Abstract:
The invention relates to a wafer scale process for the manufacture of optical waveguide devices, and particularly for the manufacture of ridge waveguide devices, and the improved waveguides made thereby. The present invention has found a process for achieving sub-micron control of an optical waveguiding layer thickness by providing a dimensionally stable wafer assembly into which adhesive can be introduced without altering the planar relationship between a carrier wafer and an optically transmissive wafer in wafer scale manufacture. This process permits wafer scale manufacture of optical waveguide devices including thin optically transmissive layers. A pattern of spacer pedestals is created by a deposition and etch back, or by a surface etch process to precisely reference surface information from a master surface to a carrier wafer to a thin optically transmissive wafer. The tolerance achievable in accordance with this process provides consistent yield across the wafer.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS 
   The present invention claims priority from Provisional Patent Application No. 60/806,040 filed Jun. 28, 2006, by Catching et al. entitled “Ridge Waveguide with Pedestals —A Component For Solid State Blue Lasers” which is incorporated herein by reference. 

   TECHNICAL FIELD 
   The present invention relates to a wafer scale process for the manufacture of optical waveguide devices, and particularly for the manufacture of ridge waveguide devices, and the improved ridge waveguides made thereby. 
   BACKGROUND OF THE INVENTION 
   Optical waveguide devices require a high degree of accuracy in the dimensions of the optical waveguiding layer. In the past it has not been possible to achieve the degree of parallelism and uniformity in a wafer scale manufacturing process that would enable an adequate yield across the wafer, and from wafer to wafer. A wafer of optically transmissive material thinned and polished to waveguide dimensions of approximately 1-10 microns does not have the dimensional stability to be polished to or to hold the flatness required, or even to be handled without breaking. In order to achieve the degree of parallelism required in a thin optical material, a master reference plane must be provided in a carrier substrate wafer. It is known in the art to polish wafers to a uniformity of parallelism within 0.005 microns. However, for wafer scale manufacture, this precision is not transferred to the thin waveguiding layer due to variation introduced by the adhesive layer securing the waveguiding layer to the carrier substrate. Optical devices such as planar lightwave circuits, electro-optic modulators and ridge waveguide devices are examples of optical waveguide devices for which dimensional uniformity is essential to achieve wafer scale production. 
   Second harmonic generation applications (frequency doubling) using ridge waveguide devices have been developed to create laser output in the ultraviolet, visible and infrared wavelength spectrum for use in numerous technologies. Demand for these devices is high. However, the manufacture of ridge waveguide devices has been limited to individual device processing. One problem that arises in the manufacture of ridge waveguides for the application of second harmonic generation is the control of dimensions of the ridge. In particular the thicknesses of the ridge waveguide must be controlled accurately, due to sensitivity of the upconversion wavelength to all dimensions of the ridge. Lateral dimensions are controlled with photolithographic processes, while vertical dimensions are controlled by etching and polishing processes. 
   Ridge waveguide devices for second harmonic generation considered in this application have periodically poled regions in the waveguides for phase matching the pump and output signals. Adhesive assembly of the supporting carrier wafer and optically transmissive wafer is preferred. In order to achieve adequate manufacturing yield, the range of thickness of the ridge and planar slab region must be controlled to within a few tenths of a micron. In order to achieve this level of uniformity across the wafer and from wafer-to-wafer, the thickness of the adhesive between the transmissive wafer and carrier wafer must be controlled to within this same range. This level of control for wafer scale manufacture has not been demonstrated in the prior art. 
   An optical wavelength conversion element is disclosed in U.S. Pat. No. 6,631,231 by Kiminori Mizuuchi et al. issued to Matsushita Electric Industrial Co. Ltd. on Oct. 7, 2003. In this patent a continuous joining layer of amorphous material is used to join a poled waveguide structure to a substrate layer. No method for controlling the adhesive thickness is disclosed, although the disclosure does recognize some critical optical limitations to adhesive thickness. Instead, significant post assembly finishing is disclosed. These are labor intensive methods for individual device production. Such methods do not produce high yield. Furthermore, the Mizuuchi design is dependent on the optical properties of the adhesive layer, which limits the design choice. 
   Adhesive layer spacing is known in various optical industries. For instance glass fiber particles are disclosed for use as spacers between LCD display screen layers in U.S. Pat. No. 4,390,245. U.S. Pat. No. 6,896,949 disclosing the wafer scale manufacture of etalons also makes use of small beads to facilitate spacing between plural assembled etalons, or of fritted glass which is applied to a certain thickness and heated to its melting point to join etalon elements. An image sensor as disclosed in U.S. Pat. No. 5,433,911 also discloses the assembly of an individual device, using spacers constructed through resist patterning in order to secure a protective cover with controlled parallelism. However, none of these disclosures provide instruction for adhesive assembly suitable for the present application that can provide the level of accuracy necessary for wafer scale production control across the wafer and from wafer to wafer. Beads and spacers available in the industry do not provide the uniformity within 0.1 microns deviation needed to ensure tolerance control across the wafer. 
   A wafer scale manufacturing process for optical waveguide devices, and ridge waveguide devices in particular, remains highly desired in the industry. 
   An object of the present invention is to provide a wafer scale manufacturing process for producing optical waveguide devices with sub micron accuracy and high yield. 
   It is a further objective of the present invention to provide a ridge waveguide device made in accordance with the manufacturing process of the present invention including rigid spacing elements within a precisely dimensioned discontinuous adhesive layer. 
   SUMMARY OF THE INVENTION 
   The present invention has found a process for achieving sub-micron control of an optical waveguiding layer thickness by providing a dimensionally stable wafer assembly into which adhesive can be introduced without altering the planar relationship between a carrier wafer and an optically transmissive wafer in wafer scale manufacture. This process permits the required dimensional control of ridge and slab in ridge waveguide devices in wafer scale manufacture. More generally, this process permits wafer scale manufacture of optical waveguide devices including thin optically transmissive layers. In particular, a pattern of spacer pedestals is created by a deposition and etch back, or by a surface etch process to precisely reference the joining surface of the optically transmissive wafer to the joining surface of the carrier wafer which is by necessity parallel to the exposed surface of the carrier wafer which is in turn referenced to a reusable master surface. The tolerance achievable in accordance with this process provides consistent yield across the wafer. The process additionally provides enhanced structural integrity to the finished devices. 
   Accordingly, the present invention relates to a wafer scale process for manufacturing optical waveguide devices comprising the steps of:
         providing a transmissive wafer of optically transmissive material having a joining surface and an exterior surface;   providing a carrier wafer having a joining surface and an exterior surface substantially parallel to the joining surface;   creating a relief pattern on one of the joining surfaces, the relief pattern comprising pedestals having a substantially uniform height;   contacting the pedestals with the joining surface of the other wafer and introducing adhesive material into the spaces created by the relief pattern;   polishing and thinning the transmissive wafer to a prescribed dimension;   creating a waveguide structure in the transmissive wafer;   dicing the assembled wafer structure into individual waveguide devices.       

   The present invention further relates to a wafer scale process wherein the waveguide structure is selected from the group consisting of: ridge waveguide, indiffused waveguide, and planar waveguide. 
   Another aspect of the present invention relates to a method of manufacturing optical ridge waveguide devices comprising the steps of:
         providing a transmissive wafer of optically non-linear transmissive material having a joining surface and an exterior surface;   providing a carrier wafer having a joining surface and an exterior surface;
           applying a cladding layer to the joining surface of the optically transmissive wafer including the waveguide structure;   
           etching a portion of the cladding layer to the joining surface, without removing the cladding on the waveguide structure, to create a relief pattern adapted to facilitate an adhesive joint between the joining surfaces;   contacting the cladding layer to the joining surface of the carrier wafer, and introducing adhesive into the spaces created by the relief pattern;   polishing and thinning the exterior surface of the transmissive wafer;   creating a waveguide structure in the joining surface of the optically transmissive wafer; dicing the assembled wafer structure into individual waveguide devices.       

   Another feature of the present invention provides an optical waveguide device comprising:
         a carrier substrate having a joining surface substantially parallel to an exterior surface;   an optically transmissive substrate adhesively joined to the carrier substrate having a waveguide formed therein;   a plurality of rigid pedestals abutting a joining surface of the carrier substrate and a joining surface of the transmissive substrate; and   a discontinuous adhesive layer surrounding the pedestals and securing the joining surface of the carrier substrate to the joining surface of the transmissive substrate, having a uniform thickness defined by a height of the pedestals.       

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The invention will be described in greater detail with reference to the accompanying drawings which represent preferred embodiments thereof, wherein: 
       FIG. 1  is a cross-section of a ridge waveguide device in accordance with the present invention in which pedestals are located on the carrier wafer along dicing streets, prior to dicing from the assembled wafer structure; 
       FIG. 2  is an enlarged cross-section of a portion of a further embodiment of the present invention in which pedestals are distributed across the waveguide device; 
       FIG. 3  illustrates a first step in a method in accordance with the present invention in which trenches are etched in a carrier wafer to form pedestals; 
       FIG. 4  illustrates a further step to the method from  FIG. 3 , in which an SiO 2  cladding is applied to a MgO doped LN transmissive wafer prior to joining the two wafers; 
       FIG. 5  illustrates a further step to the method from  FIG. 4 , in which adhesive is introduced to the space between the wafers by wicking; 
       FIG. 6  illustrates a further step to the method from  FIG. 5 , in which the MgO doped LN transmissive wafer is thinned; 
       FIG. 7  illustrates a further step to the method from  FIG. 6 , in which trenches are etched into the thinned MgO doped LN wafer to form ridge waveguides; 
       FIG. 8  illustrates a further step to the method from  FIG. 7 , in which a cladding coating of SiO 2  is deposited over the etched MgO doped LN wafer; 
       FIG. 9  is a cross-section of another embodiment of the ridge waveguide device in accordance with the present invention, in which the ridge waveguides are formed on the joining surface of the transmissive wafer with pedestals in the carrier wafer aligned on the dicing streets, prior to dicing from the assembled wafer structure; 
       FIG. 10  is cross-section of a portion of the waveguide device of  FIG. 9 ; 
       FIG. 11  is a further embodiment of the waveguide device of the present invention, in which pedestals of SiO 2  on the joining surface of the transmissive wafer surround each ridge waveguide of the device; 
       FIG. 12  illustrates a first step in a alternative method in accordance with the present invention in which trenches are etched in the joining surface of a MgO doped LN transmissive wafer to form ridge waveguides; 
       FIG. 13  illustrates a further step to the method from  FIG. 12 , in which an SiO 2  cladding layer is deposited over the joining surface of the transmissive wafer; 
       FIG. 14  illustrates a further step to the method from  FIG. 13 , in which the SiO 2  cladding layer is etched back without removing the cladding from the ridge waveguide areas; 
       FIG. 15  illustrates a further step to the method from  FIG. 14 , in which the joining surface of the transmissive wafer is joined to a joining surface of the carrier wafer showing the interstices formed by the pedestals of remaining SiO 2  cladding; 
       FIG. 16  illustrates a further step to the method from  FIG. 15 , in which adhesive is introduced into the interstices by wicking; 
       FIG. 17  illustrates a further step to the method from  FIG. 16 , in which the MgO doped LN transmissive wafer is thinned on its exterior surface; 
       FIG. 18  illustrates a further step to the method from  FIG. 17 , in which a cladding layer of SiO 2  is deposited on the exterior surface of the transmissive wafer; 
       FIG. 19  is a cross-section of an assembled wafer structure including a carrier wafer and a transmissive wafer with pedestals surrounded by adhesive between them. 
   

   DETAILED DESCRIPTION 
   Second harmonic generation is a commonly practiced technique for obtaining coherent light at short wavelengths from long wavelength laser sources. It is a non-linear process where an optical beam, called the pump beam, interacts with an optically non-linear medium, in the case of second harmonic generation, to generate a second harmonic beam, where the frequency of the second harmonic beam is twice the frequency of the pump beam. Equivalently, the free space wavelength of the second harmonic is half the free space wavelength of the pump. Any material which lacks inversion symmetry can be used as the optically non-linear medium for second harmonic generation. Materials which are commonly used include lithium niobate, MgO-doped lithium niobate and KTP (KTiOPO 4 ). Second-harmonic generation is one of a class of methods, known collectively as non-linear frequency mixing, which employ similar ridge waveguide optical structures to generate or amplify coherent light at a desired wavelength from light at an input, or from a pump. 
     FIG. 1  is a cross section illustrating a completed ridge waveguide assembly  10  (prior to dicing from the wafer) manufactured in accordance with the present invention. In this embodiment multiple ridge waveguides  30 , in this case  11 , are formed on a single chip. Each waveguide  30  has a slightly different conversion wavelength, which increases the probability that a ridge waveguide  30  with the correct conversion wavelength lies within the device. The waveguides are designed to operate at a specified laser input and output wavelength. The acceptance bandwidth of the waveguide is narrow, and small deviations of the waveguide dimensions can shift the operating center wavelength (CWL) too far from the specified laser input wavelength. Dimensional variation due to processing can be compensated by forming several adjacent waveguides on one device. Each ridge waveguide  30  within the device  10  may have slightly different lateral dimensions, or include a periodically-poled region of slightly different period. The conversion wavelength of each ridge waveguide  30  is measured, and the suitable waveguides are identified. Hence, the use of multiple, slightly different, ridge waveguides  30  improves the manufacturing yield. 
   As shown in  FIG. 1 , the ridge waveguide device  10  comprises a carrier wafer  12  and a transmissive layer  14  of optically non-linear material each having a joining surface secured by an adhesive layer  16 . The transmissive layer  14 , as mentioned above is an optically non-linear material such as lithium niobate, MgO doped lithium niobate, or KTP. The carrier wafer  12  is preferably a material having a coefficient of thermal expansion (CTE) very close to that of the transmissive layer  14 , in all directions. The carrier wafer  12  is polished to a surface parallelism within 0.005 microns. A preferred assembly includes a lithium niobate carrier wafer  12  and MgO doped lithium niobate transmissive layer  14 . The carrier wafer  12  is etched with wide trenches  18  (see  FIG. 3 ) leaving pedestals  20  along the dicing streets. The tops of the pedestals  20  retain the reference plane of the polished carrier wafer  12 . Pedestals  20  can be narrow such that they will be removed by the dicing saw; alternatively, they can be wide enough that pedestals remain in the diced devices. The trench depth is approximately 1 micron. Thus the pedestal height of 1 micron controls the adhesive layer  16  in the trench  18  to this thickness, while the transmissive wafer  14  is supported by the tops of the pedestals  20  on the reference plane of the carrier wafer  12 . Alternatively, as can be seen more clearly in the enlarged section of the embodiment  11  illustrated in  FIG. 2 , the adhesive layer  16  is interrupted by a plurality of pedestals  20  within the device, which are not removed by dicing. The pedestals  20  are constructed of a hard, dense material which forms a solid relief structure in direct contact with the wafers  12 , 14 . Adhesive is introduced into the interstices between the wafers  12 , 14  and surrounding the pedestals  20 . Pedestals  20  can be formed by etching trenches  18  from the surface of the carrier wafer  12  through a photomask. Alternatively, pedestals  20  can be formed by depositing a highly uniform, thin layer onto the joining surface  13  of the carrier wafer  12 , or the joining surface  15  of the transmissive wafer  14 . This deposited layer is etched back to create a relief pattern of pedestals  20  into which adhesive can be introduced, by wicking or pressing for example. The deposited layer is applied through a shadow mask or a photolithography mask to create a relief pattern of pedestals  20 . Alternatively the pedestals  20  can be formed by deposition over a patterned photo resist and subsequent lift-off. 
   Preferably the pedestals  20  are formed of a deposited layer which is of a material selected to be differentially etchable to the carrier wafer. For example, an SiO 2  or Ta 2 O 5  layer is easily chemically etched and lithium niobate acts as an etch stop. In addition, it is advantageous if the deposited layer is selected from a material optically similar to the adhesive, as this simplifies the thickness metrology. Most oxide dielectrics are suitable, as are durable metals such as Cr, Ni and Ti/W. A precise uniform layer can be applied by physical vapor deposition (PVD) including sputtering, electron beam, ion assisted, or atomic layer deposition, for example. Chemical vapor deposition (CVD) techniques are also sufficient, such as plasma enhanced CVD. For manufacturing tolerances, deposited pedestals  20  must have a height uniformity of 0.05 microns and preferably within 0.01 microns. 
   The relief pattern preferably creates continuous channels open at either end to facilitate adhesive wicking. Alternatively adhesive may be introduced on one or both joining surfaces  13 , 15  prior to assembly, subsequently pressure is applied to bring the joining surfaces into contact with the pedestals  20 .  FIG. 2  illustrates a narrow pedestal  20  between each ridge waveguide  30  on the device  11 , while  FIG. 1  shows wide pedestals  20  only at the periphery of the device  10 , where a dicing saw will cut the assembly into individual devices. The wide pedestals can be designed to be completely removed by the dicing saw, or to remain in the finished device. Furthermore, a device can contain either narrow or wide pedestals or both. One benefit of leaving the pedestals in the periphery of the final device is to reduce the outgassing rate of the adhesive. This is of particular interest for device lifetime reasons in hermetic packages. Pedestals also contribute to a more dimensionally stable structure that resists slumping which might disrupt waveguide alignment over time. 
   The optical properties of the joining layer do not affect the optical function of the waveguide device. The adhesive may be amorphous or crystalline, may be transparent, scattering or opaque and may have any refractive index and absorption coefficient. A preferred adhesive is low viscosity, particle-free, cures without evolving gasses, has low shrinkage, low stress, is capable of withstanding subsequent processing steps and is permanent. An example of a preferred adhesive includes UV15LV, from MasterBond 
   The wafer scale process according to the present invention can produce approximately 200 devices depending on the waveguide design, over a 3 inch wafer, in the same production time and energy consumption as current processes expend on a single device. Furthermore, the devices manufactured according to the wafer scale process of the present invention have a number of advantages over the prior art as discussed above. 
     FIGS. 3-8  illustrate a first method in accordance with the present invention. In accordance with the first method as shown in  FIG. 3 , a lithium niobate carrier wafer  12  is polished to have a surface parallelism within 0.005 microns, and preferably within 0.001 microns. The carrier wafer  12  is patterned and etched to form broad shallow trenches  18  in the joining surface  13  leaving pedestals  20  between them. The trenches  18  are between 0.5 microns and 5 microns deep, preferably 1.0 microns deep. The carrier wafer  12  is preferably congruent lithium niobate of the same crystal orientation as the MgO-doped lithium niobate waveguide layer, a material of lower cost than the waveguide layer, and readily available in all size wafers. The pedestals  20  can be located between each ridge waveguide  30  or located only at the perimeter of each device  10 , as shown in  FIG. 1 . Adding pedestals  20  between ridge waveguides  30  improves the control of the waveguide layer reference to the carrier wafer surface. However, increasing the number of pedestals  20  does reduce the surface area of adhesive, reducing the strength of the adhesive bond. Thus, the relief pattern of pedestals must balance these factors. The level of accuracy of the present invention is controlled across wafers of up to  3  inch diameter, and can be applied to larger wafers. 
   In  FIG. 4 , a thick Mg-doped lithium niobate wafer  14 , surface coated with an appropriate cladding material  22 , such as SiO 2  on the joining surface  15 , is contacted to the joining surface  13  of the carrier wafer  12 . The surfaces need to be clean and particle-free. External uniform pressure is preferably applied The bottom SiO 2  coating  22  can be eliminated if the pedestals  20  are not underneath a ridge waveguide  30 , though the SiO 2  coating may improve adhesion of the assembly. In  FIG. 5 , adhesive  16  is wicked into the gap created by the pedestals  20 . The use of a cladding layer  22  eliminates any optical property specification for the adhesive material. 
   In  FIG. 6 , the MgO-doped lithium niobate material  14  is thinned, preferably by optical lap grinding and polishing, but could be thinned by etching such as Reactive-Ion-Etching (RIE). After thinning, trenches  28  are formed into the thinned lithium niobate layer  14 , as shown in  FIG. 7 . For exampled trenches may be formed via Reactive Ion Etching (RIE) or with laser milling. The layer of lithium niobate remaining underneath these etched trenches  28  is called the planar slab region  26 . The thinned and etched lithium niobate layer  14  can have a coating  24  applied, as shown in  FIG. 8 . The top coating  24  is optional. It protects the surface of the thinned lithium niobate layer  14  from contamination. The top coating  24  acts as a cladding, as well as, reducing the effect of contaminants on the operational characteristics of the device  10 . The coating  24  may also include some conductivity, to dissipate pyroelectric generated charge. 
   Reactive Ion Etching in an inductively coupled plasma (ICP-RIE) is a preferred method for etching trenches  28 . It comprises a method to chemically impose a topographical change in the surface of the waveguide layer  14 . When the topography consists of trenches narrowly spaced, the waveguide  30  is formed by removing material on both sides of a narrow ridge. When the ridge is formed to the requisite width and height above the lower cladding layer  22 , the ridge becomes a waveguide  30 . ICP-RIE is not a mechanical working process. 
     FIGS. 9-11  show preferred embodiments of the frequency doubling device  100 , where the ridge waveguides  130  are upside down. The planar slab region  126  is above the ridge  130 , instead of underneath it. The carrier wafer  112  is still beneath the ridge  130 , as it was in  FIGS. 1-8 . In  FIGS. 9 and 10 , the adhesive layer  116  is continuous underneath all the ridges  130 . As in  FIG. 1 , the carrier wafer  112  is etched to create wide trenches  118  separated by pedestals  120 . As shown in  FIG. 9 , these are centered on the dicing streets. Thus the pedestals  120  do not show in the diced chip shown in  FIG. 10 .  FIG. 11  shows a second version of the upside down ridge, where the adhesive layer is not continuous across the width of the device. For this embodiment, the SiO 2  cladding layer  124  is etched beyond the waveguiding area, including the ridge  130  and the slab region  126  above the trenches  128 , to form a relief pattern comprising the pedestals  120  needed to control the adhesive thickness. Additional efficiency is realized in forming the pedestals  120  from the cladding layer  124 . 
     FIGS. 12-18  describe the fabrication process for this second version of the upside down ridge  100 . In  FIG. 12 , trenches  128  are etched into surface of an MgO-doped LN wafer  114 . In this case in the joining surface  115 . The orientation of the wafer  114  shows the trenches  128  to be on the bottom, simply to be consistent with the following figures. In  FIG. 13 , an SiO 2  coating  124  is applied over the trenches  128  and ridges  130 . In  FIG. 14 , the SiO 2  coating is removed in certain regions, forming pedestals  120  needed for controlling the adhesive thickness. 
   In  FIG. 15 , the MgO-doped lithium niobate wafer  114  is contacted with a carrier wafer  112 , preferably a congruent lithium niobate wafer. In  FIG. 16 , adhesive  116  is introduced into the gap created by the patterned SiO 2  coating pedestals  120  and the trenches  128  that form the ridges  130 . In  FIG. 17 , the MgO-doped lithium niobate material  114  is thinned by polishing or etching. An optional top coating  122  of SiO 2  is applied in  FIG. 18 . As before, the top coating  122  acts as a cladding, protects the surface of the thinned LN layer from contamination, and may also include some conductivity, to dissipate pyroelectric generated charge. 
   Tolerances in the method of the present invention to achieve wafer scale yield across a 4″ wafer must result in finished devices having a thickness variation in the waveguide layer of within 0.5 microns, and preferably within 0.1 microns. To obtain this, the carrier wafer must have a surface parallelism equal to the finished tolerance of 0.5 microns or better, and a deposited pedestal height must have a uniformity within 0.05 microns and preferably within 0.01 microns. 
   In this preferred embodiment, waveguide reliability and fabrication yield are improved by means of a substrate that is electrically conducting. Previous descriptions of the waveguide device use ferroelectric material for the waveguide (such as lithium niobate) and essentially the same material for the substrate, in order to optimally match the CTE of waveguide forming layer and substrate. CTE matching minimizes or eliminates thermally induced strain in the waveguide, thereby improving its wavelength stability and long term reliability. 
   Once the completed wafer assembly is diced, endfaces of the individual ridge waveguide devices are polished to laser quality level. Anti-reflective coatings for the input and output wavelengths may be applied as required to enhance coupling efficiency 
   The wafer scale process, illustrated generally by the wafer assembly shown in  FIG. 19 , is a method of adhesively securing a wafer of optically transmissive material  14  to a carrier wafer  12  having a parallelism within 0.5 microns, more preferably within 0.1 microns and accurately transferring that surface information to the joining surface  15  of the transmissive wafer  14 . Thus a very thin optical waveguiding layer can be created with a thickness variation of within 0.1 micron. This is accomplished by creating a relief pattern by etching into the joining surface  13  of the carrier wafer  12  to create a space  18  into which to introduce adhesive while placing the transmissive wafer  14  in direct contact with the reference surface  13  of the carrier wafer  12 . Alternatively, the relief pattern is created by depositing a uniform layer over the joining surface  13 ,  15  of the carrier wafer  12  or the transmissive wafer  14  through a shadow mask or photolithographic mask; or by depositing a uniform layer over a patterned photo resist and subsequent lift-off. The pedestals  20  left standing in the relief pattern have a uniform height, within 0.1 microns, which transfer the surface information from the carrier wafer  12  to the joining surface  15  of the transmissive wafer  14 . 
   This method can be used in wafer scale production of planar lightwave circuits (PLC) with highly uniform dimensions. Alternatively, this method can be used in wafer scale manufacture of electro-optic waveguide devices with very thin indiffused waveguides to reduce voltage requirements. 
   The embodiments of the invention described above are intended to be exemplary only. The scope of the invention is therefore intended to be limited solely by the scope of the appended claims.