Patent Document

FIELD OF THE INVENTION 
     The present invention relates generally to integrated circuits, and more specifically to electrical fuse (“eFUSE”). 
     BACKGROUND 
     Electrically programmable fuse (eFUSE) is commonly used in integrated circuits including CMOS integrated circuits for a variety of reasons. For example, eFUSE is used to form permanent connections in an integrated circuit after the integrated circuit is manufactured. eFUSE is also used in circuit repairs, i.e., to interconnect a redundant circuit when the primary circuit fails in order to improve product yield. eFUSE can also be used as permanent memory to store information on chips such as chip ID or critical system boot codes. Additionally, eFUSE can be used to adjust the speed of a circuit by adjusting the resistance of a current path formed by the eFUSE. 
       FIG. 1A  illustrates a top view of a known eFUSE  102 .  FIG. 1B  illustrates a cross sectional view of eFUSE  102  of  FIG. 1A . eFUSE  102  has a cathode contact region  106 , an anode contact region  108 , and a fuse link  104 . Fuse link  104  interconnects cathode contact region  106  to anode contact region  108 . The fuse link  104  of eFUSE  102  has an underlying poly-silicon layer  112  and an overlying silicide layer  110 . eFUSE  102  also has an oxide layer  114  separating poly-silicon layer  112  from nitride layer  116 . Alternatively, as illustrated in  FIG. 1C , eFUSE  102  may have an underlying oxide layer  122  and overlying silicide layer  118 , separated by a silicon layer  120 . A nitride layer  124  overlays silicide layer  118 . 
     eFUSE  102  is programmed by electromigration of silicide in fuse link  104  from cathode contact region  106  to anode contact region  108 , as follows. A voltage potential is applied across fuse link  104  via anode contact region  108  and cathode contact region  106 , such that the resultant current has a magnitude and direction to initiate electromigration of silicide from the cathode contact region side of the semiconductor fuse link  104  and to create a gap in silicide, thereby reducing the conductivity of the fuse link  104 . 
     The programming of an eFUSE is sensitive to process and power supply variations. Process variations change the fuse character, such as overall resistance and sub-components resistances, and thus lead to change of the optimal programming current. Power supplies used for fuse programming may also experience variations, such as power droop, on a given product implementation, i.e. the potential variation at fuse to be programmed due to parasistic wiring resistance and leakage current in the circuits. As a result, a fuse may be programmed with either too little current or too much current which leads to undesirable outcomes. For example, the programming yield may suffer from either end. In addition, the programmed fuse may heal in subsequent manufacturing process such as test and packaging, or worse in the field which results in a failing product in service. 
       FIG. 2  illustrates an example eFUSE  202  after the eFUSE  202  has been programmed with too much current. eFUSE  202  has experienced damage  206  at cathode contact  204  resulting from over programming that partially migrated the cathode contact material, e.g., the contact liner material and contact itself. As a result, copper metal wire above the contact can be exposed and readily diffuse into the programmed fuse link when the fused part is subjected to elevated temperature, such as those during the subsequent manufacturing process. For example, a packaging process subjects eFUSE  102  to heat as high as 360° C. This renders the eFUSE back to its original pre-programmed state.  FIG. 3A  illustrates an example of a failed eFUSE  302  resulting from copper diffusing from the cathode contact  304  into fuse link  306 .  FIG. 3B  is an elemental analysis  308  of the failed eFUSE of  FIG. 3A  showing the concentration of copper  310  in the programmed fuse link  306  that electrically reconnects the cathode and anode contacts indicating a pre-programmed state. 
     In addition, the lithography used to manufacture the known eFUSE  102  is imprecise.  FIG. 4A  illustrates eFUSE design  402  having a right angle corner  410 . Physically implementing the design, however, results in rounded corners  430  as illustrated by eFUSE  450  in  FIG. 4B . Furthermore, corner rounding is highly variable. Several factors contribute to variations in corner rounding including tool focus, dosage, optical proximity correction (OPC), light wavelength, photoresist, etc. Thus, corner rounding contributes to fuse variability in terms of optimal programming condition and programming yield. 
     An object of the present invention is to improve the safety window for fuse programming through heat conduction engineering so that programming occurs at desired location, the center region of fuse link, away from the susceptible cathode contact. Another object of the present invention is to design an eFUSE to tolerate higher programming current. Another object of the present invention is to minimize the sensitivities of fuse programming to process variations such as corner rounding effect. 
     SUMMARY 
     In a first embodiment of the present invention, an electrical fuse has an anode contact on a surface of a semiconductor substrate. The electrical fuse has a cathode contact on the surface of the semiconductor substrate spaced from the anode contact. The electrical fuse has a link within the substrate electrically interconnecting the anode contact and the cathode contact. The link comprises a semiconductor layer and a silicide layer. The silicide layer extends beyond the anode contact. An opposite end of the silicide layer extends beyond the cathode contact. A silicon germanium region is embedded in the semiconductor layer under the silicide layer, between the anode contact and the cathode contact. 
     In a second embodiment of the present invention, an electrical fuse is made by dividing a silicon substrate into a first region, a second region adjacent to the first region, and a third region adjacent to the second region, using shallow trench isolation. A first recess is created in the first region and a second recess is created in the second region, using reactive ion etching. Silicon Germanium is grown in the first and second recess. The nitride layer is removed. A silicide region is formed in the first region, above the Silicon Germanium grown in the first recess. An anode contact and a cathode contact are formed in the first region adjoining the silicide. 
     In a third embodiment of the present invention, an electrical fuse is programmed by causing electrons in silicide within a fuse link of the fuse to electromigrate towards an anode contact of the fuse, away from a cathode contact. A voltage potential is applied across the fuse link, from a cathode contact of the fuse to the anode contact. The voltage potential provides a current of 3-10 mA. 
    
    
     
       BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS 
         FIG. 1A  illustrates a top view of an eFUSE according to the Prior Art. 
         FIG. 1B  illustrates a cross-sectional view of an eFUSE according to the Prior Art, taken along the plane  1 B- 1 B of  FIG. 1A . 
         FIG. 1C  illustrates another top view of an eFUSE according to the Prior Art. 
         FIG. 2  illustrates an example of a failed eFUSE according to the Prior Art. 
         FIG. 3A  illustrates another example of a failed eFUSE according to the Prior Art which had been subjected to a thermal stress after being programmed. 
         FIG. 3B  is a graph illustrating an elemental analysis of the failed eFUSE of  FIG. 3A . 
         FIG. 4A  illustrates a top view of an eFUSE according to the Prior Art. 
         FIG. 4B  illustrates a top view of an eFUSE with corner rounding according to the Prior Art. 
         FIG. 5A  illustrates a top view of an eFUSE according to one embodiment of the present invention. 
         FIG. 5B  illustrates a cross-sectional view of the eFUSE of  FIG. 5A  taken along the plane  5 B- 5 B of  FIG. 5A . 
         FIG. 6A  illustrates a top view of an eFUSE according to another embodiment of the present invention. 
         FIG. 6B  illustrates a cross-sectional view of the eFUSE of  FIG. 6A  taken along the plan  6 B- 6 B of  FIG. 6A . 
         FIG. 7A  illustrates a stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 7B  illustrates a subsequent stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 7C  illustrates a subsequent stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 7D  illustrates a subsequent stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 7E  illustrates a subsequent stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 7F  illustrates a subsequent stage in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to one embodiment of the present invention. 
         FIG. 8  illustrates an EPI silicon growth stage after the stage in  FIG. 7D  in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to another embodiment of the present invention. 
         FIG. 9  illustrates an EPI silicon growth stage after the stage in  FIG. 7D  in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to another embodiment of the present invention. 
         FIG. 10  illustrates an EPI silicon growth stage after the stage in  FIG. 7D  in the manufacture of the eFUSEs of  FIGS. 6A and 6B , according to another embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     A reliable electrical fuse is provided which offers low programming current, improved programming yield, and reduced programming damage. The benefits are realized through the engineering of local heat conduction, local electrical current density, and power distribution from the material selection and design of the fuse structure. Embodiments herein provide the fuse structure design and material selection and the method of making and programming the fuse. 
     The present invention will now be described in detail with reference to the figures.  FIG. 5A  illustrates a top view of an eFUSE  502  according to one embodiment of the present invention.  FIG. 5B  illustrates a cross-sectional view of the eFUSE  502  of  FIG. 5A  taken along the plane  5 B- 5 B of  FIG. 5A , according to one embodiment of the present invention. The eFUSE  502  has a semiconductor layer  514  and a silicide layer  510 . In one example, semiconductor layer  514  is a poly-silicon layer. In another example, semiconductor layer  514  is a crystalline silicon layer. In another example (not shown) semiconductor layer  514  is a silicon-on-insulator (SOI) layer. It should be understood that, although semiconductor layer  514  will be described as silicon hereafter in the description, semiconductor layer  514  can also be other semiconductor materials such as III-V or II-VI semiconductors. In addition, semiconductor layer  514  can be n-type doped or p-type doped or un-doped. In the example embodiment, silicide layer  510  is formed with nickel silicide although it should be understood that other similar metal silicides may be used to form silicide layer  510 . 
     The eFUSE  502  has an anode contact  506  and a cathode contact  504 . Anode contact  506  and cathode contact  504  are electrically interconnected by the silicide in fuse link  508 . Silicide layer  510  in fuse link  508  extends outwards, underneath and beyond anode contact  506  and underneath and beyond cathode contact  504 . Cathode contact  504  is larger than anode contact  506 . Both cathode contact  504  and anode contact  506  are optimally sized to prevent cathode damage during programming. For example, anode contact  506  may be 50-100 nm wide and cathode contact  504  may be 100-150 nm wide on a 40-60 nm wide fuse link  508  of eFUSE  502 . A large cathode contact  504  lowers the current density as well as lowers the resistance of the contact and thus provides some protection for eFUSE  502  from being damaged during programming A small anode contact  506  increases the overall fuse resistance and thus helps reduce the required current for programming eFUSE  502 . 
     The eFUSE  502  includes a silicon germanium (SiGe) region  512  embedded within semiconductor layer  514  under fuse link  508 . SiGe region  512  is positioned under silicide region  510 , in between cathode contact  504  and anode contact  506 . SiGe region  512  has a much lower thermal conductivity, i.e., ˜0.1 vs 1.5 (W/cm.° C.) of that of silicon and therefore keeps heat concentrated at fuse link  508  such that programming occurs at this desired location away from cathode contact  504 . Thus, SiGe region  512  protects cathode contact  504  from being damaged during programming and therefore helps improve reliability of eFUSE  502 . 
     The generally linear shape of eFUSE  502 , which is narrower and has much smaller area under the anode and cathode contacts  506  and  504  and less total mass than the Prior Art eFUSE. Thus, during programming, less heat is absorbed by cathode contact  504  and anode contact  506 , away from fuse link  508 , as compared to the Prior Art eFUSE. Because less heat is absorbed away from the fuse link  508  and more heat is trapped in the desired location for programming above SiGe of the present invention, less current is required to program eFUSE  502 . Support circuitry for delivering large current is more costly, more complex to implement, and requires more silicon space as compared to circuitry for delivering the smaller current of the present invention. Thus, linear shaped eFUSE  502  is more optimized and cost effective as compared to the Prior Art eFUSE with or without corner rounding. 
     The eFUSE  502  can also be manufactured more precisely than the known design eFUSE illustrated in  FIGS. 1A and 4A . Linear eFUSE  502  according to one embodiment of the present invention does not have any corners and is therefore not subject to the same variability as is known to Prior Art eFUSE. 
     eFUSE  502  is programmed by applying a voltage potential across fuse link  508 , from cathode contact  504  to anode contact  506 . A low programming current is used in applying the voltage potential. For a typical example, the programming current is 3-5 mA. The current (voltage potential) is applied for a short period of time. For example, the current is maintained for 1-10 micro-seconds. This results in silicide electromigrating away from silicide region  510  in fuse link  508 , towards anode contact  506 . This creates a gap in silicide region  510  such that the resistance of eFUSE  502  is changed to very high. 
       FIG. 6A  illustrates a top view of an eFUSE  602  according to another embodiment of the present invention.  FIG. 6B  illustrates a cross-sectional view of eFUSE  602  taken along the plane  6 B- 6 B of  FIG. 6A , according to another embodiment of the present invention. The eFUSE  602  has a semiconductor layer  614  and a silicide layer  610 . The eFUSE  602  includes a silicon germanium (SiGe) region  612  embedded within semiconductor layer  614  of fuse link  608  to promote fuse programming at this location as described in the embodiment of  FIGS. 5A  and  5 B. SiGe region  612  is positioned under silicide region  610 , in between cathode contacts  604   a  and  604   b  and anode contacts  606   a  and  606   b.    
     The eFUSE  602  has two cathode contacts  604   a  and  604   b  and two anode contacts  606   a  and  606   b . Fuse link  608  electrically interconnects anode contacts  606   a  and  606   b  and cathode contacts  604   a  and  604   b . Silicide layer  610  of fuse link  608  extends outwards, beyond anode contacts  606   a  and  606   b  and beyond cathode contacts  604   a  and  604   b . Cathode contacts  604   a  and  604   b  are larger than anode contacts  606   a  and  606   b . Cathode contacts  604   a  and  604   b  and anode contacts  606   a  and  606   b  are optimally sized to help prevent cathode damage during programming. For example, anode contact  606  may be 50-100 nm wide and cathode contact  604  may be 100-150 nm wide on a 40-60 nm wide fuse link  608  of eFUSE  602 . In another example, anode contact  606  may be 50% wider than the fuse link  608  and cathode contact  604  may be 150% wider than fuse link  608 . 
     Having two cathode contacts  604   a  and  604   b  and two anode contacts  606   a  and  606   b  significantly reduces defectivity level from the redundant contacts and thus improves the programming yield. In addition, the presence of second anode contact  606   b  and second cathode contacts  604   b  helps alleviate strain on first anode contact  606   a  and first cathode contact  604   a  by reducing electrical current density and temperature at first anode contact  606   a  and first cathode contact  604   a  and therefore, helps prevent programming damages that may become reliability hazards. 
     As a result of the added protection measures for over-programming damage to the eFUSE described in  FIGS. 5A-5B  and  6 A- 6 B, programming can be conducted at slightly higher current level, and thus also improves the programming yield resulting from otherwise too little current. In other words, the sensitivity of fuse programming to process variations is reduced. 
       FIGS. 7A-7F  illustrate the stages in manufacture of the eFUSE of  FIGS. 6A and 6B , according to one embodiment of the present invention. In  FIG. 7A , shallow trench isolation (STI) defines three silicon regions, eFUSE region  702 , pFET region  704 , and nFET region  706  by dividing a nitride layer  710  on a silicon substrate  712 . Shallow trenches  708   a - d  are created using reactive ion etching. Trenches  708   a - d  are then filled with dielectric filing to form STI. 
     In  FIG. 7B , Silicon Germanium (SiGe) regions  714   a - b  are defined in eFUSE region  702  and in pFET region  704  by creating recesses in silicon substrate  712  using reactive ion etching. 
     In  FIG. 7C , SiGe  716   a  is grown in SiGe regions  714   a  of eFUSE region  702  simultaneously as SiGe  716   b  is grown in SiGe region  714   b  of pFET region  704  in a standard CMOS technology, and is therefore cost free. SiGe is epitaxially grown and un-doped. The Ge content can vary from a few percentage points to ˜40-50%. The SiGe is used in PFET region for performance gain due to the improved hole mobility from the compressive stress. 
     In  FIG. 7D , nitride layer  710  is removed. CMOS pFET  718   a  in pFET region  704  and CMOS nFET  718   b  in nFET region  706  are then completed according to standard CMOS manufacturing flows. 
     In  FIG. 7E , silicide  720   a  is formed in eFUSE region  702 , above SiGe  716   a . Simultaneously, silicide  720   b - c  is formed at CMOS FET  718   a  of pFET region  704  and at CMOS FET  718   b  of nFET region  706 . 
     In  FIG. 7F , standard middle-of-the-line (MOL) process forms anode and cathode contacts in eFUSE region  702 , pFET region  704 , and nFET region  706 . Anode contacts  722   a - b  and cathode contacts  724   a - b  are formed in eFUSE region  702 , at silicide  720   a . Source and drain contacts  726  and  728  are likewise formed in pFET region  704 , at silicide  720   b , and source and drain contacts  730  and  732  are likewise formed in nFET region  706 , at silicide  720   c.    
       FIGS. 8-10  illustrate an epi silicon growth stage, following the step of  FIG. 7D , in the manufacture of the eFUSE of  FIGS. 6A and 6B , according to other embodiments of the present invention. Silicide can then be formed on silicon instead of the SiGe as in the embodiment in  FIG. 7E . Forming silicide directly on SiGe may result in higher defect density. Including a layer of silicon between the silicide and the SiGe helps reduce the defect density. 
     In  FIG. 8 , un-doped silicon  802  is formed in eFUSE region  804 , above silicon region and SiGe  806  by epitaxial growth. Nitride  814   a  and nitride  814   b  block CMOS FET  812   a  of pFET region  808  and CMOS FET  812   b  of nFET region  810  from growing this silicon layer. 
     In  FIG. 9 , p+ doped silicon  902  is formed in eFUSE region  904 , above silicon region and SiGe  906  from the same epi process to grow the raised source/drain  916  at CMOS OFT  912   a  of pFET region  908 . Nitride  914  blocks CMOS nFET  912   b  of nFET region  910  from growing the p+ doped silicon. 
     In  FIG. 10 , n+ doped silicon  1002  is formed in eFUSE region  1004 , above silicon region and SiGe  1006  from the same epi process to grow the raised source/drain  1016  at CMOS nFET  1012   b  of nFET region  1010 . Nitride  1014  blocks CMOS pFET  1012   a  of pFET region  1008  from growing the n+ doped silicon. 
     The description above has been presented for illustration purposes only. It is not intended to be an exhaustive description of the possible embodiments. One of ordinary skill in the art will understand that other combinations and embodiments are possible.

Technology Category: g