavity. As previously discussed, reflected power results in reduced efficiency of the tool and potential damage to the magnetron source.
While the repositioning of the antenna offers the advantages of ignition over a larger operating regime, and improved operation during an “on” phase, there still remains a need for a more robust ignition system and process so that repositioning is not necessary or is minimized. Antenna positioning and adjustment of the short requires time, which impacts throughput. Moreover, the use of the microwave cavity tuning system affects reliability, and adds to the total cost to manufacture the plasma tool as well as operating costs.
A plasma tool includes a plasma generating chamber comprising a plasma tube, wherein the plasma tube comprises an open ended cylindrical body, wherein the body includes a gas inlet at one end an outlet opening at an other end, and at least one conductive fiber secured to the body; and an energy source in operative communication with the plasma tube.
A process for reducing the electric field breakdown point of a gas includes securing a conductive fiber to a surface of a plasma tube, wherein the plasma tube comprises an open ended cylindrical body, wherein the body includes a gas inlet at one end, an outlet at an other end, and at least one conductive fiber in contact with the body; flowing a gas into the gas inlet of the plasma tube; applying an electric field to the gas flowing in the plasma tube to form a plasma; and discharging the plasma from the outlet of the plasma tube.
These and other objects, advantages and features of the invention will become better understood from the detailed description of the invention that is described in conjunction with the accompanying drawings.
A method and apparatus for enhancing the ignition of a gas to form a plasma in a plasma tool includes placing conductive fibers in or near a plasma discharge volume to locally enhance the applied electric field so that plasma can be initiated at higher pressures, at lower electric fields, and/or in otherwise difficult gases to ignite. Advantageously, the process and apparatus reduces the overall process times for igniting the gas and forming a stable plasma discharge. As a result, wafer throughput for plasma-mediated processes is increased, thereby providing a significant commercial advantage.
In a preferred embodiment, at least one conductive fiber is located within or in close proximity to the plasma discharge volume. Preferably, the conductive fiber is disposed in close proximity to a wall of a plasma tube, wherein the plasma discharge volume is first generated. More preferably, the conductive fiber is secured to an interior wall of the plasma tube. The conductive fiber is preferably coated with a protective coating. As will be discussed in further detail below, the plasma tube is generally an open-ended elongated cylindrical body fabricated from quartz, sapphire, alumina-coated quartz or like material. The plasma tube includes a gas feed inlet at one end and plasma exhaust at the other end. The plasma exhaust is generally discharged into a processing chamber. Gases flowing through the tube are excited with an energy source to breakdown the gases and form the plasma discharge volume. An exemplary plasma tool employing a plasma tube is shown in FIG. 2.
The present disclosure is not intended to be limited to any particular plasma tool and is applicable to those plasma-generating tools employing RF, microwave energy or other high frequency energy sources, individually or in combination, to generate the plasma. Suitable plasma tools include downstream ashers, curing plasma tools, photostabilization tools, plasma tools configured for charge erasure and the like, such as for example, the plasma asher commercially available under the trade name FUSION ES3i from the Axcelis Technologies, Inc. in Rockville, Md.
Turning now to
The microwave energy source 14 includes a magnetron 20 that provides microwave power through a directional coupler assembly 22 to an adjustable waveguide assembly 24, which couples the microwave energy into the microwave cavity 16 through which the plasma tube 18 extends. The adjustable waveguide assembly 24 includes the adjustable antenna 30 that moves laterally into and out of the microwave cavity and an adjustable short (not shown) that vertically adjusts the length of the cavity 16. Plasma is excited in the gas flowing through the plasma tube 18 and is discharged into a process chamber (not shown) for treating wafers contained therein. The plasma generated within the plasma tube 18 defines the plasma discharge volume.
While not wanting to be bound by theory, the presence of a conductive fiber within or in close proximity to the plasma discharge volume enhances the local electric field as shown in FIG. 3. The conductive fiber allows charges (i.e., electrons) to accumulate at each end, thus distorting and enhancing the local electric field within the plasma tube 18. The gas flowing through the plasma tube 18 is exposed to the enhanced local electric field, breaks down and becomes conductive. It is believed that because the fiber resistance is high relative to the volume resistance of the steady state plasma, it does not couple significant energy during steady state operation. This reduces the field enhancement at the tips of the fiber during steady state operation, consequently reducing plasma disturbance and overheating of the fiber during operation.
The fiber is fabricated from a conductive material. Preferably, the fiber is fabricated from conductive materials that provide for a relatively high enhancement of the electric field, and is capable of surviving many ignition cycles. Alternatively, the fiber is fabricated from a non-conductive material having conductive domains and/or a conductive coating.
Preferred conductive materials for fabricating the fiber include tantalum, gold, copper, silver, tungsten, molybdenum, aluminum, carbon, graphite, palladium, platinum, ceramics, and composites or compositions comprising at least one of the foregoing materials. Other electrically conductive materials may include conducting polymers, such as polyanaline and polypyrrole, and metal powders entrapped within a thermally and plasma resistant protective coating to produce the conductive fiber. More preferably, the conductive fiber is selected from the group including a platinum fiber, a platinum coated silicon carbide fiber, and a silicon carbide fiber.
The surface resistivity for platinum is about 10−5 ohm·cm and for SiC fibers the surface resistivity generally ranges from about 1 to about 105 ohm·cm. An especially preferred silicon carbon fiber having a surface resistivity of about 1 ohm·cm is commercially available under the trade name Hi-Nicalon™ and is produced by Nippon Carbon Co., Ltd., Tokyo, Japan.
Although the resistivity of a given material is constant, the resistance of a specific volume of the same material is a function of its dimensions and resistivity. In general, the dimensions and resistivity of the fiber are chosen so that the fiber effectively enhances the electrical field yet, is resistive enough so that the fiber does not couple significant energy during steady state operation. The length and shape of the fiber disposed within or in proximity to the plasma discharge are generally unrestricted. The fiber length, depending on the construction, can be between about 50 nanometers to about 10 centimeters depending on the plasma tool and operating conditions. However, for most plasma applications, it is preferred that the length of the fiber is at about 3 millimeters (mm) to about 5 mm. Preferably, the fiber has a substantially circular cross sectional shape. Fibers having substantially non-circular cross sections may be beneficial for particular applications in terms of bonding the fiber to the wall or having a thinner profile for field enhancement. The thickness of each fiber is preferably less than about 100 microns. At thicknesses greater than about 100 microns, it is difficult to protect the fiber from the heat and reactivity of the plasma. Moreover, thicker fibers do not readily conform to the plasma tube surfaces, thus compounding the difficulty in protecting the fiber from the plasma.
There are a number of other variables that may be considered in fabricating or choosing a suitable fiber, well within the skill of those in the art in view of this disclosure. For example, the fiber should possess sufficient mechanical strength and thermal conductivity to prevent degradation or breakage during deposition of the fibers and during operation of the plasma tool, i.e., during ignition, steady state operation of the plasma and shut down. The melting point of the fibers is preferably greater than the temperatures encountered by the fiber during operation of the plasma source.
The orientation, or angle, of the fiber with respect to the applied electric field is preferably aligned to the applied electric field since charge separation and build-up can only occur along the length of the fiber. More preferably, the fiber is substantially parallel to the applied electric field. With a fiber of fixed length oriented at an angle not substantially parallel to the applied electric field, its effective length along the electric field is reduced by cos θ, where θ is the angle of the fiber with respect to the electric field.
In the case of multiple fibers being disposed within or in proximity to the plasma discharge volume, it is contemplated that each one of the fibers may be of the same composition or a different composition depending on the intended use of the plasma tool. Multiple fibers are preferred in those plasma tools including a relatively large plasma tube. At large separations, the fibers can act independently and further amplify the enhancement effect. Sufficient fiber separation for most plasma tools may be maintained by spacing the ends of opposing fibers such that the localized discharges (i.e., electron clouds) created by adjacent fiber tips do not interfere (i.e., shield) each other. This translates into a separation of approximately 3 mm. However, operation at smaller separations is still possible, especially if the number of fibers is large, i.e., greater than about 3.
A sol gel coating process is preferably employed to secure the fiber to the plasma tube. The sol gel coating preferably comprises a dielectric material and serves to protect the fiber from the plasma during operation of the plasma tool. Sol gel coating processes are well known in the art. For example, PCT Publication Nos. WO 98/56213 and WO 00/30142 describe various sol gel processes for coating a microwave lamp screen and interior surfaces of a bulb. In general terms, the sol gel solution is formulated to yield the desired coating after evaporation of an organic solvent and subsequent curing at an elevated temperature. Preferably, the desired sol gel coating is formed from a silicon dioxide precursor. The thickness of the sol-gel coating is preferably greater than about 0.1 micron to about 10 microns or more.
An exemplary process for applying the sol gel coating includes the use of a silicon dioxide precursor such a tetraorthoethylsilicate (TEOS) to prepare a sol gel solution. At least one fiber is placed onto a wall of a plasma tube and the sol gel solution is then coated onto the wall. Preferably, the wall is an interior wall of the plasma tube. The coating is then dried and cured at an elevated temperature. Several layers may be applied in this manner. The drying and curing process secures the fiber to the wall. When secured in this manner, a thin layer of the silicon dioxide coating may be between the fiber and the wall. For heat sinking purposes, the fiber is preferably in thermal contact with the plasma tube wall over substantially the entire length of the fiber. However, for thin layers of sol gel between the fiber and the wall, the fiber is still effectively in thermal contact with the wall. In this manner, the plasma tube wall acts as a heat sink. Several additional sol gel layers may be added to ensure that the fiber is sufficiently coated and protected during operation of the plasma tool.
An exemplary sol gel recipe, expressed in molar ratios, includes about 1 part TEOS, about 1 to about 4 parts ethanol, about 0 to about 5 parts water and about 0.1 to about 0.3 parts hydrochloric acid. More preferably, the sol gel recipe includes about 1 part TEOS, about 1 to about 3 parts ethanol, about 0.5 to about 5 parts water and about 0.1 to about 0.3 parts hydrochloric acid. In a preferred embodiment, the sol gel recipe includes 1 part TEOS, about 3 parts ethanol, about 1 part water and about 0.15 parts hydrochloric acid.
In general, it is believed that the resulting dielectric thickness (e.g., silicon dioxide layers) deposited onto the conductive fiber is at about 0.2 to about 0.5 microns. Several layers may be applied and the resulting thickness may still be less than about 1 to about 2 microns. Preferably, the final thickness of the dielectric coatings is effective to inhibit reaction between the plasma and the fiber during operation and facilitate the desired field enhancement. Depending on the applied starting field strength, between 2 and 4 layers of sol-gel applied coatings are preferred.
As previously described, some plasma tools utilize tuning hardware for optimizing the electric field breakdown for the particular gas mixture at ignition and also separately during steady state operation. The need to tune for a separate optimized “start” condition is eliminated with the use of the conductive fiber in the plasma tube. Reflected power is minimized since the local electric field generated by the conductive fibers lowers the electric field necessary to breakdown the plasma. As a result, a plasma load is available sooner to absorb microwave power and reduce the amount of reflected power. Significant savings in process time and manufacturing costs can be obtained by eliminating the use of the tuning hardware, e.g., adjustable antenna and short positions for a special “start” condition and positioning of the antenna and short hardware. A commercially available plasma ashing tool that employs tuning hardware is the Fusion ES3i Plasma Asher available from Axcelis Technologies, Inc. Using the Fusion ES3i Plasma Asher as an example, it is estimated that it takes about one second for the antenna to be adjusted once the magnetron is engaged, about one second for the antenna to be adjusted to the preprogrammed “on position” once the plasma is ignited and about 1.5 to about 3.5 seconds for antenna movement for optimization, resulting in a cumulative time of about 3.5 to about 5.5 seconds per wafer for the tuning hardware. Consequently, an immediate increase in wafer throughput will result from eliminating the need for a “start” position or a “start” condition.
In another embodiment, a light source is focused onto a region near the location of the fiber.
In addition to improving ignition cycles, the conductive fiber and its use in some plasma applications can be used to reduce run-up time. Once a plasma discharge is initiated (i.e., initial breakdown), there is typically a finite time for the plasma discharge to reach a steady state or equilibrium condition, hereinafter defined as “run-up” time. The use of an enhanced electric field reduces the run-up time.
By elimination of the run-up time, the throughput can be increased as much as about 15% for certain recipes, such as that for poly/oxide etch, metal etch and other recipes that require low power operation.
According to the foregoing, the advantages of the invention include at least the following:
The foregoing descriptions of the preferred embodiments of the invention have been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obvious modifications or variations are possible in light of the above teachings. The embodiments were chosen and described to provide the best illustration of the principles of the invention and its practical applications to thereby enable one of ordinary skill in the art to utilize the invention in various embodiments and with various modifications as are suited to the particular use contemplated. All such modifications and variations are within the scope of the invention as determined by the appended claims when interpreted in accordance with the breadth to which they are fairly, legally and equitably entitled.
The present application is a continuation-in-part application of, and claims priority from, U.S. patent application Ser. No. 09/838,234, entitled “Lamp Utilizing Fiber for Enhanced Starting Field” filed on Apr. 20, 2001,which application claims the benefit of the date of an earlier filed provisional application, having U.S. Provisional Application No. 60/199,810, filed on Apr. 26, 2000, hereby incorporated by reference in their entireties.
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| Number | Date | Country | |
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| Number | Date | Country | |
|---|---|---|---|
| Parent | 09838234 | Apr 2001 | US |
| Child | 10004523 | US |
