PATENT ABSTRACT
A chemical vapor deposition reactor and system has a housing, a substrate transport apparatus and a plurality of fixed processing zones. The processing zones include one or more chemical vapor deposition zones, each having an independent reactant gas supply. Each chemical vapor deposition zone may have a respective showerhead. The substrate transport apparatus moves the substrate along a path from the entrance of the housing to the exit of the housing, passing sequentially through each of the processing zones. A respective isolation zone between neighboring processing zones functions to prevent mixing of gases between the processing zones. The isolation zone has a gas dual flow path directing gas flows in opposing directions. The isolation zone may include a gas inflow isolator coupled via a gas dual flow path to respective exhaust ports of respective process zones. The isolation zone may include a respective isolation curtain having a split gas flow.

PATENT DESCRIPTION
CROSS-REFERENCE TO RELATED APPLICATIONS 
       [0001]    This application is a continuation-in-part of U.S. patent application Ser. No. 12/577,641, filed Oct. 12, 2009, entitled “CONTINUOUS FEED CHEMICAL VAPOR DEPOSITION,” claiming benefit of priority from U.S. Provisional Application. No. 61/104,288, filed Oct. 10, 2008, entitled “An Analysis of MOCVD PLATFORMS,” all of which are incorporated herein by reference in their entireties. Further, this application is a continuation-in-part of U.S. patent application Ser. No. 12/475,169, filed May 29, 2009, entitled “METHODS AND APPARATUS FOR A CHEMICAL VAPOR DEPOSITION REACTOR” and a continuation-in-part of U.S. patent application Ser. No. 12/475,131, filed May 29, 2009, entitled “METHODS AND APPARATUS FOR A CHEMICAL VAPOR DEPOSITION REACTOR”, both of which claim benefit of priority from U.S. Provisional Application. No. 61/057,788, filed on May 30, 2008, entitled “METHOD AND APPARATUS FOR A CHEMICAL VAPOR DEPOSITION REACTOR”, U.S. Provisional Application. No. 61/104,284, filed on Oct. 10, 2008, entitled “METHOD AND APPARATUS FOR A CHEMICAL VAPOR DEPOSITION REACTOR” and U.S. Provisional Application. No. 61/122,591, filed on Dec. 15, 2008, entitled “LEVITATING SUBSTRATE CARRIER”, all of which are incorporated herein by reference in their entireties. 
     
    
     BACKGROUND OF THE INVENTION 
       [0002]    1. Field of the Invention 
         [0003]    Embodiments of the invention generally relate to methods and apparatuses for vapor deposition, and more particularly, to chemical vapor deposition processes and chambers. 
         [0004]    2. Description of the Related Art 
         [0005]    Chemical vapor deposition (“CVD”) is the deposition of a thin film on a substrate, such as a wafer, by the reaction of vapor phase chemicals. Chemical vapor deposition reactors are used to deposit thin films of various compositions on the substrate. CVD is highly utilized in many activities, such as during the fabrication of devices for semiconductor, solar, display, and other electronic applications. 
         [0006]    There are numerous types of CVD reactors for very different applications. For example, CVD reactors include atmospheric pressure reactors, low pressure reactors, low temperature reactors, high temperature reactors, and plasma enhanced reactors. These distinct designs address a variety of challenges that are encountered during a CVD process, such as depletion effects, contamination issues, and reactor maintenance. 
         [0007]    Notwithstanding the many different reactor designs, there is a need for new and improved CVD reactor designs. 
       SUMMARY OF THE INVENTION 
       [0008]    Embodiments of a chemical vapor deposition reactor and system are described. Processing zones, including one or more chemical vapor deposition zone, are sequentially disposed. Neighboring processing zones or neighboring chemical vapor deposition zones are isolated from each other by isolator means. A substrate is moved sequentially through the processing zones in the manner of an assembly line. 
         [0009]    In an embodiment, a chemical vapor deposition reactor system has process zones and a transport apparatus. The process zones are sequence of fixed, reduced pressure process zones. Each pair of adjacent zones is separated by a gas inflow isolator. The gas inflow isolator is coupled via a dual flow path to respective exhaust ports of the respective process zones. At least one of the process zones performs a reactant gas deposition process. The transport apparatus has a plurality of movable substrate carriers holding a respective plurality of substrates. The substrates are to be sequentially processed by moving the carriers with corresponding substrates through the sequence of fixed process zones. 
         [0010]    In an embodiment, a chemical vapor deposition system has a housing and a plurality of fixed processing zones. Inside the housing, there is a substrate transport apparatus. The substrate transport apparatus extends from an entrance of the housing to an exit of the housing. The processing zones are sequentially disposed within the housing and along the transport apparatus. The processing zones include at least one chemical vapor deposition zone. Each such chemical vapor deposition zone has an independent reactant gas supply. At least two of the processing zones or neighboring. The neighboring processing zones are separated by a respective isolation zone. Each isolation zone has a respective dual flow path. The dual flow path directs flows in opposing first and second directions. The first direction is towards the first of the neighboring processing zones. The second direction is towards the second of the neighboring processing zones. 
         [0011]    In an embodiment, a chemical vapor deposition reactor has a housing, a substrate transport apparatus and a plurality of fixed processing zones. Within the housing, the substrate transport apparatus is disposed from the entrance of the housing to the exit of the housing. The fixed processing zones are sequentially disposed within the housing and along the transport apparatus. The processing zones include a first chemical vapor deposition zone. The first chemical vapor deposition zone is arranged to supply a first chemical vapor deposition reactant gas through a first showerhead. The processing zones include a second chemical vapor deposition zone. The second chemical vapor deposition zone is arranged to supply a second chemical vapor deposition reactant gas through a second showerhead. Neighboring sequential processing zones are separated from each other by a respective isolation curtain. The isolation curtain has a split flow. Each flow from the split flow is directed toward the respective neighboring processing zone. Each flow from the split flow is coupled to a respective exhaust port. Substrates are moved through the processing zones, using the transport apparatus. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0012]    So that the manner in which the above recited features of the invention can be understood in detail, a more particular description of the invention, briefly summarized above, may be had by reference to embodiments, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical 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. 
           [0013]      FIG. 1A  depicts a chemical vapor deposition (CVD) reactor according to one embodiment of the invention. 
           [0014]      FIG. 1B  depicts a perspective view of a reactor lid assembly according to one embodiment of the invention. 
           [0015]      FIG. 2  depicts a side perspective view of the CVD reactor according to one embodiment described herein. 
           [0016]      FIG. 3  depicts a reactor lid assembly of the CVD reactor according to one embodiment described herein. 
           [0017]      FIG. 4  depicts a top view of a reactor lid assembly of the CVD reactor according to another embodiment described herein. 
           [0018]      FIG. 5  depicts a wafer carrier track of the CVD reactor according to one embodiment described herein. 
           [0019]      FIG. 6  depicts a front view of the wafer carrier track of the CVD reactor according to one embodiment described herein. 
           [0020]      FIG. 7  depicts a side view of the wafer carrier track of the CVD reactor according to one embodiment described herein. 
           [0021]      FIG. 8  depicts a perspective view of the wafer carrier track of the CVD reactor according to one embodiment described herein. 
           [0022]      FIG. 9  depicts the reactor lid assembly and the wafer carrier track of the CVD reactor according to one embodiment described herein. 
           [0023]      FIG. 10A  depicts a CVD reactor according to one embodiment described herein. 
           [0024]      FIGS. 10B-10C  depict a levitating wafer carrier according to another embodiment described herein. 
           [0025]      FIGS. 10D-10F  depict other levitating wafer carriers according to another embodiment described herein. 
           [0026]      FIG. 11  depicts a first layout of the CVD reactor according to one embodiment described herein. 
           [0027]      FIG. 12  depicts a second layout of the CVD reactor according to one embodiment described herein. 
           [0028]      FIG. 13  depicts a third layout of the CVD reactor according to one embodiment described herein. 
           [0029]      FIG. 14  depicts a fourth layout of the CVD reactor according to one embodiment described herein. 
           [0030]      FIG. 15  depicts a fifth layout of the CVD reactor according to one embodiment described herein. 
           [0031]      FIG. 16  depicts a sixth layout of the CVD reactor according to one embodiment described herein. 
           [0032]      FIG. 17  depicts a seventh layout of the CVD reactor according to one embodiment described herein. 
           [0033]      FIG. 18  depicts flow path configurations of the CVD reactor according to one embodiment described herein. 
           [0034]      FIG. 19  depicts a cooling showerhead according to one embodiment described herein. 
           [0035]      FIG. 20  depicts a CVD system having a plurality of tiled showerheads according to an alternative embodiment described herein. 
           [0036]      FIG. 21  depicts a CVD system having several processing zones according to another alternative embodiment described herein. 
       
    
    
     DETAILED DESCRIPTION 
       [0037]    Embodiments of the invention generally relate to an apparatus and a method of chemical vapor deposition (“CVD”). As set forth herein, embodiments of the invention are described as they relate to an atmospheric pressure CVD reactor and metal-organic precursor gases. It is to be noted, however, that aspects of the invention are not limited to use with an atmospheric pressure CVD reactor or metal-organic precursor gases, but are applicable to other types of reactor systems and precursor gases. To better understand the novelty of the apparatus of the invention and the methods of use thereof, reference is hereafter made to the accompanying drawings. 
         [0038]    According to one embodiment of the invention, an atmospheric pressure CVD reactor is provided. The CVD reactor may be used to provide multiple epitaxial layers on a substrate, such as a wafer, such as a gallium arsenide wafer. These epitaxial layers may include aluminum gallium arsenide, gallium arsenide, and phosphorous gallium arsenide. These epitaxial layers may be grown on the gallium arsenide wafer for later removal so that the wafer may be reused to generate additional materials. In one embodiment, the CVD reactor may be used to provide solar cells. These solar cells may further include single junction, heterojunction, or other configurations. In one embodiment, the CVD reactor may be configured to develop a wafer which produces about 2.5 watts and has the dimension of about 10 cm by about 10 cm. In one embodiment, the CVD reactor may provide a throughput range of about 1 wafer per minute to about 10 wafers per minute. 
         [0039]      FIG. 1A  shows a CVD reactor  10 , according to one embodiment of the invention. The reactor  10  includes a reactor lid assembly  20 , a wafer carrier track  30 , a wafer carrier track support  40 , and a heating lamp assembly  50 . The reactor lid assembly  20  may be formed from molybdenum, molybdenum alloys, stainless steel, and quartz. The reactor lid assembly  20  is disposed on the wafer carrier track  30 . The wafer carrier track  30  may be formed from quartz, molybdenum, silica (such as fused silica), alumina, or other ceramic materials. The wafer carrier track  30  may be seated in a wafer carrier track support  40 . The wafer carrier track support  40  may be formed from quartz or a metal, such as molybdenum, molybdenum alloys, steel, stainless steel, nickel, chromium, iron, or alloys thereof. Finally, a heating lamp assembly  50  (further discussed below with respect to  FIG. 10 ) is disposed below the wafer carrier track support  40 . The overall CVD reactor length may be in a range of about 18 feet to about 25 feet, but may extend beyond this range for different applications. 
         [0040]      FIGS. 1B ,  2 ,  3 , and  4 A provide various views of embodiments of the reactor lid assembly  20 . Referring to  FIG. 2 , the reactor lid assembly  20  forms a rectangular body having sidewalls  25  extending from the bottom surface of the reactor lid assembly  20 , and having a plurality of raised portions  26  centrally located between the sidewalls  25 . The raised portions  26  may extend from the bottom surface of the top plate at different lengths along the reactor lid assembly  20 . The raised portions  26  are disposed between the sidewalls  25  so that clearances are formed between the raised portions  26  and each sidewall  25 . These clearances may be used to help couple the reactor lid assembly  20  to the track  30  (further described below). Both the sidewalls  25  and the raised portions  26  may extend substantially the longitudinal length of the reactor lid assembly  20 . The reactor lid assembly  20  may be formed as a single solid structural component, or it may be constructed from several segments coupled together. The raised portions  26  may vary in length and number, thereby forming zones which may be utilized for different applications in a CVD process. The reactor lid assembly  20  may also include multiple patterns of raised portions  26  along its length, such as to develop numerous layouts or stages in a CVD process. 
         [0041]      FIG. 3  also shows the reactor lid assembly  20 . As stated above, the reactor lid assembly  20  as shown in  FIG. 3  may represent an entire top plate structure or a single segment of a larger constructed top plate structure. Also shown, is a plurality of ports  21  disposed through the top surface of the reactor lid assembly  20  and centrally located along the longitudinal axis of the reactor lid assembly  20 . The ports  21  may vary in size, shape, number, and location along the top surface of the reactor lid assembly  20 . The ports  21  may be used as injection, deposition, and/or exhaust ports for communicating a gas, into the CVD reactor. Generally, each port  21  is disposed between two adjacent raised portions  26  (as show in  FIG. 2 ), thereby forming paths through which injection, deposition, and/or exhaustion of a gas may take place. In one example, a gas may be injected into a port  21  so that the gas first travels along the sides of the adjacent raised portions  26  and then travels along the bottom surfaces of the raised portions  26  and into the flow path of a substrate. As shown in  FIG. 3 , the sidewalls  25  are enclosed at the ends of the reactor lid assembly  20  to encapsulate any fluids that are communicated to the zones and paths created by the ports  21  and the raised portions  26  of the reactor lid assembly  20 . 
         [0042]      FIG. 4  shows a top view of the reactor lid assembly  20 , according to one embodiment, having one or more openings, such as deposition ports  23 , exhaust ports  22 , and injection ports  24  (also shown in  FIG. 1B ) disposed through the body  28 . The openings may be disposed through the body  28  from the upper surface  29  to the lower surface  27 . These ports may be fitted with removable isolator, showerhead, exhaust, or other gas manifold assemblies, which may extend beyond the lower surface  27  of the body  28 , to facilitate distribution of a gas, into and/or out of the CVD reactor, and specifically to uniformly apply the gas to a wafer passing beneath the assemblies. In one embodiment, the ports  22 ,  23 ,  24  may define a circular shape, a square shape, a rectangular shape, or combinations thereof. In one embodiment, the showerhead assemblies may include injection hole diameters within the range of about 0.1 mm to about 5 mm and may include injection hole spacing within the range of about 1 mm to about 30 mm. These dimensions may extend beyond these ranges for different applications. The gas manifold assemblies and the reactor lid assembly  20  may be configured to provide a high reactant utilization, meaning that the gases utilized in the reactor are nearly 100 percent consumed by the reactions during the CVD process. 
         [0043]      FIG. 19  depicts a cooling showerhead  1900  as described in one embodiment herein. The cooling showerhead  1900  may be incorporated into the reactor lid assembly  20  within one or more openings, such as deposition ports  23 . The cooling showerhead  1900  may have a cooling plate  1902  extending across the upper portion of the cooling showerhead  1900  and in thermal communication with at least one gas distribution plate  1904 . Each of the gas distribution plate  1904  contains a plurality of shower holes  1906  for distributing or otherwise flowing gases therethrough. The cooling showerhead  1900 , the cooling plate  1902 , and the distribution plates  1904  may each independently be made from or contain steel, stainless steel, aluminum, other metals. In one example, each of the cooling showerhead  1900 , the cooling plate  1902 , and the distribution plates  1904  each contain 316 stainless steel. The cooling showerhead  1900  may have a thickness from about 20 mm to about 40 mm. 
         [0044]    Heat dissipates through the cooling showerhead  1900  and creates a temperature gradient across the thickness of the cooling showerhead  1900 . The cooling showerhead  1900  may be heated to a temperature within a range from about 20° C. to about 750° C. In one example, the front face  1910  of the cooling showerhead  1900  is heated to a temperature (T 1 ) of about 300° C., while the rear face  1912  is cooled to a temperature (T 2 ) of about 50° C. In another embodiment, the cooling showerhead  1900  may have multiple stackable gas distribution plates  1904 , which may be joined together by a braze layer  1916  in order to form a multi-level hierarchical distribution or separated multi-source distribution. 
         [0045]    A cooling fluid  1920  may be used to circulate within the cooling plate  1902  and transfers heat energy away from the front face of the distribution plate  1904  and to a cooling reservoir (not shown). Water, alcohol solutions, glycol solutions, and/or other fluids may be used to transfer heat away from the front face of the cooling showerhead  1900  and away from the reactor lid assembly  20 . 
         [0046]    The exhaust ports  22  and the injection ports  24  may be used to develop “gas curtains” or “isolation curtains” to help prevent contamination and to help prevent back diffusion of the gases introduced into the CVD reactor  10  between the various zones created in the reactor. These gas curtains or isolation curtains may be introduced at the front end (entrance) and the back end (exit) of the CVD reactor  10 , as well as between the various zones created within the CVD reactor  10 . In one example, nitrogen or argon may be injected into an injection port  24  to purge contaminants, such as oxygen, out of a particular zone, which are then exhausted out of an adjacent exhaust port  22 . By utilizing the gas curtains or isolation curtains with the paths and zones created by the reactor lid assembly  20 , the CVD reactor  10  limits the gas isolation to a two dimension configuration that protects between zones and isolates the reactor from outside contaminants, such as air. 
         [0047]      FIGS. 2 ,  5 ,  6 ,  7 , and  8  provide various views of embodiments of the wafer carrier track  30 . The wafer carrier track  30  may provide a levitation-type system so that a wafer may float across a cushion of a gas, such as nitrogen or argon, supplied from the gas holes  33  of the wafer carrier track  30 . Referring back to  FIG. 2 , the wafer carrier track  30  generally may be a rectangular body having an upper portion  31  and a lower portion  32 . The upper portion  31  includes side surfaces  35  extending from the top surface of the wafer carrier track  30  and disposed along the longitudinal length of the wafer carrier track  30 , thereby forming a “guide path” along which a wafer travels through the CVD reactor. The width of the guide path (e.g., the distance between the inner sides of the side surfaces  35 ) may be in a range of about 110 mm to about 130 mm, the height of the guide path may be in a range of about 30 mm to about 50 mm, and the length of the guide path may be in a range of about 970 mm to about 1,030 mm, however, these dimensions may extend beyond these ranges for different applications. The upper portion  31  may include a recessed bottom surface, and the bottom section may include a recessed top surface, such that when joined together, a gas cavity  36  is formed therebetween. The gas cavity  36  may be used to circulate and distribute gas that is injected into the gas cavity  36  to the guide path of the wafer carrier track  30  to generate the cushion of gas. The number, size, shape, and location of the gas cavity  36  along the wafer carrier track  30  may vary. Both the side surfaces  35  and the gas cavity  36  may extent substantially the longitudinal length of the wafer carrier track  30 . The wafer carrier track  30  may be formed as a single solid structural component, or it may be constructed from several segments coupled together. In one embodiment, the wafer carrier track  30  may be tilted at an angle, such that the entrance is elevated above the exit, so that the wafers may float down the track with the aid of gravity. As discussed above, the side surfaces  35  of the wafer carrier track  30  may be received into the gaps formed between the raised portions  26  and the flange members  25  of the reactor lid assembly  20  to enclose the “guide path” along the wafer carrier track  30  and to further compassing the zones formed with the raised portions  26  along the wafer carrier track  30 . 
         [0048]      FIG. 5  shows an embodiment of the wafer carrier track  30 . As shown, wafer carrier track  30  includes a plurality of gas holes  33  along the guide path of the wafer carrier track  30  and between the side surfaces  35 . The gas holes  33  may be uniformly disposed along the guide path of the wafer carrier track  30  in multiple rows. The diameter of the gas holes  33  may include a range of about 0.2 mm to about 0.10 mm and the pitch of the gas holes  33  may include a range of about 10 mm to about 30 mm, but these dimensions may extend beyond these ranges for different applications. The number, size, shape, and location of the gas holes  33  along the wafer carrier track  30  may vary. In an alternative embodiment, the gas holes  33  may include rows of rectangular slits or slots disposed along the guide path of the wafer carrier track  30 . 
         [0049]    Gas holes  33  are in communication with the gas cavity  36  disposed beneath the guide path of the wafer carrier track  30 . Gas that is supplied to the gas cavity  36  is uniformly released through the gas holes  33  to develop a cushion of gas along the wafer carrier track  30 . A wafer positioned on the guide path of the wafer carrier track  30  may be levitated by the gas supplied from underneath and easily transported along the guide path of the wafer carrier track  30 . The gap between a levitated wafer and the guide path of the wafer carrier track  30  may be greater than about 0.05 mm, but may vary depending on different applications. This levitation-type system reduces any drag effects produced by continuous direct contact with the guide path of the wafer carrier track  30 . In addition, gas ports  34  may be provided along the sides of the side surfaces  35  adjacent the guide path of the wafer carrier track  30 . These gas ports  34  may be used as an exhaust for the gas that is supplied through the gas holes  33 . Alternatively, these gas ports  34  may be used to inject gas laterally into the center of the wafer carrier track  30  to help stabilize and center a wafer that is floating along the guide path of the wafer carrier track  30 . In an alternative embodiment, the guide path of the wafer carrier track  30  may include a tapered profile to help stabilize and center a wafer that is floating along the guide path of the wafer carrier track  30 . 
         [0050]      FIG. 6  shows a front view embodiment of the wafer carrier track  30 . As shown, the wafer carrier track  30  includes the upper portion  31  and the lower portion  32 . The upper portion  31  includes side surfaces  35  that form the “guide path” along the length of the wafer carrier track  30 . The upper portion  31  may further include side surfaces  35  that form recessed portions  39  between the sides of the side surfaces  35 . These recessed portions  39  may be adapted to receive the flange members  25  of the reactor lid assembly  20  (shown in  FIG. 2 ) to couple the reactor lid assembly  20  and the wafer carrier track  30  together and enclose the guide path along the wafer carrier track  30 . Also show in  FIG. 5  are gas holes  33  extending from the guide path of the wafer carrier track  30  to the gas cavity  36 . The lower portion  32  may act as a support for the upper portion  31  and may include a recessed bottom surface. An injection line  38  may be connected to the lower portion  32  so that gas may be injected through the line  38  and into the gas cavity  36 . 
         [0051]      FIG. 7  shows a side view of the wafer carrier track  30  having a single injection line  38  into a gas cavity  36  along the entire wafer carrier track  30  length. Alternatively, the wafer carrier track  30  may include multiple gas cavities  36  and multiple injection lines  38  along its length. Alternatively still, the wafer carrier track  30  may include multiple segments, each segment having a single gas cavity and a single injection line  38 . Alternatively still, the wafer carrier track  30  may include combinations of the above described gas cavity  36  and injection line  38  configurations. 
         [0052]      FIG. 8  shows a cross sectional perspective view embodiment of the wafer carrier track  30  having the upper portion  31  and the lower portion  32 . The upper portion  31  having side surfaces  35 , gas holes  33 , and the gas cavity  36  disposed on the lower portion  32 . In this embodiment, the side surfaces  35  and the lower portion  32  are hollow, which may substantially reduce the weight of the wafer carrier track  30  and may enhance the thermal control of the wafer carrier track  30  relative to the wafers traveling along the wafer carrier track  30 . 
         [0053]      FIG. 9  shows the reactor lid assembly  20  coupled to or with the wafer carrier track  30 . O-rings may be used to seal the reactor lid assembly  20  and wafer carrier track  30  interfaces. As shown, the entrance into the CVD reactor  10  may be sized to receive varying sizes of wafers. In one embodiment, a gap  60 , formed between the raised portions  26  of the reactor lid assembly  20  and the guide path of the wafer carrier track  30 , in which the wafer is received, is dimensioned to help prevent contaminants from entering the CVD reactor  10  at either end, dimensioned to help prevent back diffusion of gases between zones, and dimensioned to help ensure that the gases supplied to the wafer during the CVD process are uniformly distributed across the thickness of the gap and across the wafer. In one embodiment, the gap  60  may be formed between the lower surface of the reactor lid assembly  20  and the guide path of the wafer carrier track  30 , In one embodiment, the gap  60  may be formed between the lower surface of the gas manifold assemblies and the guide path of the wafer carrier track  30 , In one embodiment, the gap  60  may be within the range of about 0.5 mm to about 5 mm in thickness and may vary along the length of the reactor lid assembly  20  and wafer carrier track  30 . In one embodiment, the wafer may have a length within the range of about 50 mm to about 150 mm, a width within the range of about 50 mm to about 150 mm, and a thickness within the range of about 0.5 mm to about 5 mm. In one embodiment, the wafer may include a base layer having individual strips of layers disposed on the base layer. The individual strips are treated in the CVD process. These individual strips may have a length of about 10 cm and a width of about 1 cm (although other sizes may be utilized as well), and may be formed in this manner to facilitate removal of the treated strips from the wafer and to reduce the stresses induced upon the treated strips during the CVD process. The CVD reactor  10  may be adapted to receive wafers having dimensions that extend beyond the above recited ranges for different applications. 
         [0054]    The CVD reactor  10  may be adapted to provide an automatic and continuous feed and exit of wafers into and out of the reactor, such as with a conveyor-type system. A wafer may be fed into the CVD reactor  10  at one end of the reactor, by a conveyor for example, communicated through a CVD process, and removed at the opposite end of the reactor, by a retriever for example, using a manual and/or automated system. The CVD reactor  10  may be adapted to produce wafers within the range of one wafer about every 10 minutes to one wafer about every 10 seconds, and may extend beyond this range for different applications. In one embodiment, the CVD reactor  10  may be adapted to produce 6-10 treated wafers per minute. 
         [0055]    In one embodiment, wafers are continuously fed into a CVD system or reactor, similar to the same as the CVD reactor  10 , and are continuously and horizontally moved through multiple process zones within the CVD system. Multiple layers are grown or formed on each substrate. Each layer may be compositionally the same as the immediate underlayer or may be compositionally different as the immediate underlayer. In some embodiments, a wafer passes through a heat-up zone, a growth zone, and a cool-down zone while passing through the CVD system. In one example, a wafer may pass through the heat-up zone for about 3 minutes, pass through the growth zone for about 14 minutes, and then pass through the cool-down zone for about 3 minutes. The deposition zone may be broken down to sub-zones, separated by distance and isolators, such as optional gas curtains and vacuum isolators. In one example, each wafer passes through 7 different deposition sub-zones which are each isolated from each other. The wafer continuously moves through each sub-zone and spends a predetermined time in each zone, for example, about 2 minutes. Therefore, a single layer may be deposited on the wafer in each deposition sub-zone. 
         [0056]      FIG. 10A  shows an alternative embodiment of a CVD reactor  100 . The CVD reactor  100  includes a reactor body  120 , a wafer carrier track  130 , a wafer carrier  140 , and a heating lamp assembly  150 . The reactor body  120  may form a rectangular body and may be contain molybdenum, quartz, stainless steel, or other similar material. The reactor body  120  may enclose the wafer carrier track  130  and extend substantially the length of the wafer carrier track  130 . The wafer carrier track  130  may also form a rectangular body and may contain quartz or other low thermal conductive material to assist with temperature distribution during the CVD process. The wafer carrier track  130  may be configured to provide a levitation-type system that supplies a cushion of gas to communicate a wafer along the wafer carrier track  130 . As shown, a conduit, such as a gas cavity  137  having a v-shaped roof  135  is centrally located along the longitudinal axis of the guide path of the wafer carrier track  130 . Gas is supplied through gas cavity  137  and is injected through gas holes in the roof  135  to supply the cushion of gas that floats a wafer having a corresponding v-shaped notch (not shown) on its bottom surface along the wafer carrier track  130 . In one embodiment, the reactor body  120  and the wafer carrier track  130  each are a single structural component. In an alternative embodiment, the reactor body  120  includes multiple segments coupled together to form a complete structural component. In an alternative embodiment, the wafer carrier track  130  includes multiple segments coupled together to form a complete structural component. 
         [0057]    Also shown in  FIG. 10A  is a wafer carrier  140  adapted to carry a single wafer (not shown) or strips  160  of a wafer along the wafer carrier track  130 . The wafer carrier  140  may be formed from graphite or other similar material. In one embodiment, the wafer carrier  140  may have a v-shaped notch  136  along its bottom surface to correspond with the v-shaped roof  135  of the wafer carrier track  130 . The v-shaped notch  136  disposed over the v-shaped roof  135  helps guide the wafer carrier  140  along the wafer carrier track  130 . The wafer carrier  140  may be used to carry the wafer strips  160  through the CVD process to help reduce the thermal stresses imparted on the wafer during the process. Gas holes in the roof  135  of the gas cavity  137  may direct a cushion of gas along the bottom of the wafer carrier  140 , which utilizes the corresponding v-shaped feature to help stabilize and center the wafer carrier  140 , and thus the strips  160  of wafer, during the CVD process. As stated above, a wafer may be provided in strips  160  to facilitate removal of the treated strips from the wafer carrier  140  and to reduce the stresses induced upon the strips during the CVD process. 
         [0058]    In another embodiment,  FIGS. 10B-10F  depict a wafer carrier  70  which may be used to carry a wafer through a variety of processing chambers including the CVD reactors as described herein, as well as other processing chambers used for deposition or etching. The wafer carrier  70  has short sides  71 , long sides  73 , an upper surface  72 , and a lower surface  74 . The wafer carrier  70  is illustrated with a rectangular geometry, but may also have a square geometry, a circular geometry, or other geometries. The wafer carrier  70  may contain or be formed from graphite or other materials. The wafer carrier  70  usually travels through the CVD reactor with the short sides  71  facing forward while the long sides  73  face towards the sides of the CVD reactor. 
         [0059]      FIG. 10B  illustrates a top view of the wafer carrier  70  containing 3 indentations  75  on the upper surface  72 . Wafers may be positioned within the indentations  75  while being transferred through the CVD reactor during a process. Although illustrated with 3 indentations  75 , the upper surface  72  may have more or less indentations, including no indentations. For example, the upper surface  72  of the wafer carrier  70  may contain 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 12, or more indentations for containing wafers. In some example, one or multiple wafers may be disposed directly on the upper surface  72  which does not have an indentation. 
         [0060]      FIG. 10C  illustrates a bottom view of the wafer carrier  70  containing the indentation  78  on the lower surface  74 , as described in one embodiment herein. The indentation  78  may be used to help levitate the wafer carrier  70  upon the introduction of a gas cushion under the wafer carrier  70 . A gas flow may be directed at the indentation  78 , which accumulates gas to form the gas cushion. The lower surface  74  of the wafer carrier  70  may have no indentations, or may have one indentation  78  ( FIG. 10C ), two indentations  78  ( FIGS. 10D-10F ), three indentations  78  (not shown) or more. The indentation  78  may have straight or tapered sides. In one example, the indentation  78  has tapered sides such that the sides  76  are steeper or more abrupt than the sides  77  which have more of a gradual change of angle. The sides  77  within the indentation  78  may be tapered to compensate for a thermal gradient across the wafer carrier  70 . In another example, the indentation  78  has straight sides and tapered sides such that the sides  76  are straight and the sides  77  have a taper or the sides  77  are straight and the sides  76  have a taper. Alternatively, the indentation  78  may have all straight sides such that the sides  76  and  77  are straight. 
         [0061]    In another embodiment,  FIGS. 10D-10F  illustrate bottom views of the wafer carrier  70  containing two indentations  78  on the lower surface  74 . The two indentations  78  help levitate the wafer carrier  70  upon the introduction of a gas cushion under the wafer carrier  70 . A gas flow may be directed at the indentations  78 , which accumulates gas to form the gas cushion. The indentations  78  may have straight or tapered sides. In one example, as illustrated in  FIG. 10E , the indentations  78  have all straight sides such that the sides  76  and  77  are straight, e.g., perpendicular to the plane of the lower surface  74 . In another example, as illustrated in  FIG. 10F , the indentations  78  have all tapered sides such that the sides  76  are steeper or more abrupt than the sides  77  which have more of a gradual change of angle. The sides  77  within the indentations  78  may be tapered to compensate for a thermal gradient across the wafer carrier  70 . Alternatively, the indentations  78  may have a combination of straight sides and tapered sides such that the sides  76  are straight and the sides  77  have a taper or the sides  77  are straight and the sides  76  have a taper. 
         [0062]    The wafer carrier  70  contains a heat flux which extends from the lower surface  74  to the upper surface  72  and to any wafers disposed thereon. The heat flux may be controlled by both the internal pressure and length of the processing system. The profile of wafer carrier  70  may be tapered to compensate the heat loses from other sources. During a process, heat is lost through the edges of the wafer carrier  70 , such as the short sides  71  and the long sides  73 . However, the heat lost may be compensated by allowing more heat flux into the edges of the wafer carrier  70  by reducing the gap of the guide path in the levitation. 
         [0063]      FIG. 10A  also depicts the reactor body  120  disposed on the heating lamp assembly  150 . The heating lamp assembly  150  may be configured to control the temperature profile within the CVD reactor by increasing and decreasing the temperature of the reactor body  120 , the wafer carrier track  130 , and specifically the wafer, along the length of the CVD reactor. The heating lamp assembly  150  may include a plurality of heating lamps disposed along the longitudinal length of the wafer carrier track  130 . In one embodiment, the heating lamp assembly  150  includes individually controlled heating lamps disposed along the length of the wafer carrier track  130 . In an alternative embodiment, the heating lamp assembly  150  includes a bank of heating lamps that are movable and follow a wafer as it travels along the wafer carrier track  130 . The embodiments of the heating lamp assembly  150  may also be used as the heating lamp assembly  50 , described above with respect to  FIG. 1 . 
         [0064]    In an alternative embodiment, other types of heating assemblies (not shown) may be utilized to heat the reactor body  120  instead of the heating lamp assembly  150 . In one embodiment, a heating assembly may include resistive heating elements, such as resistive heaters, which may be individually controlled along the length of the wafer carrier track  130 . In one example, a resistive heating element may be bonded to or painted onto the reactor body  120 , the wafer carrier track  130 , or the wafer carrier  140 . In alternative embodiment, another type of heating assembly that may be utilized to heat the reactor body  120  is an inductive heating element, such as with a radio frequency power source (not shown). The inductive heating element may be coupled to or with the reactor body  120 , the wafer carrier track  130 , and/or the wafer carrier  140 . Embodiments of the various types of heating assemblies (including heating lamp assemblies  50  and  150 ) described herein may be utilized independently or in combination with the CVD reactor. 
         [0065]    In one embodiment, the heating lamp assembly  150  may be configured to heat a wafer in the CVD reactor to a temperature within a range from about 300° C. to about 800° C. In one embodiment, the heating lamp assembly  150  may be configured to raise the temperature of the wafer to an appropriate process temperature prior to introduction into a deposition zone of the CVD reactor. In one embodiment, the heating lamp assembly  150  may be configured with the CVD reactor to bring the wafer to a temperature within a range from about 300° C. to about 800° C. prior to introduction into a deposition zone of the CVD reactor. In one embodiment, the wafer may be heated to within a process temperature range prior to entering one or more deposition zones of the CVD reactor to facilitate the deposition processes, and the temperature of the wafer may be maintained within the process temperature range as the wafer passes through the one or more deposition zones. The wafer may be heated to and maintained within the process temperature range as it moves along the wafer carrier track. A center temperature to an edge temperature of the wafer may be within 10° C. of each other. 
         [0066]    In one embodiment, a method for forming a multi-layered material during a continuous chemical vapor deposition (CVD) process is provided. In many embodiments, the wafers horizontally advance or move in the same direction and at the same relative rate through multiple deposition zones within the deposition system. Multiple layers of materials are deposited on each wafer, such that one layer is deposited at each deposition zone. The multiple deposited layers on each wafer may all have the same composition, but usually, each layer differs by composition. Embodiments described herein may be utilized for a variety of CVD and/or epitaxial deposition processes to deposit, grow, or otherwise form an assortment of materials on wafers or substrates, especially for forming Group III/V materials on gallium arsenide wafers. 
         [0067]    In some embodiments, a method for forming a multi-layered material during a continuous CVD process is provided which includes continuously moving or advancing a plurality of wafers through a deposition system, wherein the deposition system contains a first deposition zone, a second deposition zone, a third deposition zone, and a fourth deposition zone. In some configurations, the system may have a fifth deposition zone, a sixth deposition zone, additional deposition zones, a heat-up zone, a cool-down zone, as well as other processing zones. The method further provides depositing a first material layer on a first wafer within the first deposition zone, moving or advancing the first wafer to the second deposition zone and moving or advancing a second wafer into the first deposition zone, and then depositing a second material layer on the first wafer within the second deposition zone, while depositing the first material layer on a second wafer within the first deposition zone. The second material layer is deposited on or over the first material layer for each wafer. 
         [0068]    The method further provides moving or advancing the first wafer to the third deposition zone, moving or advancing the second wafer into the second deposition zone, and moving or advancing a third wafer into the first deposition zone, and then depositing a third material layer on the first wafer within the third deposition zone, while depositing the second material layer on the second wafer within the second deposition zone, and while depositing the first material layer on a third wafer within the first deposition zone. 
         [0069]    The method further provides moving or advancing the first wafer to the fourth deposition zone, moving or advancing the second wafer to the third deposition zone, moving or advancing the third wafer into the second deposition zone, and moving or advancing a fourth wafer into the first deposition zone, and then depositing a fourth material layer on the first wafer within the fourth deposition zone, while depositing the third material layer on the second wafer within the third deposition zone, while depositing the second material layer on the third wafer within the second deposition zone, and while depositing the first material layer on a fourth wafer within the first deposition zone. 
         [0070]    In some embodiments, the method further provides depositing a fifth material layer on the first wafer within a fifth deposition zone, while depositing the fourth material layer on the second wafer within the fourth deposition zone, while depositing the third material layer on the third wafer within the third deposition zone, while depositing the second material layer on the fourth wafer within the second deposition zone, and while depositing the first material layer on a fifth wafer within the first deposition zone. Examples are provided wherein the wafers or substrate generally advance or move horizontally in a forward direction, in the same direction, and at the same relative rate while advancing through the multiple deposition zones within the deposition system. 
         [0071]    In some examples provide that the first material layer, the second material layer, the third material layer, and the fourth material layer have the same composition. In other examples, each of the first material layer, the second material layer, the third material layer, and the fourth material layer has a different composition. In many examples, each of the first material layer, the second material layer, the third material layer, and the fourth material layer contains arsenic, such as gallium arsenic, aluminum arsenic, aluminum gallium arsenic, alloys thereof, derivatives, or other materials. 
         [0072]    The method further provides heating each of the wafers to a predetermined temperature within a heat-up zone prior to advancing into the first deposition zone. The predetermined temperature may be within a range from about 30° C. to about 850° C., preferably, from about 50° C. to about 750° C., and more preferably, from about 100° C. to about 350° C. In some embodiments, each of the wafers may be heated to the predetermined temperature for a duration within a range from about 2 minutes to about 6 minutes or from about 3 minutes to about 5 minutes. In other embodiments, each of the wafers may be heated to the predetermined temperature for a duration within a range from about 0.5 minutes to about 2 minutes or from about 1 minute to about 5 minutes or from about 5 minutes to about 15 minutes. The method also provides transferring each of the wafers into a cool-down zone subsequent to depositing the fourth material layer. Thereafter, the wafers may be cooled to a predetermined temperature while in the cool-down zone. The predetermined temperature may be within a range from about 18° C. to about 30° C. In some embodiments, each of the wafers may be cooled to the predetermined temperature for a duration within a range from about 2 minutes to about 6 minutes or from about 3 minutes to about 5 minutes. In other embodiments, each of the wafers may be cooled to the predetermined temperature for a duration within a range from about 0.5 minutes to about 2 minutes or from about 1 minute to about 5 minutes or from about 5 minutes to about 15 minutes. 
         [0073]    In other embodiments, the wafers pass through a heat-up zone prior to entering the first deposition zone and the wafers pass through a cool-down zone subsequent to exiting the fourth deposition zone. The heat-up zone, the first deposition zone, the second deposition zone, the third deposition zone, and the fourth deposition zone, and the cool-down zone may all share a common linear path. The wafers may continuously and horizontally advance along the common linear path within the deposition system. 
         [0074]    In one embodiment, a method for forming a multi-layered material during a continuous CVD process is provided which includes continuously advancing a plurality of wafers through a deposition system, wherein the deposition system has a first deposition zone, a second deposition zone, a third deposition zone, and a fourth deposition zone. The method further provides depositing a buffer layer on a first wafer within the first deposition zone, depositing a sacrificial layer on the first wafer within the second deposition zone, while depositing the buffer layer on a second wafer within the first deposition zone. The method further provides depositing a passivation layer on the first wafer within the third deposition zone, while depositing the sacrificial layer on the second wafer within the second deposition zone, and while depositing the buffer layer on a third wafer within the first deposition zone. The method further provides depositing a gallium arsenide active layer on the first wafer within the fourth deposition zone, while depositing the passivation layer on the second wafer within the third deposition zone, while depositing the sacrificial layer on the third wafer within the second deposition zone, and while depositing the buffer layer on a fourth wafer within the first deposition zone. In many examples, the wafers are gallium arsenide wafers. 
         [0075]    In some embodiments, the method further provides depositing a gallium-containing layer on the first wafer within a fifth deposition zone, while depositing the gallium arsenide active layer on the second wafer within the fourth deposition zone, while depositing the passivation layer on the third wafer within the third deposition zone, while depositing the sacrificial layer on the fourth wafer within the second deposition zone, and while depositing the buffer layer on a fifth wafer within the first deposition zone. In some examples, the gallium-containing layer contains a phosphorous gallium arsenide. 
         [0076]    In some embodiments, the method further provides heating each of the wafers to a predetermined temperature within a heat-up zone prior to the wafer advancing into the first deposition zone. The predetermined temperature may be within a range from about 30° C. to about 850° C., preferably, from about 50° C. to about 750° C., and more preferably, from about 100° C. to about 350° C. In other embodiments, the method further provides transferring each of the wafers into a cool-down zone subsequent to depositing the gallium arsenide active layer. Thereafter, each wafer is cooled to a predetermined temperature within a range from about 18° C. to about 30° C. while in the cool-down zone. 
         [0077]    In other embodiments, the wafers pass through a heat-up zone prior to entering the first deposition zone and the wafers pass through a cool-down zone subsequent to exiting the fourth deposition zone. The heat-up zone, the first deposition zone, the second deposition zone, the third deposition zone, the fourth deposition zone, and the cool-down zone share a common linear path. Optionally, additional deposition zones, such as a fifth, sixth, seventh, or more, may also share the common linear path. The method provides the wafers continuously and horizontally advance along the common linear path within the deposition system. 
         [0078]    In other embodiments, the method further provides flowing at least one gas between each of the deposition zones to form gas curtains therebetween. In some embodiments, the gas curtains or isolation curtains contain or are formed from at least one gas, such as hydrogen, arsine, a mixture of hydrogen and arsine, nitrogen, argon, or combinations thereof. In many examples, a mixture of hydrogen and arsine is utilized to form the gas curtains or isolation curtains. 
         [0079]    In another embodiment, a method for forming a multi-layered material during a continuous CVD process is provided which includes continuously advancing a plurality of wafers through a deposition system, wherein the deposition system has a heat-up zone, a first deposition zone, a second deposition zone, a third deposition zone, a fourth deposition zone, and a cool-down zone. The method further provides depositing a gallium arsenide buffer layer on a first wafer within the first deposition zone, then depositing an aluminum arsenide sacrificial layer on the first wafer within the second deposition zone, while depositing the gallium arsenide buffer layer on a second wafer within the first deposition zone. The method further provides depositing an aluminum gallium arsenide passivation layer on the first wafer within the third deposition zone, while depositing the aluminum arsenide sacrificial layer on the second wafer within the second deposition zone, and while depositing the gallium arsenide buffer layer on a third wafer within the first deposition zone. The method further provides depositing a gallium arsenide active layer on the first wafer within the fourth deposition zone, while depositing the aluminum gallium arsenide passivation layer on the second wafer within the third deposition zone, while depositing the aluminum arsenide sacrificial layer on the third wafer within the second deposition zone, and while depositing the gallium arsenide buffer layer on a fourth wafer within the first deposition zone. 
         [0080]      FIGS. 11-17  illustrate various configurations of CVD processes that can be utilized with the CVD reactor as described herein.  FIG. 11  illustrates a first configuration  200 , having an entrance isolator assembly  220 , a first isolator assembly  230 , a second isolator assembly  240 , a third isolator assembly  250 , and an exit isolator assembly  260 . A plurality of deposition zones  290  may be located along the wafer carrier track of the CVD reactor and may be surrounded by the isolator assemblies. Between each of these isolator assemblies, one or more exhausts  225  may be provided to remove any gases that are supplied to the wafer at each isolator assembly or deposition zone. As shown, a precursor gas may be injected at the entrance isolator assembly  220 , which follows a two dimensional flow path, e.g., down to the wafer and then along the length of the wafer carrier track, indicated by flow path  210  for example. The gas is then exhausted up through exhaust  225 , which may be provided on each side of the isolator assembly  220 . The gas may be directed at the entrance isolator assembly  220  and then along the length of the wafer carrier track, indicated by flow path  215  for example, to prevent contaminants from entering the entrance of the CVD reactor. Gas injected at the intermediate isolator assemblies, such as isolator assembly  230 , or at the deposition zones  290 , may travel upstream from the flow of the wafer, indicated by flow path  219  for example. This back diffusion of gas may be received through the adjacent exhaust to prevent contaminants or mixing of gases between zones along the wafer carrier track of the CVD reactor. In addition, the flow rate of the gases injected through the isolator assemblies, e.g., along flow path  210 , in the direction of the wafer flow may also be adapted to further prevent back diffusion from entering the isolation zone. The laminar flow along flow path  210  may be flowed at different flow rates to meet any back diffusion of gas, for example at junction  217  below exhaust  225 , to prevent the back diffusion of gas from isolator assembly  230  from entering the isolation zone developed by isolator assembly  220 . In one embodiment, the wafer may be heated to within a process temperature range as it travels along the wafer carrier track prior to entering the deposition zones  290 . The temperature of the wafer may be maintained within the process temperature range as it travels along the wafer carrier track through the deposition zones  290 . The wafer may be cooled to within a specific temperature range upon exiting the deposition zones  290  as it travels along the remainder of the wafer carrier track. 
         [0081]    The lengths of the isolation zones and the deposition zones may be varied to reduce the effects of back diffusion of gases. In one embodiment, the lengths of the isolation zones created may range from about 1 meter to about 2 meters in length but may extend beyond this range for different applications. 
         [0082]    The flow rates of the gases injected from the isolator assemblies may also be varied to reduce the effects of back diffusion of gases. In one embodiment, the entrance isolator assembly  220  and the exit isolator assembly  260  may supply a precursor gas at about 30 liters per minute, while the first  230 , second  240 , and third  250  isolator assemblies may supply a precursor gas at about 3 liters per minute. In one embodiment, the precursor gas supplied at the entrance isolator assembly  220  and the exit isolator assembly  260  may include nitrogen. In one embodiment, the precursor gas supplied at the first  230 , second  240 , and third  250  isolator assemblies may include arsine. In one embodiment, two isolator assemblies may supply a total of about 6 liters per minute of nitrogen. In one embodiment, three isolator assemblies may supply a total of about 9 liters per minute of arsine. 
         [0083]    The gap, e.g., the thickness between the guide path of the wafer carrier track and the raised portion of the reactor lid assembly, alternatively, the thickness of the space through which wafer travels into and out of the CVD reactor, of the isolation zones may also be varied to reduce the effects of back diffusion of gases. In one embodiment, the isolator gap may be in a range of about 0.1 mm to about 5 mm. 
         [0084]      FIG. 18  illustrates several flow path configurations  900  which may be provided by the CVD reactor. The flow path configurations  900  may be used for injecting a gas through one or more isolator assemblies, injecting a gas into a deposition zone, and/or exhausting a gas from isolation and/or deposition zones. Dual flow path configuration  910  shows a gas directed in the same direction as the flow path of the wafer, as well as in the opposite direction of the flow path of the wafer. In addition, a larger volume of flow may be directed through the dual flow path configuration  910  due to the wider flow area  911 . This wider flow area  911  may be adapted for use with the other embodiments described herein. Single flow path configuration  920  shows a gas directed in a single direction, which may be in the same or opposite direction of the flow path of the wafer. In addition, a low volume of flow may be directed through the single flow path configuration  920  due to the narrow flow area  921 . This narrower flow area  921  may be adapted for use with the other embodiments described herein. Exhaust flow path configuration  930  shows that gas may be exhausted from adjacent zones through a wider flow area  931 , such as adjacent isolation zones, adjacent deposition zones, or an isolation zone adjacent to a deposition zone. 
         [0085]    In one embodiment, first exhaust/injector flow path configuration  940  shows a dual flow path configuration  941  having a narrow flow area  943  disposed between an exhaust flow path  944  and a single injection flow path  945 . Also shown is a narrower gap  942  portion along which the wafer may travel through the CVD reactor. As described above, the gap  942  may vary along the wafer carrier track of the CVD reactor, thereby allowing a gas to be directly and uniformly injected onto the surface of the wafer. This narrower gap  942  portion may be used to provide full consumption or near full consumption of the gas injected onto the wafer during a reaction in a deposition zone. In addition, the gap  942  may be used to facilitate thermal control during the isolation and/or deposition process. A gas injected in the narrower gap  942  portion may maintain a higher temperature as it is injected onto the wafer. 
         [0086]    In one embodiment, a second exhaust/injector flow path configuration  950  provides a first exhaust flow path  954  having a wide flow area, a first dual flow path configuration  951  having a narrow gap portion  952  and flow area  953 , a first single injection flow path  955  having a wide flow area, a plurality of single injection flow paths  956  having narrow flow areas a wide gap portion, a second exhaust flow path  957  having a wide flow area, a second dual flow path configuration  958  having a narrow gap portion  959  and flow area, and a second single injection flow path  960  having a wide flow area and gap portion. 
         [0087]    In one embodiment, the gas injected through the isolator assemblies may be directed in the same direction as the flow path of the wafer. In an alternative embodiment, the gas injected through the isolator assemblies may be directed in the opposite direction as the flow path of the wafer. In an alternative embodiment, the gas injected through the isolator assemblies may be directed in both the same and opposite direction as the flow path of the wafer. In an alternative embodiment, the isolator assemblies may direct gas in different directions depending on their location in the CVD reactor. 
         [0088]    In one embodiment, the gas injected into the deposition zones may be directed in the same direction as the flow path of the wafer. In an alternative embodiment, the gas injected into the deposition zones may be directed in the opposite direction as the flow path of the wafer. In an alternative embodiment, the gas injected into the deposition zones may be directed in both the same and opposite direction as the flow path of the wafer. In an alternative embodiment, gas may be directed in different directions depending on the location of the deposition zone in the CVD reactor. 
         [0089]      FIG. 12  illustrates a second configuration  300 . The wafer(s)  310  is introduced into the entrance of the CVD reactor and travels along the wafer carrier track of the reactor. The reactor lid assembly  320  provides several gas isolation curtains  350  located at the entrance and the exit of the CVD reactor, as well as between deposition zones  340 ,  380 ,  390  to prevent contamination and mixing of the gases between deposition and isolation zones. The gas isolation curtains and deposition zones may be provided by one or more gas manifold assemblies of the reactor lid assembly  320 . These deposition zones include an aluminum arsenide deposition zone  340 , a gallium arsenide deposition zone  380 , and a phosphorous gallium arsenide deposition zone  390 , thereby forming a multiple layer epitaxial deposition process and structure. As the wafer(s)  310  travels along the bottom portion  330  of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer  310  may be subjected to temperature ramps  360  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zones  340 ,  380 ,  390 , to reduce thermal stress imparted on the wafer  310 . The wafer  310  may be heated to within a process temperature range prior to entering the deposition zones  340 ,  380 ,  390  to facilitate the deposition processes. As the wafer  310  travels through the deposition zones  340 ,  380 ,  390  the temperature of the wafer may be maintained within a thermal region  370  to assist with the deposition processes. The wafer(s)  310  may be provided on a conveyorized system to continuously feed and receive wafers into and out of the CVD reactor. 
         [0090]      FIG. 13  illustrates a third configuration  400 . The CVD reactor may be configured to supply nitrogen  410  to the reactor to float the wafer(s) along the wafer carrier track of the reactor at the entrance and the exit. A hydrogen/arsine mixture  420  may also be used to float the wafer along the wafer carrier track of the CVD reactor between the exit and entrance. The stages of the third configuration  400  may be provided by one or more gas manifold assemblies of the reactor lid assembly. The stages along the wafer carrier track may include an entrance nitrogen isolation zone  415 , a preheat exhaust zone  425 , a hydrogen/arsine mixture preheat isolation zone  430 , a gallium arsenide deposition zone  435 , a gallium arsenide exhaust  440 , an aluminum gallium arsenide deposition zone  445 , a gallium arsenide N-layer deposition zone  450 , a gallium arsenide P-layer deposition zone  455 , a phosphorous hydrogen arsine isolation zone  460 , a first phosphorous aluminum gallium arsenide deposition zone  465 , a phosphorous aluminum gallium arsenide exhaust zone  470 , a second phosphorous aluminum gallium arsenide deposition zone  475 , a hydrogen/arsine mixture cool down isolation zone  480 , a cool down exhaust zone  485 , and an exit nitrogen isolation zone  490 . As the wafer travels along the bottom portion of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer may be subjected to one or more temperature ramps  411  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zones  435 ,  445 ,  450 ,  455 ,  465 ,  475  to reduce thermal stress imparted on the wafer. The wafer may be heated to within a process temperature range prior to entering the deposition zones  435 ,  445 ,  450 ,  455 ,  465 ,  475  to facilitate the deposition processes. As the wafer travels through the deposition zones  435 ,  445 ,  450 ,  455 ,  465 ,  475  the temperature of the wafer may be maintained within a thermal region  412  to assist with the deposition processes. As shown, the temperature of the wafer traveling through the third configuration  400  may be increased as it passes the entrance isolation zone  415 , may be maintained as is travels through the zones  430 ,  435 ,  440 ,  445 ,  450 ,  455 ,  460 ,  465 ,  470 ,  475 , and may be decreased as it nears the hydrogen/arsine mixture cool down isolation zone  480  and travels along the remainder of the wafer carrier track. 
         [0091]      FIG. 14  illustrates a fourth configuration  500 . The CVD reactor may be configured to supply nitrogen  510  to the reactor to float the wafer(s) along the wafer carrier track of the reactor at the entrance and the exit. A hydrogen/arsine mixture  520  may also be used to float the wafer along the wafer carrier track of the CVD reactor between the exit and entrance. The stages of the fourth configuration  500  may be provided by one or more gas manifold assemblies of the reactor lid assembly. The stages along the wafer carrier track may include an entrance nitrogen isolation zone  515 , a preheat exhaust zone  525 , a hydrogen/arsine mixture preheat isolation zone  530 , an exhaust zone  535 , a deposition zone  540 , an exhaust zone  545 , a hydrogen/arsine mixture cool down isolation zone  550 , a cool down exhaust zone  555 , and an exit nitrogen isolation zone  545 . In one embodiment, the deposition zone  540  may include an oscillating showerhead assembly. As the wafer travels along the bottom portion of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer may be subjected to one or more temperature ramps  511 ,  513  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zone  540  to reduce thermal stress imparted on the wafer. The wafer may be heated to within a process temperature range prior to entering the deposition zone  540  to facilitate the deposition process. In one embodiment, the wafer may be heated and/or cooled to within a first temperature range as it travels through the temperature ramps  511 . In one embodiment, the wafer may be heated and/or cooled to within a second temperature range as it travels through the temperature ramps  513 . The first temperature range may be greater than, less than, and/or equal to the second temperature range. As the wafer travels through the deposition zone  540  the temperature of the wafer may be maintained within a thermal region  512  to assist with the deposition processes. As shown, the temperature of the wafer traveling through the fourth configuration  500  may be increased as it passes the entrance isolation zone  515 , may be maintained as is travels through the deposition zone  540 , and may be decreased as it nears the hydrogen/arsine mixture cool down isolation zone  550  and travels along the remainder of the wafer carrier track. 
         [0092]      FIG. 15  illustrates a fifth configuration  600 . The CVD reactor may be configured to supply nitrogen  610  to the reactor to float the wafer(s) along the wafer carrier track of the reactor at the entrance and the exit. A hydrogen/arsine mixture  620  may also be used to float the wafer along the wafer carrier track of the CVD reactor between the exit and entrance. The stages of the fifth configuration  600  may be provided by one or more gas manifold assemblies of the reactor lid assembly. The stages along the wafer carrier track may include an entrance nitrogen isolation zone  615 , a preheat exhaust with flow balance restrictor zone  625 , an active hydrogen/arsine mixture isolation zone  630 , a gallium arsenide deposition zone  635 , an aluminum gallium arsenide deposition zone  640 , a gallium arsenide N-layer deposition zone  645 , a gallium arsenide P-layer deposition zone  650 , a phosphorous aluminum gallium arsenide deposition zone  655 , a cool down exhaust zone  660 , and an exit nitrogen isolation zone  665 . As the wafer travels along the bottom portion of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer may be subjected to one or more temperature ramps  611  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zones  635 ,  640 ,  645 ,  650 ,  655  to reduce thermal stress imparted on the wafer. The wafer may be heated to within a process temperature range prior to entering the deposition zones  635 ,  640 ,  645 ,  650 ,  655  to facilitate the deposition processes. As the wafer travels through the deposition zones  635 ,  640 ,  645 ,  650 ,  655  the temperature of the wafer may be maintained within a thermal region  612  to assist with the deposition processes. As shown, the temperature of the wafer traveling through the fifth configuration  600  may be increased as is passes the entrance isolation zone  615  and approaches the active hydrogen/arsine mixture isolation zone  630 , may be maintained as it travels through the deposition zones  635 ,  640 ,  645 ,  650 ,  655 , and may be decreased as it nears the cool down exhaust zone  660  and travels along the remainder of the wafer carrier track. 
         [0093]      FIG. 16  illustrates a sixth configuration  700 . The CVD reactor may be configured to supply nitrogen  710  to the reactor to float the wafer(s) along the wafer carrier track of the reactor at the entrance and the exit. A hydrogen/arsine mixture  720  may also be used to float the wafer along the wafer carrier track of the CVD reactor between the exit and entrance. The stages of the sixth configuration  700  may be provided by one or more gas manifold assemblies of the reactor lid assembly. The stages along the wafer carrier track may include an entrance nitrogen isolation zone  715 , a preheat exhaust with flow balance restrictor zone  725 , a gallium arsenide deposition zone  730 , an aluminum gallium arsenide deposition zone  735 , a gallium arsenide N-layer deposition zone  740 , a gallium arsenide P-layer deposition zone  745 , a phosphorous aluminum gallium arsenide deposition zone  750 , a cool down exhaust with flow balance restrictor zone  755 , and an exit nitrogen isolation zone  760 . As the wafer travels along the bottom portion of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer may be subjected to one or more temperature ramps  711  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zones  730 ,  735 ,  740 ,  745 ,  750  to reduce thermal stress imparted on the wafer. The wafer may be heated to within a process temperature range prior to entering the deposition zones  730 ,  735 ,  740 ,  745 ,  750  to facilitate the deposition processes. As the wafer travels through the deposition zones  730 ,  735 ,  740 ,  745 , 750  the temperature of the wafer may be maintained within a thermal region  712  to assist with the deposition processes. As shown, the temperature of the wafer traveling through the sixth configuration  700  may be increased as is passes the entrance isolation zone  715  and approaches the gallium arsenide deposition zone  730 , may be maintained as it travels through the deposition zones  730 ,  735 ,  740 ,  745 ,  750 , and may be decreased as it nears the cool down exhaust zone  755  and travels along the remainder of the wafer carrier track. 
         [0094]      FIG. 17  illustrates a seventh configuration  800 . The CVD reactor may be configured to supply nitrogen  810  to the reactor to float the wafer(s) along the wafer carrier track of the reactor at the entrance and the exit. A hydrogen/arsine mixture  820  may also be used to float the wafer along the wafer carrier track of the CVD reactor between the exit and entrance. The stages of the seventh configuration  800  may be provided by one or more gas manifold assemblies of the reactor lid assembly. The stages along the wafer carrier track may include an entrance nitrogen isolation zone  815 , a preheat exhaust zone  825 , a deposition zone  830 , a cool down exhaust zone  835 , and an exit nitrogen isolation zone  840 . In one embodiment, the deposition zone  830  may include an oscillating showerhead assembly. As the wafer travels along the bottom portion of the reactor, which may generally include the wafer carrier track and the heating lamp assembly, the wafer may be subjected to one or more temperature ramps  811 ,  813  at the entrance and exit of the reactor to incrementally increase and decrease the temperature of the wafer, prior to entering and upon exiting the deposition zone  830  to reduce thermal stress imparted on the wafer. The wafer may be heated to within a process temperature range prior to entering the deposition zone  830  to facilitate the deposition process. In one embodiment, the wafer may be heated and/or cooled to within a first temperature range as it travels through the temperature ramps  811 . In one embodiment, the wafer may be heated and/or cooled to within a second temperature range as it travels through the temperature ramps  813 . The first temperature range may be greater than, less than, and/or equal to the second temperature range. As the wafer travels through the deposition zone  830  the temperature of the wafer may be maintained within a thermal region  812  to assist with the deposition processes. As shown, the temperature of the wafer traveling through the seventh configuration  800  may be increased as it passes the entrance isolation zone  815  and approaches the deposition zone  830 , may be maintained as it travels through the deposition zone  830 , and may be decreased as it nears the cool down exhaust zone  835 , then the exit nitrogen isolation zone  840  and travels along the remainder of the wafer carrier track. 
         [0095]    In one embodiment, the CVD reactor may be configured to grow or deposit a high quality gallium arsenide and aluminum gallium arsenide double heterostructure at a deposition rate of about 1 μm/min, may be configured to grow or deposit a high quality aluminum arsenide epitaxial lateral overgrowth sacrificial layer, and may be configured to provide a throughput of about 6 wafers per minute to about 10 wafers per minute. 
         [0096]    In some embodiments, the CVD reactor may be configured to grow or deposit materials on wafers of varying sizes, for example, 4 cm×4 cm or 10 cm×10 cm. In one embodiment the CVD reactor may be configured to provide a 300 nm gallium arsenide buffer layer. In another embodiment the CVD reactor may be configured to provide a 30 nm aluminum gallium arsenide passivation layer. In another embodiment the CVD reactor may be configured to provide a 1,000 nm gallium arsenide active layer. In another embodiment the CVD reactor may be configured to provide a 30 nm aluminum gallium arsenide passivation layer. In another embodiment the CVD reactor may be configured to provide a dislocation density of less than 1×10 4  per cm 2 , a photoluminescence efficiency of 99%, and a photoluminescence lifetime of 250 nanoseconds. 
         [0097]    In another embodiment the CVD reactor may be configured to provide an epitaxial lateral overgrowth layer having a 5 nm deposition ±0.5 nm, an etch selectivity greater than 1×10 6 , zero pinholes, and an aluminum arsenide etch rate greater than 0.2 mm per hour. In another embodiment the CVD reactor may be configured to provide a center to edge temperature non-uniformity of no greater than 10° C. for temperatures above 300° C., a V-III ratio of no more than 5, and a maximum temperature of 800° C. 
         [0098]    In one embodiment the CVD reactor may be configured to provide a deposition layers having a 300 nm gallium arsenide buffer layer, a 5 nm aluminum arsenide sacrificial layer, a 10 nm aluminum gallium arsenide window layer, a 700 nm gallium arsenide 2×10 17  Si active layer, a 300 nm aluminum gallium arsenide 1×10 19  C P+ layer, and a 300 nm gallium arsenide 1×10 19  C P+ layer. 
         [0099]    In another embodiment the CVD reactor may be configured to provide a deposition layers having a 300 nm gallium arsenide buffer layer, a 5 nm aluminum arsenide sacrificial layer, a 10 nm gallium indium phosphide window layer, a 700 nm gallium arsenide 2×10 17  Si active layer, a 100 nm gallium arsenide C P layer, a 300 nm gallium indium phosphide P window layer, a 20 nm gallium indium phosphide 1×10 20  P+ tunnel junction layer, a 20 nm gallium indium phosphide 1×10 20  N+ tunnel junction layer, a 30 nm aluminum gallium arsenide window, a 400 nm gallium indium phosphide N active layer, a 100 nm gallium indium phosphide P active layer, a 30 nm aluminum gallium arsenide P window, and a 300 nm gallium arsenide P+ contact layer. 
         [0100]    Embodiments of the invention generally relate to a levitating substrate carrier or support. In one embodiment, a substrate carrier for supporting and carrying at least one substrate or wafer passing through a reactor is provided which includes a substrate carrier body containing an upper surface and a lower surface, and at least one indentation pocket disposed within the lower surface. In another embodiment, the substrate carrier includes a substrate carrier body containing an upper surface and a lower surface, and at least two indentation pockets disposed within the lower surface. In another embodiment, the substrate carrier includes a substrate carrier body containing an upper surface and a lower surface, an indentation area within the upper surface, and at least two indentation pockets disposed within the, lower surface. In another embodiment, the substrate carrier includes a substrate carrier body containing an upper surface and a lower surface, an indentation area within the upper surface, and at least two indentation pockets disposed within the lower surface, wherein each indentation pocket has a rectangular geometry and four side walls which extend perpendicular or substantially perpendicular to the lower surface. In another embodiment, the substrate carrier includes a substrate carrier body containing an upper surface and a lower surface, and at least two indentation pockets disposed within the lower surface, wherein each indentation pocket has a rectangular geometry and four side walls which extend perpendicular or substantially perpendicular to the lower surface. 
         [0101]    In another embodiment, a substrate carrier for supporting and carrying at least one substrate passing through a reactor is provided which includes a substrate carrier body containing an upper surface and a lower surface, and at least one indentation pocket disposed within the lower surface. The substrate carrier body may have a rectangular geometry, a square geometry, or another type of geometry. In one example, the substrate carrier body has two short sides and two long sides, wherein one of the two short sides is the front of the substrate carrier body and the other short side is the rear of the substrate carrier body. The substrate carrier body may contain or be made from graphite. 
         [0102]    In some examples, the upper surface contains at least one indentation area disposed therein. The indentation area within the upper surface is configured to hold a substrate thereon. In other examples, the upper surface may have at least two, three, four, eight, twelve, or more of the indentation areas. In another example, the upper surface has no indentation areas. 
         [0103]    In another embodiment, the lower surface may have at least two of the indentation pockets, which are configured to accept a gas cushion. In some examples, the lower surface has one, three, or more of the indentation pockets. The indentation pocket may have a rectangular geometry, a square geometry, or another type of geometry. Each of the indentation pockets usually has two short sides and two long sides. In one example, the short sides and the long sides are straight. The short sides and the long sides are perpendicular relative to the lower surface. In another example, at least one of the two short sides is tapered at a first angle, at least one of the two long sides is tapered at a second angle, and the first angle may be greater than or less than the second angle. In another example, at least one of the two short sides is straight and at least one of the two long sides is tapered. In another example, at least one of the two short sides is tapered and at least one of the two long sides is straight. In one embodiment, the indentation pocket has a rectangular geometry and the indentation pocket is configured to accept a gas cushion. The indentation pocket may have tapered side walls which taper away from the upper surface. 
         [0104]    In another embodiment, a method for levitating substrates disposed on an upper surface of a substrate carrier during a vapor deposition process is provided which includes exposing a lower surface of a substrate carrier to a gas stream, forming a gas cushion under the substrate carrier, levitating the substrate carrier within a processing chamber, and moving the substrate carrier along a path within the processing chamber. In many examples, the movement of the substrate carrier and/or the velocity of the substrate carrier along the path may be controlled by adjusting the flow rate of the gas stream. The air cushion may be formed within at least one indentation pocket disposed within the lower surface. In some examples, the lower surface has at least two indentation pockets. The indentation pockets are configured to accept the gas cushion. An upper surface of the substrate carrier has at least one indentation area for supporting a substrate. The indentation pocket may have tapered side walls which taper away from the upper surface of the substrate carrier. 
         [0105]    In another embodiment, a method for levitating substrates disposed on a substrate carrier during a vapor deposition process is provided which includes exposing a lower surface of a substrate carrier to a gas stream, wherein at least one wafer is disposed on an upper surface of the substrate carrier and the lower surface contains at least one indentation pocket, forming a gas cushion under the substrate carrier, levitating the substrate carrier within a processing chamber, and moving the substrate carrier along a path within the processing chamber. 
         [0106]    In another embodiment, a method for levitating substrates disposed on a substrate carrier during a vapor deposition process is provided which includes exposing a lower surface of a substrate carrier to a gas stream, wherein the lower surface contains at least one indentation pocket, forming a gas cushion under the substrate carrier, levitating the substrate carrier within a processing chamber, and moving the substrate carrier along a path within the processing chamber. 
         [0107]    In another embodiment, a method for levitating substrates disposed on a substrate carrier during a vapor deposition process is provided which includes exposing a lower surface of a substrate carrier to a gas stream, wherein the lower surface contains at least two indentation pockets, forming a gas cushion under the substrate carrier, levitating the substrate carrier within a processing chamber, and moving the substrate carrier along a path within the processing chamber. 
         [0108]    Embodiments of the invention generally relate to a CVD reactor system and related methods of use. In one embodiment, a CVD system is provided which includes a lid assembly, such as a top plate, having a plurality of raised portions located along the longitudinal axis of the top plate. The system includes a track having a guide path, such as a channel, located along the longitudinal axis of the track, wherein the channel is adapted to receive the plurality of raised portions of the top plate, thereby forming a gap between the plurality of raised portions and a floor of the track, wherein the gap is configured to receive a substrate. The system includes a heating assembly, such as a heating element, operable to heat the substrate as the substrate moves along the channel of the track. In one embodiment, the track is operable to float the substrate along the channel of the track. 
         [0109]    In one embodiment, system includes a trough that supports the track. The gap may have a thickness within a range from about 0.5 mm to about 5 mm, or from about 0.5 mm to about 1 mm. The top plate is formed from molybdenum or quartz, the track is formed from quartz or silica. The top plate is operable to direct a gas to the gap and may further include a plurality of ports located along the longitudinal axis of the top plate and disposed between the plurality of raised portions, thereby forming paths between the plurality of raised portions. One or more of the plurality of ports is adapted to communicate and/or exhaust a gas to the gap between plurality of raised portions of the top plate and the floor of the track. 
         [0110]    Examples of the heating element include a heating lamp coupled to or with the track, a plurality of heating lamps disposed along the track, a heating lamp bank operable to move along the track as the substrate moves along the channel of the track, resistive heaters coupled to or with the track, an inductive heating source coupled to or with the substrate and/or the track. The heating element is operable to maintain a temperature differential across the substrate, wherein the temperature differential is less than 10° C. In one embodiment, the CVD system is an atmospheric pressure CVD system. 
         [0111]    In one embodiment, a CVD system is provided which includes an entrance isolator operable to prevent contaminants from entering the system at an entrance of the system, an exit isolator operable to prevent contaminants from entering the system at an exit of the system, and an intermediate isolator disposed between the entrance and exit isolators. The system may further include a first deposition zone disposed adjacent the entrance isolator and a second deposition zone disposed adjacent the exit isolator. The intermediate isolator is disposed between the deposition zones and is operable to prevent mixing of gases between the first deposition zone and the second deposition zone. 
         [0112]    In one embodiment, the entrance isolator is further operable to prevent back diffusion of gases injected into the first deposition zone, the intermediate isolator is further operable to prevent back diffusion of gases injected into the second deposition zone, and the exit isolator is further operable to prevent back diffusion of gases injected into the second deposition zone. An isolation zone formed by at least one of the isolators has a length within a range from about 1 meter to about 2 meters. A gas, such as nitrogen, is injected into the entrance isolator at a first flow rate, such as about 30 liters per minute, to prevent back diffusion of gases from the first deposition zone. A gas, such as arsine, is injected into the intermediate isolator at a first flow rate, such as about 3 liters per minute, to prevent back mixing of gases between the first deposition zone and the second deposition zone. A gas, such as nitrogen, is injected into the exit isolator at a first flow rate, such as about 30 liters per minute, to prevent contaminants from entering the system at the exit of the system. In one embodiment, an exhaust is disposed adjacent each isolator and operable to exhaust gases injected by the isolators. An exhaust may be disposed adjacent each deposition zone and operable to exhaust gases injected into the deposition zones. 
         [0113]    In one embodiment, a CVD system is provided which includes a housing, a track surrounded by the housing, wherein the track forms a guide path, such as a channel, adapted to guide the substrate through the CVD system. The system includes a carrier for moving the substrate along the channel of the track, wherein the track is operable to levitate the carrier along the channel of the track. The housing contains or is formed from molybdenum, quartz, or stainless steel, the track contains or is formed from quartz, molybdenum, fused silica, ceramic, and the carrier is formed from graphite. 
         [0114]    In one embodiment, the track contains a plurality of openings and/or a conduit disposed along the floor of the track each operable to supply a cushion of gas to the channel and the bottom surface of the carrier to lift or levitate the carrier and substantially center the carrier along the channel of the track. The conduit may have a v-shape and the carrier may have a notch (e.g., v-shape) disposed along its bottom surface. A gas is applied to the notch of the carrier to substantially lift the carrier from the floor of the track and to substantially center the carrier along the channel of the track. The track may be tilted, such as at an angle less than about 20°, less than about 10°, or between about 1° and about 5°, to allow the substrate to move and float from a first end of the channel to a second end of the channel. The track and/or housing may include multiple segments. 
         [0115]    In one embodiment, the system may include a conveyor operable to automatically introduce substrates into the channel, a retriever operable to automatically retrieve substrates from the channel, and/or a heating element operable to heat the substrate. The heating element is coupled to or with the housing, the substrate, and/or the track. The carrier is operable to carry strips of the substrate along the channel of the track. 
         [0116]    In one embodiment, a track assembly for moving a substrate through a CVD system is provided which includes a top section having a floor, side supports, such as a pair of rails, disposed adjacent the floor, thereby forming a guide path, such as a channel, to guide the substrate along the floor. A bottom section is coupled to or with the top section to form one or more chambers therebetween. The top section may include a recessed bottom surface and the bottom section may include a recessed top surface to form the chamber. In one embodiment the top section and/or the bottom section is formed from molybdenum, quartz, silica, alumina, or ceramic. 
         [0117]    In one embodiment, the top section has a plurality of openings disposed through the floor to provide fluid communication between the chamber and the channel. A cushion of gas, such as nitrogen, is supplied from the chamber to the channel to substantially lift and carry the substrate from and along the floor of the top section. The floor may be tilted, such as at an angle less than about 10°, about 20°, or within range from about 1° to about 5°, to allow the substrate to move and float from a first end of the channel to a second end of the channel. 
         [0118]    In one embodiment, the top section has a plurality of openings disposed through the pair of rails adjacent the floor. A gas is supplied through the plurality of openings to substantially center the substrate moving along the channel of the top section. The floor may also include a tapered profile and/or a conduit through which a gas is supplied each operable to substantially center the substrate moving along the channel of the top section. The conduit may have a v-shape and/or the substrate may have a notch (e.g., v-shaped) for receiving a gas cushion disposed along a bottom surface of the substrate operable to substantially center the substrate moving along the channel of the top section. 
         [0119]    In one embodiment, the track assembly may include a conveyor operable to automatically introduce substrates into the channel and/or a retriever operable to automatically retrieve substrates from the channel. An injection line may be coupled to or with the bottom section to supply a gas to the chamber through the floor to substantially float the substrate along the floor of the top section. The top section may further include recessed portions adjacent the rails operable to receive reactor lid assembly, such as a top plate. The track assembly may include a trough in which the top section and bottom section are seated. The trough is formed from quartz, molybdenum, or stainless steel. 
         [0120]    In one embodiment, a method for forming a multi-layered material during a CVD process is provided which includes forming a gallium arsenide buffer layer on a gallium arsenide substrate, forming an aluminum arsenide sacrificial layer on the buffer layer, and forming an aluminum gallium arsenide passivation layer on the sacrificial layer. The method may further include forming a gallium arsenide active layer (e.g., at about 1,000 nm thick) on the passivation layer. The method may further include forming a phosphorous gallium arsenide layer on the active layer. The method may further include removing the sacrificial layer to separate the active layer from the substrate. The aluminum arsenide sacrificial layer may be exposed to an etching solution while the gallium arsenide active layer is separated from the substrate during an epitaxial lift off process. The method may further include forming additional multi-layered materials on the substrate during a subsequent CVD process. The buffer layer may be about 300 nm in thickness, the passivation layer may be about 30 nm in thickness, and/or the sacrificial layer may be about 5 nm in thickness. 
         [0121]    In one embodiment, a method of forming multiple epitaxial layers on a substrate using a CVD system is provided which includes introducing the substrate into a guide path, such as a channel, at an entrance of the system, while preventing contaminants from entering the system at the entrance, depositing a first epitaxial layer on the substrate, while the substrate moves along the channel of the system, depositing a second epitaxial layer on the substrate, while the substrate move along the channel of the system, preventing mixing of gases between the first deposition step and the second deposition step, and retrieving the substrate from the channel at an exit of the system, while preventing contaminants from entering the system at the exit. The method may further include heating the substrate prior to depositing the first epitaxial layer, maintaining the temperature of the substrate as the first and second epitaxial layers are deposited on the substrate, and/or cooling the substrate after depositing the second epitaxial layer. The substrate may substantially float along the channel of the system. The first epitaxial layer may include aluminum arsenide and/or the second epitaxial layer may include gallium arsenide. The method may further include depositing a phosphorous gallium arsenide layer on the substrate and/or heating the substrate to a temperature within a range from about 300° C. to about 800° C. during the depositing of the epitaxial layers. A center temperature to an edge temperature of the substrate may be within 10° C. of each other. 
         [0122]    In one embodiment, a CVD reactor is provided which includes a lid assembly having a body, and a track assembly having a body and a guide path located along the longitudinal axis of the body. The body of the lid assembly and the body of the track assembly are coupled together to form a gap therebetween that is configured to receive a substrate. The reactor may further include a heating assembly containing a plurality of heating lamps disposed along the track assembly and operable to heat the substrate as the substrate moves along the guide path. The reactor may further include a track assembly support, wherein the track assembly is disposed in the track assembly support. The body of the track assembly may contain a gas cavity within and extending along the longitudinal axis of the body and a plurality of ports extending from the gas cavity to an upper surface of the guide path and configured to supply a gas cushion along the guide path. The body of the track assembly may contain quartz. The body of the lid assembly may include a plurality of ports configured to provide fluid communication to the guide path. The heating assembly may be operable to maintain a temperature differential across the substrate, wherein the temperature differential is less than 10° C. In one embodiment, the CVD reactor is an atmospheric pressure CVD reactor. 
         [0123]    In one embodiment, a CVD system is provided which includes an entrance isolator operable to prevent contaminants from entering the system at an entrance of the system, an exit isolator operable to prevent contaminants from entering the system at an exit of the system, and an intermediate isolator disposed between the entrance and exit isolators. The system may further include a first deposition zone disposed adjacent the entrance isolator and a second deposition zone disposed adjacent the exit isolator. The intermediate isolator is disposed between the deposition zones and is operable to prevent mixing of gases between the first deposition zone and the second deposition zone. A gas is injected into the entrance isolator at a first flow rate to prevent back diffusion of gases from the first deposition zone, a gas is injected into the intermediate isolator at a first flow rate to prevent back mixing of gases between the first deposition zone and the second deposition zone, and/or a gas is injected into the exit isolator at a first flow rate to prevent contaminants from entering the system at the exit of the system. An exhaust may be disposed adjacent each isolator and operable to exhaust gases injected by the isolators and/or disposed adjacent each deposition zone and operable to exhaust gases injected into the deposition zones. 
         [0124]    In one embodiment, a CVD system is provided which includes a housing, a track surrounded by the housing, wherein the track contains a guide path adapted to guide a substrate through the CVD system, and a substrate carrier for moving the substrate along the guide path, wherein the track is operable to levitate the substrate carrier along the guide path. The track may include a plurality of openings operable to supply a gas cushion to the guide path. The gas cushion is applied to a bottom surface of the substrate carrier to lift the substrate carrier from a floor of the track. The track may include a conduit disposed along the guide path and operable to substantially center the substrate carrier along the guide path of the track. A gas cushion may be supplied through the conduit to a bottom surface of the substrate carrier to substantially lift the substrate carrier from a floor of the track. The track may be tilted to allow the substrate to move from a first end of the guide path to a second end of the guide path. The system may include a heating assembly containing a plurality of heating lamps disposed along the track and operable to heat the substrate as the substrate moves along the guide path. 
         [0125]    The CVD reactors, chambers, systems, zones, and derivatives of these reactors may be used for a variety of CVD and/or epitaxial deposition processes to form an assortment of materials on wafers or substrates, as described in embodiments herein. In one embodiment, a Group III/V material—which contains at least one element of Group III (e.g., boron, aluminum, gallium, or indium) and at least one element of Group V (e.g., nitrogen, phosphorous, arsenic, or antimony) may be formed or deposited on a wafer. Examples of deposited materials may contain gallium nitride, indium phosphide, indium gallium phosphide, gallium arsenide, aluminum gallium arsenide, aluminum arsenide derivatives thereof, alloys thereof, multi-layers thereof, or combinations thereof. In some embodiments herein, the deposited materials may be epitaxial materials. The deposited material or epitaxial material may contain one layer, but usually contains multiple layers. In some examples, the epitaxial material contains a layer having gallium arsenide and another layer having aluminum gallium arsenide. In another example, the epitaxial material contains a gallium arsenide buffer layer, an aluminum gallium arsenide passivation layer, and a gallium arsenide active layer. The gallium arsenide buffer layer may have a thickness within a range from about 100 nm to about 500 nm, such as about 300 nm, the aluminum arsenide sacrificial layer may have a thickness within a range from about 1 nm to about 20 nm, such as about 5 nm, the aluminum gallium arsenide passivation layer may have a thickness within a range from about 10 nm to about 50 nm, such as about 30 nm, and the gallium arsenide active layer may have a thickness within a range from about 500 nm to about 2,000 nm, such as about 1,000 nm. In some examples, the epitaxial material further contains a second aluminum gallium arsenide passivation layer. 
         [0126]    In one embodiment, the process gas used in the CVD reactors, chambers, systems, zones may contain arsine, argon, helium, nitrogen, hydrogen, or mixtures thereof. In one example, the process gas contains an arsenic precursor, such as arsine. In other embodiments, the first precursor may contain an aluminum precursor, a gallium precursor, an indium precursor, or combinations thereof, and the second precursor may contain a nitrogen precursor, a phosphorus precursor, an arsenic precursor, an antimony precursor or combinations thereof. 
         [0127]    In an alternative embodiment, a CVD system  2000  contains a plurality of showerheads  2010  disposed one after another in a linear path, as depicted in  FIG. 20 . The showerheads  2010  may be tiled together in order to produce the effect of a larger showerhead, such as to form large growth area or large deposition zone. Multiple wafers  2002  rest on a platter  2004  during the deposition processes. The wafers  2002  may also be placed in a tiled pattern in order to stay clear from any seams between the showerhead  2010 . In one process embodiment, the CVD system  2000  may be exhausted between tiles of showerheads  2010 , such as at exhaust ports  2014  and  2016 , in order to reduce flow speed. The CVD system  2000  may also be exhausted at exhaust port  2012  and  2018 . 
         [0128]    In another alternative embodiment, a CVD system  2100  contains a heat-up zone  2120 , a growth zone  2130 , and a cool-down zone  2140  along a linear path, as depicted in  FIG. 21 . Showerheads (not shown) are usually disposed within the growth zone  2130 . Multiple wafers  2102  rest on each platter  2104  within each processing zone, such as the heat-up zone  2120 , the growth zone  2130 , and the cool-down zone  2140 . Platter  2104  contains raised edges  2106  in order to form a “pocket”—such as process region  2110 —around each group of wafers  2102 . Process regions  2110  keep the wafers  2102  in a semi-enclosed environment within each of the processing zones. Platters  2104  are disposed on platform  2108 , which contains a heater, a cooler, and a temperature regulation system (not shown). Therefore, the temperature for each of the heat-up zone  2120 , the growth zone  2130 , and the cool-down zone  2140  may be independently controlled and regulated by platform  2108 . 
         [0129]    The CVD system  2100  provides for a much narrower gap for isolation than growth zone and reduces the total flow rate requirement for back-flow isolation. In one process embodiment, the heat-up zone  2120  and the growth zone  2130  may be separated by isolation exhaust port  2114  therebetween, similarly, the growth zone  2130  and the cool-down zone  2140  may be separated by isolation exhaust port  2116 . 
         [0130]    While the foregoing is directed to embodiments of the 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.