Substrate processing system and method

Abstract

A system for processing substrates has a vacuum enclosure and a processing chamber situated to process wafers in a processing zone inside the vacuum enclosure. Two rail assemblies are provided, one on each side of the processing zone. Two chuck arrays ride, each on one of the rail assemblies, such that each is cantilevered on one rail assemblies and support a plurality of chucks. The rail assemblies are coupled to an elevation mechanism that places the rails in upper position for processing and at lower position for returning the chuck assemblies for loading new wafers. A pickup head assembly loads wafers from a conveyor onto the chuck assemblies. The pickup head has plurality of electrostatic chucks that pick up the wafers from the front side of the wafers. Cooling channels in the processing chucks are used to create air cushion to assist in aligning the wafers when delivered by the pickup head.

Description

BACKGROUND

1. Field

This Application relates to systems and methods for substrate processing, such as silicon substrates processing to form semiconductor circuits, solar cells, flat panel displays, etc.

2. Related Art

Substrate processing systems are well known in the art. Examples of substrate processing systems include sputtering and ion implant systems. While in many such systems the substrate is stationary during processing, such stationary systems have difficulties meeting recent demand for high throughput processing. The high throughput processing is especially severe for processing substrates such as, e.g., solar cells. Accordingly, new system architectures are needed to meet this demand.

SUMMARY

The following summary of the invention is included in order to provide a basic understanding of some aspects and features of the invention. This summary is not an extensive overview of the invention and as such it is not intended to particularly identify key or critical elements of the invention or to delineate the scope of the invention. Its sole purpose is to present some concepts of the invention in a simplified form as a prelude to the more detailed description that is presented below.

Disclosed herein is a processing system and method that enables high throughput processing of substrates. One embodiment provides a system wherein substrates continually move in front of the processing systems, e.g., the sputtering target or ion implantation beam. During travel in front of the processing system the substrate is moved at one speed, and during travel to/from load and unload positions the substrates are moved at a second speed, much higher than the first speed. This enables an overall high throughput of the system.

Various disclosed embodiments provide a vacuum processing system for processing substrates, e.g., ion implanting, using two chuck arrays. In the described embodiments each chuck array has two rows of wafers positioned on electrostatic chuck on each array, but other embodiment may use one or more rows. The arrays are mounted on opposite sides of the chamber, so that they can each have water/gas and electrical connections without interfering with the operation of the other array. The use of at least two rows on each array enables continuous processing, i.e., continuous utilization of the processing chamber without idle time. For example, by using two rows for ion implantation, the ion beam can always be kept over one chuck array while the other array is unloaded/loaded and returned to the processing position before the processed array exits the beam.

In the disclosed embodiments, all wafers on the chuck array are loaded at the same time. Wafers come from the load lock in rows, several wafers abreast, e.g., three wafers abreast. When two rows are present on the incoming conveyor, the wafers are lift up to a pick and place mechanism. In one embodiment, the pick and place mechanism uses electrostatic chucks to hold the wafers, but other mechanisms, such as vacuum, may be used. The system may optionally include dynamic wafer locating mechanisms for locating the wafer on the chucks with the correct alignment to assure that the processing is aligned to the wafer. For example, when performing ion implantation, the alignment ensures that the implanted features are perpendicular or parallel with the wafer edges.

In one embodiment, the chuck arrays have manual alignment features that are used during setup to make sure the direction of travel is parallel to the processing chamber, e.g., to implant mask features. In one example, the chuck arrays are first aligned to the implant masks by using a camera at the mask location and features on the arrays. Then each head on the pick and place mechanism is aligned to the mask by transferring an alignment wafer with precision alignment features from the input conveyor to the chuck array. The array then moves under the mask alignment camera and the angular displacement of the alignment wafer is determined. This angular displacement is then used to adjust the pick and place head. The steps are repeated until alignment is satisfactory. These steps create a fixed alignment. They are not dynamically controlled and varied by the system during wafer processing.

The pick and place heads may also have dynamic wafer alignment. For example, pawls may be used to push wafers against alignment pins while the wafer floats on a gas cushion. This gas cushion may be established by flowing gas into the chuck via the wafer cooling channels so that these channels serve a dual purpose. The alignment pins can be mounted on piezo stages for dynamic control of elevation, if needed.

In one specific example, an ion implant system is provided which comprises a vacuum enclosure, an ion implant chamber delivering an ion beam into a processing zone inside the vacuum enclosure. First and second chuck arrays are configured to ride back and forth on first and second rail assemblies, respectively, wherein an elevation mechanism is configured to change the elevation of the rail assemblies between an upper position and a lower position. Each of the first and second chuck arrays have a cantilevered portion upon which plurality of processing chucks are positioned. Each of the first and second chuck assemblies is configured to travel on its respective rail assembly in the forwards direction when the respective rail assembly is in the upper position, and ride on its respective rail assembly in the backwards direction when the respective rail assembly is in the lower position to thereby pass under the other chuck assembly.

In the described ion implant system, a delivery conveyor belt is positioned inside the vacuum enclosure on its entrance side, and a removal conveyor is position inside the vacuum chamber in its exit side. A first pickup mechanism is configured to remove wafers from the delivery conveyor and place the wafers onto the first and second chuck assemblies. A second pickup mechanism is configured to remove wafers from the first and second chuck assemblies and deliver the wafers to the removal conveyor belt. A camera is provided to enable aligning the first pickup mechanism. The camera is configured to take images of the first and second chuck assemblies while positioned in the processing zone. The images are analyzed to determine the alignment of the first pickup mechanism.

The chuck assemblies are configured to travel at one speed while in the processing zone, and at a second speed, faster than the first speed, while traveling in the reverse or backward direction. In this arrangement, when the rail assembly is in the upper position, the chuck assemblies may be traveling in either fast forward or slow forward speed, depending on the location, but always travel in the reverse fast speed when the rail assembly is in the lower position.

Each of the first and second chuck assemblies has a plurality of electrostatic chucks having gas flow channels. The first and second chuck assemblies are configured to deliver gas to the gas flow channels so as to generate gas cushion when wafers are being loaded onto the electrostatic chucks. Each of the first and second chuck assemblies also has plurality of alignment pins. Actuators may be included such that the pins may be actuated to assume an upper position for wafer alignment and thereafter assume a lower position.

Each of the first and second pickup mechanisms comprises a plurality of pickup chucks arranged to mimic the arrangement of the processing chucks on the first and second chuck assemblies. Each of the pickup chucks has associated wafer alignment actuators configured to urge against the wafers during wafer alignment procedure. The wafer alignment actuators may be configured to urge the wafers against alignment pins attached to the chuck assemblies.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of this specification, exemplify the embodiments of the present invention and, together with the description, serve to explain and illustrate principles of the invention. The drawings are intended to illustrate major features of the exemplary embodiments in a diagrammatic manner. The drawings are not intended to depict every feature of actual embodiments nor relative dimensions of the depicted elements, and are not drawn to scale.

FIG. 1 is a cross-sectional schematic illustrating major parts of a system and architecture according to one embodiment.

FIG. 2 is a top view of chuck arrays depicting a process flow to highlight certain features of the embodiment illustrated in FIG. 1.

FIGS. 3A and 3B illustrate an embodiment of the chuck array system.

FIG. 4 illustrates an example of a system used with an ion implanter.

FIG. 5 illustrates a top view of the substrate loading according to one embodiment, which enables accurate alignment of the wafers to the chucks.

FIG. 6 is a schematic view of a pickup chuck according to one embodiment.

FIG. 7A illustrates a pickup chuck with the pawls open, while FIG. 7B illustrates a pickup chuck with the pawls in the close position.

FIG. 8A is a schematic illustrating an arrangement with a pickup chuck having pawls and a processing chuck having alignment pins, while FIG. 8B is a side view of the arrangement of FIG. 8A.

FIG. 9 is a flow chart illustrating a process for transferring a wafer onto the processing chuck.

FIG. 10 is a flow chart illustrating a process for aligning the pickup head to the processing chamber.

DETAILED DESCRIPTION

Various embodiments disclosed herein provide a system architecture that enables high processing throughput, especially for processes such as sputtering and ion implant. The architecture enables pass-by processing, such that the substrate is being processed as it passes by the processing chamber. For example, the substrate can be passed under an ion beam such that it is being implanted as it traverses the ion beam. In some specific examples, the ion beam is made as a wide ribbon, such that it can cover sections of several substrates simultaneously. Using such an arrangement, several substrates can be passed under the beam, such that the substrates can be processed together simultaneously to increase the system's throughput.

An embodiment of the inventive sputtering chamber will now be described with reference to the drawings. FIG. 1 illustrates part of a system for processing substrates using movable chuck arrays, indicated as C1 and C2, and positioned inside vacuum enclosure 100. In FIG. 1, a processing chamber 115 is served by the two movable chuck arrays; such that at all times at least one substrate is processed by the processing chamber. The processing chamber 115 may be, for example, a sputtering chamber, an ion implant chamber, etc., having a processing zone, indicated by arrow 145. The processing zone may be, e.g., an ion beam. By having the movable chuck arrays as illustrated in FIG. 1, the processing zone is always occupied by at least one substrate, so that the chamber is never in an idle mode, but rather is always processing at least one substrate.

In the example of FIG. 1, the substrates 102 arrive on a conveyor 130 which, in this embodiment, is in vacuum. In this example, the substrates are arranged three abreast, i.e., in three rows as shown in the callout L1 of FIG. 1. Also, in this example, each chuck array has six chucks 106, arranged as a 2×3 array, as illustrated in the callout L2 of FIG. 1. A pick-up head arrangement 105 rids on an overhead rail 110 and, in this example, picks up six substrates from the conveyor simultaneously, and transfers them to the chuck array, here C1.

The wafer transport mechanism used to transport the wafers 102 from the conveyor 130 onto the processing chucks 106, employs one or more electrostatic pickup chucks 105, which are movable along tracks 110 and use electrostatic force to pick up one or more wafers, e.g., one row of three wafers 102, and transfer the wafers to the processing chucks 106. The pickup chucks 105 electrostatically chuck the wafers from their front surface, and then position the wafers on the processing chucks 106, which electrostatically chucks the wafers from their backside. Such an arrangement is particularly suitable for processing solar cells, which are rather forgiving for handling from the front surface.

Meanwhile, chuck array C2 continuously passes the processing region 145 of processing chamber 115, such that all six substrates will be exposed for processing. The motion of the chuck arrays while traversing under the processing region 145 is at a constant speed, referred to herein as S1. Once chuck array C1 has been loaded with substrates 102, it moves into processing position behind chuck array C2. This move into the processing position is done at a speed, referred to herein as S2, which is faster than speed S1, so that chuck C1 can be loaded and moved to be in position for processing before processing of the substrates on chuck array C2 is completed. Chuck array C1 then moves behind chuck array C2 at speed S1, so that when chuck array C2 exits the processing zone 145, chuck C1 immediately enters the processing zone 145. This condition is depicted as situation A in FIG. 2, wherein chuck array C2 just completed processing and chuck array C1 enters the processing zone 145. In the position illustrated in FIG. 2, chuck array C1 has just began entering the processing zone 145, for example, just started passing under the implant beam 147. Chuck array C1 will continue to move slowly at speed S1 through the implant zone 147, e.g., at about 35 mm/sec. On the other hand, chuck array C2 is just about to exit the coverage of the implant beam 147.

Once chuck array C2 passes beyond the processing zone, i.e., exits the coverage of ion beam 147, it then accelerates and moves at speed S2 to the unloading position, depicted as situation B in FIG. 2. At this time, the front edge of chuck array C1 starts processing below the processing zone, while continuing to move at speed S1. As shown in this example, chuck array C1 is arranged such that three substrates are processed simultaneously. Of course, more or less substrates can be processed simultaneously, depending on the size of the processing zone 145, in this example, the width of the ion beam 147.

When chuck array C2 stops at the unloading station, shown in broken-line in FIG. 1, an unloading pick-up arrangement 125 picks up the substrates and moves them onto conveyor 135. Chuck array C2 is then lowered and moves at speed S2 below chuck array C1 to the load station, shown as position C in FIG. 2. When chuck array C2 is loaded with substrates, it moves into processing position behind chuck array C1, as shown in position D in FIG. 2. This cycle repeats itself, such that substrates are always present in the processing zone 145.

FIGS. 3A and 3B illustrate an embodiment of the chuck array system. In this embodiment, each of chuck arrays C1 and C2 has six chucks, 352, 357, each of which may be, e.g., an electrostatic chuck. Chuck array C1 rides on tracks 350 on one side, while chuck array C2 rides on tracks 355, situated in a position opposed to the tracks 350. Each of chuck arrays C1 and C2 can ride back and forth on its tracks, as indicated by the double-headed arrow. The chuck arrays C1 and C2 can be moved on tracks using motors, stepping motors, linear motors, etc. Each of the tracks is coupled to an elevation mechanism 360, which assumes an upper position and a lower position. During loading, processing, and unloading the elevation mechanism 360 is activated to have the tracks assume the upper position. FIG. 3A illustrates the condition wherein both tracks are in the upper position, such that all of the chucks are at the same level. However, during transfer from unloading position to loading position, the elevation mechanism 360 is activated to lower the respective track to assume the lower position, so that one chuck array can pass below the other. This is shown in FIG. 3B, wherein tracks 350 assume the lower position and chuck array C1 passes below chuck array C2.

As illustrated in FIGS. 3A and 3B, each chuck array has a cantilevered shelf, 372, 374, upon which the chucks are assembled. Each of the cantilevered shelves has a drive assembly 373, 375, which rides on the rails, and a free standing support assembly 374, 376, upon which the chucks are attached, and which is cantilevered from the respective drive assembly. When one rail assembly assumes the lower position, the free standing support assembly of the respective chuck assembly can pass below the free standing support assembly of the other chuck assembly. Also, as illustrated in FIG. 3, the shelves are cantilevered so that when both rails are in upper position, the chucks situated on both shelves are aligned in the travel direction, as shown by the broken lines.

FIG. 4 illustrates an example of a system used with an ion implanter. The system illustrated in FIG. 4 is used for fabrication of solar cells. In the fabrication of solar cells, sometimes ion implantation is performed on only selected areas of the substrate. An example for such processing is selective emitter solar cell. According to the embodiment of FIG. 4, a mask (see, e.g., mask 170 in FIG. 1) is placed in the path of the ion beam, such that only ions that pass through holes in the mask reach the substrate. FIG. 4 illustrates how the processing using the mask proceeds and the cycle time using one numerical example.

In FIG. 4, the chuck array is shown in solid line and is illustrated to have a length Lc in the direction of travel, while the mask is shown in broken line and is illustrated to have length Lm in the direction of travel. In this arrangement, an array of 3×2 is illustrated. Such that three wafers are positioned in the width direction to be processed simultaneously. This particular mask can be used to provide even doping on the surface of the wafers, and then enhanced doping for the contact “fingers” of the solar cell. That is, as the wafers is being transported under the mask, the wide opening of the mask enables a wide uninterrupted beam of ions to pass and evenly dope the surface of three wafers simultaneously. As the wafers continue to travel and come under the “comb” section of the mask, only “beamlets” of ions are allowed to pass to the wafers to thereby dope the wafers in straight lines.

The doping process continues uninterruptedly, such that the implant source is always operational and always provides an ion beam. FIG. 4 illustrates four snapshots of four states during the continuous operation. In State 1, chuck array C2 is under the ion beam to implant the wafers positioned thereupon. The leading edge of chuck array C1 is just about to enter the area covered by the mask. Both arrays C1 and C2 travel at slow speed S1. At State 2, ion implant of the wafer positioned on chuck array C2 is completed and the trailing edge of chuck array C2 is just about to exit the area covered by the mask. Both arrays C1 and C2 still travel at slow speed S1.

Once array C2 completely exits the coverage area of the mask, during time t₂₃, it accelerates to speed S2 and travels to the unload station, wherein the wafers are unloaded from the array. The tracks of array C2 are then lowered and array C2 travels at speed S2 under array C1 to be loaded with fresh wafers at the loading station. Once loaded, array C2 again accelerates to speed S2 to a position just behind array C1, and then slows down to travel at speed S1 behind array C1. State 3 is a snapshot of array C2 as its leading edge is just about to enter the coverage area of the mask. Process then continues at speed S1, and, as shown in state 4, the trailing edge of chuck array C1 is about to exit the coverage area of the mask, which defines one cycle. The process then repeats itself ad infinitum, so long as wafers are loaded onto the system.

As can be understood from the example of FIG. 4, the cycle time for one chuck array is t₁₂+t₂₃+t₃₄+t₄₁. In one example, this cycle time is about 18 seconds. The processing time is the time from when the leading edge of the chuck array enters the mask coverage, to the time the trailing edge of the array exits the mask coverage. However, the time a chuck array travels at processing speed, i.e., S1, is longer and is shown in FIG. 4 to be t₁₂+t₂₃+t₃₄=18−t₄₁. On the other hand, FIG. 4 illustrates that the time the chuck array travels at speed S2 and is unloaded and loaded with new wafers is t₂₃, which in one example is about 6 seconds.

As can be understood from the above, for proper ion implant at high throughput speeds, the wafers need to be loaded onto the chucks at high alignment accuracy. However, since the wafers arrive on conveyor, it is difficult to maintain accurate alignment. FIG. 5 illustrates a top view of the substrate loading according to one embodiment, which enables accurate alignment of the wafers to the chucks. In this example six substrates are aligned loaded simultaneously onto six chucks.

FIG. 5 is a top view of the pick-up head 105 of FIG. 1, having a 3×2 array of electrostatic chucks 505 for simultaneously loading 6 wafers 502. Each of the chucks 505 is capable of rotational alignment about an axis, as indicated by double-arrow 590. The alignment is performed so that the wafers are aligned to the mask, and is done prior to start of processing. For example, as shown in FIG. 1, a camera 119 can be positioned near the mask 170, so as to image the mask and the chuck array. In FIG. 1, the pickup head can be rotationally aligned about axis 190. For performing the alignment, a special alignment wafer with alignment mask can be used, so its alignment to the mask can be imaged using camera 119. Once the alignment is set for a particular mask, the alignment stays static and need not be changed for each cycle. In practice, this rotational alignment is required only for the loading pick-up head 105, and is not required for the unloading pick-up head 125.

Each individual wafer is aligned to its individual processing chuck by movable pawls 585, which push the wafer against pins 580. The pawls 585 are in the open position when a wafer is picked up by the chuck 505, and then are closed, e.g., by gravity, to press the wafers against the pins 580 for alignment. The pins 580 may be fixed or may be movable by, e.g., piezo, as will be explained below. As will be described with respect to the example of FIG. 8, gas flow may be used to float the wafer as it is being aligned to the chuck.

FIG. 6 is a schematic view of a single pickup chuck of the pickup head, e.g., pickup chucks 505 of pickup head 105, according to one embodiment. As illustrated in FIG. 5, six such pickup chucks 505 can be arranged on one pickup head 105, so as to transport six wafers simultaneously. In the embodiment of FIG. 6, each pickup chuck has individual radial alignment about axis 690. For example, each time a new mask is installed on the ion implant system, each of the pickup chucks can be individually radially aligned so that when they deliver the wafers to the processing chucks, the wafers are aligned to the mask. Once alignment is completed, processing can commence and no further alignment may be required until such time as a new mask is installed.

Each wafer is held by an electrostatic chuck 605, and is aligned to the processing chuck. In one embodiment, the wafer is aligned by having static pins on two sides and movable alignment levers on the two counter-sides. In FIG. 6 static pins 680 are fixed and are arranged such that one pin is centered on one side of the wafer and two pins are provided on the adjacent side of the wafer at 90° angle. As shown in FIG. 5, the two pins are provided on the side that is the leading edge of the wafer, i.e., the side of the wafer that is the leading edge during transport of the wafer. Two movable levers, in FIG. 6 two pawls 685, push the wafer against the static pins so as to align the wafer. The levers may have defined point of contacts, e.g., pins or bumps, such that only the defined point of contact touches and urges the wafer against the static pins. As shown in FIG. 5, some pawls have only a single point of contact, while others may have two or more points of contact. In FIG. 5, the pawls that urge against the leading edge of the wafer have two points of contact 512.

FIGS. 7A and 7B illustrate an example wherein levers 780 from both sides of the wafer urge the wafer to assume an aligned position. In FIG. 7A levers 780 are in the open position, i.e., not urging the wafer 702. The wafer 702 is held by electrostatic chuck 705, which is aligned about axis 790. In FIG. 7B the levers 780 assume the close position and urge the wafer to assume an aligned position.

FIGS. 8A and 8B illustrate another embodiment, wherein the alignment is performed partly by the pickup chuck and partly by the processing chuck. In the embodiment of FIGS. 8A and 8B, the electrostatic chuck 805 is radially aligned about axis 890 and electrostatically holds wafer 802. During the time that the electrostatic chuck 805 holds wafer 802 the pawls 885 are in the open position, such that they do not urge against the wafer 802. When the pickup chuck delivers the wafer to the processing chuck 806, gas is pumped under the wafer via channels 833 in the chuck. This creates an gas cushion upon which the wafer floats. At that time, the levers 855 assume the close position, e.g., by gravity or actuators, to urge the wafer against the fixed pins 880. As, illustrated, in this embodiment the fixed pins 880 are attached to the base 874 of the chuck array, upon which processing chuck 806 is mounted. Once the levers 885 have urged the wafer against the pins 880, air flow can be terminated and the processing chuck energized so as to chuck the wafer in an aligned position. Also, in this embodiment the pins 880 are movable in the z-direction, i.e., elevated for alignment and lowered during transport and processing, as illustrated by the double-headed arrow.

FIG. 9 is a flow chart illustrating a process for transferring a wafer onto the processing chuck using the embodiment shown in FIGS. 8A and 8B. Similar processes can be performed using other disclosed embodiments. In the embodiments described above the transfer is performed from a conveyor belt onto a processing chuck, or vice versa, but a similar process can be performed when transferring from, e.g., a wafer cassette, a wafer tray, robot arm, etc. The process starts at step 900 by placing the pickup head at the pick up position, over the wafer to be picked up. In step 905 the pickup head is activated to pick up the wafer by, e.g., vacuum, electrostatic force, mechanical attachment, etc. In step 910 the pickup head is moved to the drop off position, e.g., over the processing chuck.

Since this process relates to the embodiment of FIGS. 8A and 8B, in step 915 gas flow is activated, so as to flow gas through the processing chuck. This step is optional and is performed only when gas flow channels are included in the processing chuck. Such gas channels are usually included in the chuck for the purpose of flowing cooling gas, such as helium, but the same arrangement can be used for the purpose of creating a gas cushion to float the wafer above the processing chuck. The gas cushion can be maintained by flowing helium, argon, nitrogen, air, etc. Also, if used, at this time the alignment pins can be elevated to their upward alignment position.

The wafer is then released onto the gas cushion at step 920 and, as the pickup head is elevated a bit over the dropped wafer, the alignment mechanism aligns the wafer over the chuck in step 925. The alignment mechanism may be static pins and movable levers or pawls as illustrated in the above embodiments. In step 930 gas flow is reduced until it stops so that the wafer can be gently lowered onto the chuck without going out of alignment, and in step 935 the wafer is chucked onto the processing chuck. This can be done by vacuum, mechanical clamping, electrostatic force, etc. At step 940 the pickup head is moved away and, if used, the alignment pins are lowered.

FIG. 10 is a flow chart illustrating a process for aligning the pickup head to the processing chamber. This is done to align the radial position of the pickup head to the processing chamber, so it is done only if the process generates features on the wafer and wherein the alignment of the features to the wafer's topology is critical. Otherwise, this process need not be performed. Thus, for example, if the processing generates a uniform layer over the entire surface of the wafer, no alignment is needed. However, if the processing generates features, such as, e.g., contact fingers on a solar cell, then the alignment process may be carried out before processing commences. After the alignment is done, processing may commence without the need for further alignment.

In Step 1000 the pickup head is moved into position and loads a wafer. If multiple pickup chucks are used, then multiple wafers can be loaded. Also, in one example, a specially designed alignment wafer(s) can be used. For example, the wafer can have special marks to assist in determining proper alignment. At step 1005 the pickup head is moved to drop the wafer(s) onto the processing chuck(s). Then at step 1010 the chuck array is moved onto wafer processing position and at step 1015 an image of the chucks and/or wafers is taken. For example, if the system is used for ion implantation through a mask, the image may be of the mask, as aligned to the marks on the alignment wafers. At step 1020 the image is inspected and it is determined whether the alignment is proper. If it is not, the process proceeds to step 1025 where the proper alignment is performed to the pickup head. Then the process repeats to confirm the alignment. If at step 1020 it is determined that the alignment is proper, then at step 1030 regular processing can commence.

It should be understood that processes and techniques described herein are not inherently related to any particular apparatus and may be implemented by any suitable combination of components. Further, various types of general purpose devices may be used in accordance with the teachings described herein. The present invention has been described in relation to particular examples, which are intended in all respects to be illustrative rather than restrictive. Those skilled in the art will appreciate that many different combinations will be suitable for practicing the present invention.

Moreover, other implementations of the invention will be apparent to those skilled in the art from consideration of the specification and practice of the invention disclosed herein. Various aspects and/or components of the described embodiments may be used singly or in any combination. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the invention being indicated by the following claims.

Claims

1. A wafer processing system, comprising: a vacuum enclosure having a processing region;a processing chamber attached to the vacuum enclosure and defining a processing zone within the vacuum enclosure;a first rail assembly positioned inside the vacuum enclosure on one side of the processing chamber;a first elevation mechanism coupled to the first rail assembly and configured to raise the first rail assembly to elevated position and lower the first rail assembly to lower position;a second rail assembly positioned inside the vacuum enclosure on opposite side of the first rail assembly;a second elevation mechanism coupled to the second rail assembly and configured to raise the second rail assembly to elevated position and lower the second rail assembly to lower position;a first chuck assembly positioned and configured to ride on the first rail assembly in a forward travel direction while traversing under the processing region when the first rail assembly is in the elevated position to thereby perform pass-by processing; and,a second chuck assembly positioned and configured to ride on the second rail assembly in a forward travel direction while traversing under the processing region when the second rail assembly is in the elevated position to thereby perform pass-by processing.

2. The system of claim 1, further comprising a wafer delivery mechanism positioned inside the vacuum enclosure and a wafer removal mechanism positioned inside the vacuum enclosure.

3. The system of claim 2, further comprising a first pick-and-place assembly configured to transfer wafers from the wafer delivery mechanism to the first and second chuck assemblies, and a second pick-and-place assembly configured to transfer wafers from the first and second chuck assemblies to the wafer removal mechanism.

4. The system of claim 3, wherein the wafer delivery mechanism comprises a first conveyor belt and the wafer removal mechanism comprises a second conveyor belt.

5. The system of claim 4, wherein the pick-and-place assembly comprises a pickup head having a plurality of pickup chucks configured for simultaneously chucking a plurality of wafers.

6. The system of claim 5, wherein each of the chuck assemblies comprises a plurality of electrostatic chucks.

7. The system of claim 6, wherein the pick-and-place assembly further comprises actuators configured to align the wafers to the plurality of chucks.

8. The system of claim 7, wherein each of the chuck assemblies comprises a plurality of alignment pins configured for aligning the wafers by urging the wafers against the alignment pins.

9. The system of claim 1, wherein the first chuck assembly is positioned on a first cantilevered shelf configured to ride on the first rail assembly; and, wherein the second chuck assembly is positioned on a second cantilevered shelf configured to ride on the second rail assembly.

10. The system of claim 1, further comprising a transport mechanism configured to operate such that when the first chuck assembly exits the processing zone, the second chuck assembly immediately enters the processing zone and when the second chuck assembly exits the processing zone, the first chuck assembly immediately enters the processing zone.

11. The system of claim 1, wherein each of the first and second chuck assemblies is further configured to ride on its respective first and second rail assemblies in the backwards direction when the respective first and second rail assembly is in the lower position, to thereby pass under the other one of the first and second chuck assemblies.

12. The system of claim 11, wherein each of the first and second chuck assemblies travels in the backward direction in a speed that is faster than speed of the forward travel direction.

13. The system of claim 1, wherein the processing region comprises an ion implantation beam.

14. The system of claim 13, wherein ion implantation beam is a wide ion beam such that it can cover sections of several substrates simultaneously.

15. The system of claim 1, wherein the processing region comprises a sputtering target.

16. The system of claim 1, wherein when both first and second rail assemblies are in the elevated position, the first and second chuck assemblies are aligned in the travel direction.