Abstract:
The present invention is an apparatus for integrating multiple devices. The apparatus includes a substrate having a first via and a second via, a semiconductor chip positioned on a top portion of the substrate and positioned between the first via and the second via, first and second bumps positioned on the semiconductor chip, and an interposer wafer having a first interposer spring assembly and a second interposer spring assembly, the first interposer spring assembly having a first interposer spring and a first electrical connection attached to the first interposer spring, and the second interposer spring assembly having a second interposer spring and a second electrical connection attached to the second interposer spring.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of application Ser. No. 12/751,980, now U.S. Pat. No. 8,154,119, entitled “Compliant Spring Interposer for Wafer Level Three Dimensional (3D) Integration and Method of Manufacturing,” filed on Mar. 31, 2010, which is assigned to the assignee hereof and hereby expressly incorporated by reference herein. 
    
    
     FIELD 
     The invention relates to an interposer module that bridges chips (or wafers) to a substrate and routes interconnection lines. More particularly, the invention relates to a compliant spring interposer for wafer level three dimensional (3D) integration and method of manufacturing the same. 
     BACKGROUND 
     An interposer module (also called an interposer wafer) is used to bridge or connect multiple devices, chips or wafers to a substrate. Designing an interposer module is difficult because the interposer module needs to account for different sized and shaped devices having different topologies. Heterogeneous integration requires the interposer module to incorporate different sized and shaped devices that generally have different topologies. For example, the difference in device heights makes the design of the interposer module challenging because the designer needs to adjust the vertical topology of the interposer module to be exactly matched with the device heights. This requires accurate control of the fabrication process. 
     In addition, the interposer module has limits in selecting bonding methods and requires multiple bonding. Heterogeneous integration generally requires multiple bonding processes. The bonding process becomes more frequent as the number of devices increases. The difficulty becomes more challenging when the devices are stacked in a three-dimensional (3D) orientation. 
     Existing interposer modules have several drawbacks. For example, the different device topologies have different device heights making it difficult to properly integrate the devices. To modulate the different heights, prior methods involved stacking bump materials or using bonding methods that compress bonding material. However, both methods are difficult because these methods do not allow for accurate control of the fabrication process. Furthermore, even though the device topologies for integration can be adjusted or involves identically designed devices, the device topologies can be diverse because of fabrication variations. This diversity cannot be controlled and the process should be designed to compensate for the unpredictable difference in wafer surface profile, material deposition thickness, material etching rate, wafer bowing, etc. 
     Another drawback is the number of different bonding processes required for the different devices. Typically, as the number of devices increase, so does the number of bonding processes. The multiple bonding processes involve different bonding steps, materials and conditions such as temperature, pressure, voltage, etc. The sequence of bonding processes should be carefully designed and controlled so that latter bonding methods do not damage former bonding materials and former bonding methods do not generate any issues to disturb the latter bonding conditions. The multiple bonding processes also generate several thermal cycles, which can produce problems such as device stress, wafer bowing, material oxidation, inter-material reaction, outgasing, and material damages. 
     In some situations, the devices need to be encapsulated to protect them from damage or contamination created by dust, debris, particles, humidity or chemicals. Some applications need a hermetically sealed vacuum package to improve device performance and reliability. These goals are generally achieved by employing additional wafers that cap the devices, which, however, increase fabrication complexity and cost and produce yield problems. 
     The above drawbacks provide challenges to designers of interposer modules. Thus, there is a need for an interposer module that overcomes the above drawbacks. 
     SUMMARY 
     In one embodiment, the present invention is an apparatus for integrating multiple devices. The apparatus includes a substrate having a first via and a second via, a semiconductor chip positioned on a top portion of the substrate and positioned between the first via and the second via, first and second bumps positioned on the semiconductor chip, and an interposer wafer having a first interposer spring assembly and a second interposer spring assembly, the first interposer spring assembly having a first interposer spring and a first electrical connection attached to the first interposer spring, and the second interposer spring assembly having a second interposer spring and a second electrical connection attached to the second interposer spring. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The features, objects, and advantages of the invention will become more apparent from the detailed description set forth below when taken in conjunction with the drawings, wherein: 
         FIG. 1A  is a cross-sectional view of a device and an apparatus that incorporates interposer technology where the apparatus is spaced apart from the device according to an embodiment of the invention; 
         FIG. 1B  is a cross-sectional view of a device and an apparatus that incorporates interposer technology where the apparatus is bonded to the device according to an embodiment of the invention; 
         FIG. 1C  is a cross-sectional view of a device and an apparatus that incorporates interposer technology where the first and second interposer springs are not bonded to but are touching the first and second TSVs and the first and second bumps located on the chip of the device according to an embodiment of the invention; 
         FIG. 2  is a chart of several bonding materials and their corresponding bonding process according to an embodiment of the invention; 
         FIGS. 3A-3F  are cross-sectional views of a device and an apparatus that incorporates interposer technology according to an embodiment of the invention; and 
         FIGS. 4A and 4B  are cross-sectional views of a device and an apparatus that incorporates interposer technology according to an embodiment of the invention. 
     
    
    
     DETAILED DESCRIPTION 
     Apparatus, systems and methods that implement the embodiments of the various features of the invention will now be described with reference to the drawings. The drawings and the associated descriptions are provided to illustrate some embodiments of the invention and not to limit the scope of the invention. Throughout the drawings, reference numbers are re-used to indicate correspondence between referenced elements. 
       FIG. 1A  is a cross-sectional view of a device  101  and an apparatus  100  that incorporates interposer technology where the apparatus  100  is spaced apart from the device  101  according to an embodiment of the invention. The apparatus  100  may be positioned on the device  101  as shown in  FIG. 1B . The device  101  may include a substrate  102  or a through-silicon via (TSV) wafer  102 , first and second TSVs  104   a  and  104   b , a chip  106 , first and second bumps  108   a  and  108   b , and/or first and second lower outer bond rings  110   a  and  110   b . The first and second bumps  108   a  and  108   b  may provide electrical connections to the underlying chip  106 . The first and second lower outer bond rings  110   a  and  110   b  may be a single lower outer bond ring. As shown in  FIG. 1A , the heights of the first and second TSVs  104   a  and  104   b , the first and second bumps  108   a  and  108   b , and the first and second lower outer bond rings  110   a  and  110   b  are different. 
     The first and second TSVs  104   a  and  104   b  are vertical electrical connections which pass completely through the TSV wafer  102 . The chip  106  is mounted on the TSV wafer  102 . The first and second TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  may be flat or curved and/or flexible. The first and second bumps  108   a  and  108   b  may be bonded to the chip  106 . 
     The apparatus  100  may include an interposer wafer  112 , a cap  114 , first and second upper outer bond rings  116   a  and  116   b , a first interposer spring assembly  117   a  having a first interposer spring  118   a  and a first electrical connection  120   a , and a second interposer spring assembly  117   b  having a second interposer spring  118   b  and a second electrical connection  120   b . In one embodiment, the first and second interposer springs  118   a  and  118   b  are cantilevered springs or interposer beams. The first and second interposer springs  118   a  and  118   b  may be formed in the shapes of a cantilevered bridge L shape or curved shape or crab leg shape and are made from a ceramic, a silicon, a metal or a glass material and combinations thereof. The downward force  122  exerted on each interposer spring  118   a  or  118   b  is greater than the bending force of each interposer spring  118   a  or  118   b  and less than the fracture force of each interporser spring  118   a  or  118   b . The minimum downward force  122  can also be greater than the bonding force needed to bond the first upper outer bonding ring  116   a  to the first lower outer bonding ring  110   a . The first and second upper outer bond rings  116   a  and  116   b  may be a single upper outer bond ring. 
     The apparatus  100  may be referred to as a compliant interposer. The apparatus  100  can be separately fabricated from the device  101 . Thus, the design and fabrication processes for the apparatus  100  can be simplified and decoupled from the device  101 . In addition, the apparatus  100  (i.e., the interposer wafer) can be used as a cap  114  or a cover to protect the device  101  from contamination such as dust, debris or particles. The first and second upper outer bond rings  116   a  and  116   b  may be hermetically bonded to the first and second lower outer bond rings  110   a  and  110   b  to produce a hermetically packaged apparatus or chip. 
       FIG. 1B  is a cross-sectional view of the device  101  and the apparatus  100  that incorporates interposer technology where the apparatus  100  is bonded to the device  101  according to an embodiment of the invention. As shown in  FIG. 1B , the first interposer spring assembly  117   a  and the second interposer spring assembly  117   b  may gradually bend when each assembly  117   a  and  117   b  comes into contact with the first and second TSVs  104   a  and  104   b , the first and second bumps  108   a  and  108   b  located on the chip  106  and/or the first and second lower outer bond rings  110   a  and  110   b . The bending allows the apparatus  100  to accommodate for the height differences of the components of the device  101  and to provide for good bonding and mechanical and electrical connections. 
     The first electrical connection  120   a  is mechanically connected to the first interposer spring  118   a . The first interposer spring  118   a  is capable of bending to allow the first electrical connection  120   a  to electrically contact the first TSV  104   a  and the first bump  108   a , which is connected to the chip  106 . Similarly, the second electrical connection  120   b  is connected to the second interposer spring  118   b . The second interposer spring  118   b  is capable of bending to allow the second electrical connection  120   b  to electrically contact the second TSV  104   b  and the second bump  108   b , which is connected to the chip  106 . The first and second interposer springs  118   a  and  118   b  provide an electrical and mechanical bridge to connect the first and second TSVs  104   a  and  104   b  to the first and second bumps  108   a  and  108   b  on the chip  106 . A larger bonding pressure  122  can be applied to the interposer wafer  112 , which is transferred to the TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b , because of the flexibility and bending force of the first and second interposer springs  118   a  and  118   b.    
     The first and second electrical connections  120   a  and  120   b  are in direct mechanical and electrical contact with the first and second TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  located on the chip  106 . Specifically, the first electrical connection  120   a  connects the first TSV  104   a  to the first bump  108   a  and the second electrical connection  120   b  connects the second TSV  104   b  to the second bump  108   b.    
     The bonding pads (e.g., the first and second TSVs  104   a  and  104   b , the first and second bumps  108   a  and  108   b , and/or the first and second lower outer bond rings  110   a  and  110   b ) are designed to provide good electrical connections and to withstand large bending pressures provided by the interposer wafer  112 . The first and second TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  may have a flat or curved surface, or may be formed in the shape of a square, rectangle or oval and/or may be made of a flexible material to allow for good connections to the first and second electrical connection  120   a  and  120   b  and to avoid any open connections across the TSV wafer  102 . The good connections are achieved by adjusting or controlling the height of the bonding pads and/or by utilizing compliant and conductive materials such as soft metals like gold, silver, tin, aluminum or copper. The compliant and conductive materials should not be oxidized and should be chemically stable during processing. For example, copper may quickly become oxidized after deposition but can be encapsulated or plated with a less-oxidizing material such as gold. Hence, the bonding pads can be encapsulated or plated with a less-oxidizing material. Also, the compliant and conductive material should be able to sustain high pressures from the first and second interposer springs  118   a  and  118   b , which may induce cracks or fractures. 
     After the apparatus  100  is pressed onto the device  101 , all the TSVs  104   a  and  104   b , the first and second bumps  108   a  and  108   b , the first and second interposer springs  118   a  and  118   b , the first and second electrical connections  120   a  and  120   b , the lower outer bond rings  110   a  and  110   b , and the upper outer bond rings  116   a  and  116   b  are simultaneously bonded together in a single bonding step. Hence, all the components are fixed and bonded together at the same time to limit the number of bonding materials, minimize misalignment of the components, reduce the complexity of the fabrication process and increase the reliability of the apparatus  100  after the single step bonding process. The single bonding step includes the appropriate bonding conditions such as temperature, pressure and/or voltage. 
       FIG. 2  is a chart of several bonding materials and their corresponding bonding process according to an embodiment of the invention. In one embodiment, the bonding process can be set up so that each component bonds one after another. In this embodiment, a different bonding material or process is used for each component.  FIG. 2  shows several different bonding materials and processes that can be used for each of the components to produce a bonding process where each component may bond one after another (i.e., in a sequential manner). For example, a sequential bonding process can occur by increasing the bonding temperature from 200 degrees C. to 300 degrees C. so that a first Gold-Indium bond occurs between the lower outer bond rings  110   a  and  110   b  and the upper outer bond rings  116   a  and  116   b , a second Silver-Tin bond occurs between the TSVs  104   a  and  104   b  and the first and second interposer springs  118   a  and  118   b , and a third Nickel-Tin bond occurs between the first and second bumps  108   a  and  108   b  and the first and second interposer springs  118   a  and  118   b . In this example, the highest bonding temperature of 300 degrees C. does not damage the first Gold-Indium bond because of a higher remelt temperature of greater than 495 degrees C. Using a sequential bonding process, the selection of the bonding materials and processes is important so that previously bonded materials are not damaged by subsequent bonding materials in order to maintain good quality bonding. 
       FIG. 1C  is a cross-sectional view of a device  101  and an apparatus  100  that incorporates interposer technology where the first and second interposer springs  118   a  and  118   b  are not bonded to but are touching the first and second TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  located on the chip  106  of the device  101  according to an embodiment of the invention. When the apparatus  100  is pressed onto the device  101 , the TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  are mechanically and electrically connected using the first and second interposer springs  118   a  and  118   b  and the upper outer bond rings  116   a  and  116   b  are bonded to the lower outer bond rings  110   a  and  110   b.    
     When the apparatus  100  is spaced apart from (i.e., not touching) the device  101 , the first and second interposer springs  118   a  and  118   b  are positioned along a horizontal plane (see  FIG. 1A ). When the apparatus  100  is touching the device  101 , the first and second interposer springs  118   a  and  118   b  are bent in an upward direction (see  FIG. 1C ). As shown in  FIG. 1C , the upper outer bond rings  116   a  and  116   b  are bonded to the lower outer bond rings  110   a  and  110   b  causing the first and second interposer springs  118   a  and  118   b  to bend. However, the first and second interposer springs  118   a  and  118   b  only slightly compress the TSVs  104   a  and  104   b  and the first and second bumps  108   a  and  108   b  to make the mechanical and electrical connections. In one embodiment, the mechanical and electrical connections are maintained only by the bending force  124  from the first and second interposer springs  118   a  and  118   b  and the bonding strength between the upper outer bond rings  116   a  and  116   b  and the lower outer bond rings  110   a  and  110   b . The single bonding between the upper outer bond rings  116   a  and  116   b  and the lower outer bond rings  110   a  and  110   b  is advantageous because of the single bonding material and process resulting in a greater reliability, a simpler fabrication process, and a lower production cost. In one embodiment, the first and second interposer springs  118   a  and  118   b  are designed to provide a sufficient bending force and are not damaged by excessive bending stress. 
     In one embodiment, only the lower outer bond rings  110   a  and  110   b  and the upper outer bond rings  116   a  and  116   b  are bonded together. The remaining components (i.e., the TSVs  104   a  and  104   b  and the first and second interposer springs  118   a  and  118   b , and the first and second bumps  108   a  and  108   b  and the first and second interposer springs  118   a  and  118   b ) are not bonded together but are touching one another. 
       FIGS. 3A-3F  are cross-sectional views of a device  301  and an apparatus  300  that incorporates interposer technology according to an embodiment of the invention. The device  301  includes a substrate  302  and a plurality of chips  306 ,  307  and  309  that are mounted on the substrate  302 . The substrate  302  may also be a TSV wafer or a second interposer wafer. 
     The device  301  may include a substrate  302  or a TSV wafer  302 , first and second TSVs  304   a  and  304   b , chips  306 ,  307  and  309 , first and second bumps  308   a  and  308   b  located on the chip  306 , first and second bumps  308   c  and  308   d  located on the chip  307 , first and second bumps  308   e  and  308   f  located on the chip  309 , upper bonding pads  316   a  and  316   b  and/or lower bonding pads  310   a  and  310   b . The first and second bumps  308   a  and  308   b  (or  308   c  and  308   d  or  308   e  and  308   f ) may provide electrical connections to the underlying chip  306  (or  307  or  309 ). As shown in  FIG. 3A , the heights or thickness of the chips  306 ,  307  and  309  are different. In one embodiment, the chips  307  and  309  have the same design but have slightly different heights or thicknesses because of fabrication variations. The bonding pads  320   a ,  320   b ,  320   c ,  320   d ,  320   e  and  320   f  on the interposer springs  318   a ,  318   b ,  318   c ,  318   d ,  318   e  and  318   f , respectively, are mechanically and electrically connected to the upper bonding pads  310   b  and  316   b . After the upper bonding pads  316   a  and  316   b  are bonded to the lower bonding pads  310   a  and  310   b , the bonding pads  320   a ,  320   b ,  320   c ,  320   d ,  320   e  and  320   f  are connected to the bumps  308   a ,  308   b ,  308   c ,  308   d ,  308   e  and  308   f , respectively, and the TSVs  304   a  and  304   b  on the substrate  302 . 
     The first and second TSVs  304   a  and  304   b  are vertical electrical connections which pass completely through the substrate  302 . The chips  306 ,  307  and  309  are mounted on the substrate  302 . The bumps  308   a ,  308   b ,  308   c ,  308   d ,  308   e  and  308   f  may be flat, square, curved, round, oval and/or flexible. The first and second bumps  108   a  and  108   b  may be bonded to the chip  106 . 
     The apparatus  300  may include a spring interposer wafer  312 , first and second upper bonding pads  316   a  and  316   b , and a plurality of interposer springs  318  connected to a plurality of bonding pads  320 . In one embodiment, the plurality of interposer springs  318  are each a cantilevered spring. 
     By applying the bonding pressure  322 , the bonding pads successively touch the bumps on the chips or the TSVs. The differences in heights or thicknesses of the chips  306 ,  307  and  309  causes the bonding pads  320  to touch the bonding pads  308  at different times. First, the bonding pads  320   a  and  320   b  touch the bonding pads  308   a  and  308   b  (see  FIG. 3B ). Second, the bonding pads  320   c  and  320   d  touch the bonding pads  308   c  and  308   d  (see  FIG. 3C ). Third, the bonding pads  320   e  and  320   f  touch the bonding pads  308   e  and  308   f  (see  FIG. 3D ). Fourth, the upper bonding pads  316   a  and  316   b  touch the lower bonding pads  310   a  and  310   b  (see  FIG. 3E ). Due to the compliance of the interposer springs  318 , the spring interposer wafer  312  can move downwards, even though some of the bonding pads  320  are touching the bonding pads  308 , until the upper bonding pads  316   a  and  316   b  come into contact with the lower bonding pads  310   a  and  310   b  (see  FIG. 3E ). Then, the appropriate bonding conditions (e.g., temperature, additional pressure, voltage, etc.) are applied to the combined structure shown in  FIG. 3E  and all the components (i.e., the chips  306 ,  307  and  309 , the TSVs  304   a  and  304   b , and the interposer springs (collectively referred as interposer springs  317 )) are simultaneously bonded to form the final structure as shown in  FIG. 3F . 
     The bonding conditions may be applied one time or several times depending on the particular application. For example, a different bonding process may be used for chip bonding and TSV bonding. In this example, a first bonding condition may be applied for chip bonding at the step shown in  FIG. 3D  and a second bonding condition may be applied for TSV bonding at the step shown in  FIG. 3E . In one embodiment, only a single bonding can take place, for example, between the upper bonding pads  316   a  and  316   b  and the lower bonding pads  310   a  and  310   b . The interposer springs  317  are designed to be flexible to provide sufficient bonding force without damaging the bonding pads  308 . 
       FIGS. 4A and 4B  are cross-sectional views of a semiconductor device  401  and an apparatus  400  that incorporates interposer technology according to an embodiment of the invention.  FIGS. 4A and 4B  show interposer springs  418   a ,  418   b ,  418   c  and  418   d  that are initially tilted or bowed to provide a larger bending force between the interposer springs  418   a ,  418   b ,  418   c  and  418   d  and the bumps  408   a ,  408   b ,  408   c  and  408   d  and/or the TSVs  404   a  and  404   b . The interposer springs  418   a ,  418   b ,  418   c  and  418   d  can be tilted or bowed by initiating thermal stress, generating material property mismatches, or applying external forces such as electrostatic or magnetic forces. Each interposer spring  418   a ,  418   b ,  418   c  and  418   d  may have a corresponding bonding pad  420   a ,  420   b ,  420   c  and  420   d  attached thereto. 
     Those of ordinary skill would appreciate that the various illustrative logical blocks, modules, and algorithm steps described in connection with the examples disclosed herein may be implemented as electronic hardware, computer software, or combinations of both. To clearly illustrate this interchangeability of hardware and software, various illustrative components, blocks, modules, circuits, and steps have been described above generally in terms of their functionality. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the overall system. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the disclosed apparatus and methods. 
     The previous description of the disclosed examples is provided to enable any person of ordinary skill in the art to make or use the disclosed methods and apparatus. Various modifications to these examples will be readily apparent to those skilled in the art, and the principles defined herein may be applied to other examples without departing from the spirit or scope of the disclosed method and apparatus. The described embodiments are to be considered in all respects only as illustrative and not restrictive and the scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.