Abstract:
A semiconductor arrangement including:
       a substrate having a substrate layer ( 13 ) with an upper and lower surface, the substrate layer ( 13 ) being of a first conductivity type;   a first buried layer ( 12 ) in the substrate, extending along said lower surface below a first portion of said upper surface of said substrate layer ( 13 ), and a second buried layer ( 12 ) in the substrate, extending along said lower surface below a second portion of said upper surface of said substrate layer ( 13 );   a first diffusion ( 26 ) in said first portion of said substrate layer ( 13 ), being of a second conductivity type opposite to said first conductivity type and having a first distance to said first buried layer ( 12 ) for defining a first breakdown voltage between said first diffusion ( 26 ) and said first buried layer ( 12 );   a second diffusion ( 45 ) in said second portion of said substrate layer ( 13 ), being of said second conductivity type and having a second distance to said second buried layer ( 12 ) for defining a second breakdown voltage between said second diffusion ( 45 ) and said second buried layer ( 12 );
 
said first distance being larger than said second distance such that said first breakdown voltage is larger than said second breakdown voltage.

Description:
FIELD OF THE INVENTION 
     The present invention relates to a semiconductor arrangement with a protection diode for improved ruggedness of a radio frequency power transistor and self-defining method to manufacture such protection diode as defined in the outset of claim  1 . 
     BACKGROUND OF THE INVENTION 
     Radio frequency (RF) power transistors are used e.g. for mobile communication devices in the frequency range from 900 MHz to 2 GHz. Failure of RF power transistors can occur due to a mismatch of the load impedance (e.g. an antenna) and the output impedance of the transistor. Due to the impedance mismatch the voltage between base and collector of the RF transistor may increase above the level where breakdown occurs and the transistor becomes damaged. A protection diode connected between collector and emitter will prevent breakdown of the transistor by providing a lower breakdown voltage for the diode. Such a device is known from U.S. Pat. No. 5,751,052, which shows a transistor integrated with a Zener diode as protection diode. In  FIG. 2  of U.S. Pat. No. 5,751,052 a cross-sectional view of a device comprising a transistor and a protection Zener diode is shown. During the manufacturing of a device according to this prior art, the construction of the Zener diode requires additional processing steps. As known to persons skilled in the art of semiconductor technology, such steps comprise the formation of precisely defined lateral diffusion zones for which the respective depth must also be defined precisely. 
     Therefore, the formation of a Zener diode disadvantageously contributes to the manufacturing time and costs of the device. Moreover, the formation of a Zener diode may be prohibited in some types of power transistor device due to restrictions imposed by the technology. For example, in a double poly-Si process for bipolar devices as known in the art, formation of a Zener diode connected to a RF power transistor is not feasible. 
     SUMMARY OF THE INVENTION 
     It is an object of the present invention to provide a bipolar device comprising a RF power transistor and a protection diode and a method to manufacture such a bipolar device in a double poly-Si process. 
     The present invention relates to a semiconductor arrangement comprising: a substrate having a substrate layer with an upper surface and a lower surface, the substrate layer being of a first conductivity type; a first buried layer in the substrate, extending along said lower surface below a first portion of said upper surface of said substrate layer, and a second buried layer in the substrate, extending along said lower surface below a second portion of said upper surface of said substrate layer; a first diffusion region in said first portion of said substrate layer, being of a second conductivity type opposite to said first conductivity type and having a first distance to said first buried layer for defining a first breakdown voltage between said first diffusion region and said first buried layer; a second diffusion region in said second portion of said substrate layer, being of said second conductivity type and having a second distance to said second buried layer for defining a second breakdown voltage between said second diffusion region and said second buried layer; said first distance being larger than said second distance such that said first breakdown voltage is larger than said second breakdown voltage. 
     Moreover, the present invention relates to the arrangement as described above, wherein said first diffusion region is a base of a bipolar transistor and said first buried layer is a collector of said bipolar transistor. 
     Also, the present invention relates to the aforementioned arrangement, wherein said second diffusion region is an anode of a protection diode and said second buried layer is a cathode of said protection diode. 
     Furthermore, the present invention relates to the aforementioned arrangement, wherein said first buried layer is connected to said second buried layer, and said first and second buried layers are manufactured in the same step. 
     Also, the present invention relates to the arrangement as defined above, further comprising a channel stopper region in said second portion of said substrate layer; the channel stopper region being of said first conductivity type, for electrically isolating said second portion of said substrate layer within the substrate, wherein said channel stopper region is arranged to extend substantially as an extended channel stopper region in between said second diffusion region and said second buried layer, for reducing said second breakdown voltage. 
     The present invention relates to a method of manufacturing a semiconductor arrangement, comprising the steps of:
         providing a substrate with a substrate layer with an upper surface and a lower surface, the substrate layer being of a first conductivity type, a first buried layer being provided in the substrate, extending along said lower surface below a first portion of said upper surface of said substrate layer, and a second buried layer being provided in the substrate, extending along said lower surface below a second portion of said upper surface of said substrate layer;   diffusing a first diffusion region in said first portion of said substrate layer, being of a second conductivity type opposite to said first conductivity type and having a first distance to said first buried layer for defining a first breakdown voltage between said first diffusion region and said first buried layer;   diffusing a second diffusion region in said second portion of said substrate layer, being of said second conductivity type and having a second distance to said second buried layer for defining a second breakdown voltage between said second diffusion region and said second buried layer;   said first distance being larger than said second distance such that first breakdown voltage is larger than said second breakdown voltage.       

     Moreover, the present invention relates to the method described above, wherein said first and second diffusion regions are formed by depositing, in a single manufacturing step, a first poly-silicon layer in a first area in said first portion and a second poly-silicon layer in a second area in said second portion, and diffusing said first and second diffusion regions from said first and second poly-silicon layers, respectively, in a single annealing step, said first area being smaller than said second area. 
     Furthermore, the present invention relates to the aforementioned method, further comprising the step of forming by ion-implantation a channel stopper region in said second portion of said substrate layer; the channel stopper regions being of said first conductivity type, for electrically isolating said second portion of said substrate layer within the substrate, wherein said channel stopper region is formed by ion-implantation as an extended channel stopper region in between said second diffusion region and said second buried layer, for reducing said second breakdown voltage. 
     According to the present invention the formation of the protection diode does not require any additional processing steps (e.g., deposition, implantation, masking and etching) in comparison with the processing steps required to construct a separate RF power transistor. The protection diode is formed within the same processing steps as the power transistor. Moreover, the method of the present invention is self-defining: i.e., any variations occurring during the processing steps will influence the electrical (and physical) properties of both power transistor and protection diode in a similar way. Under these circumstances the breakdown voltage of the protection diode will always be lower than the detrimental breakdown voltage of the transistor. 
    
    
     
       SUMMARY OF THE INVENTION 
       Below, the invention will be explained with reference to some drawings, which are intended for illustration purposes only and not to limit the scope of protection as defined in the accompanying claims. 
         FIG. 1  shows a schematic, prior art illustration of a circuit comprising a RF power transistor and protection diode; 
         FIG. 2  shows schematically a layout in plane view for a device comprising a RF power transistor and protection diode according to the present invention; 
         FIGS. 3   a - 3   m  show schematically cross-sectional views of the transistor part of the device after successive processing steps according to the present invention; 
         FIGS. 4   a  and  4   b  show cross-sectional areas of the protection diode in two respective preferred embodiments after the step of metallization. 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       FIG. 1  shows a schematic illustration of a prior art circuit comprising a RF power transistor and protection diode. In the circuit  1  of  FIG. 1 , the RF power transistor  2  is shown comprising a base  3 , an emitter  4  and a collector  5 . The RF power transistor  2  is in a configuration, known in the art as a common emitter configuration, where emitter  4  and the substrate region  6  (not shown) are at electrical ground level. Between emitter  4  and collector  5  there is a parasitic capacitance  7  in series with a resistance  8 . Parallel to the parasitic capacitance  7  and resistance  8  a protection diode  9  between collector  5  and emitter  4  is created in the manufacturing process. The protection diode  9  comprises a cathode  10  and an anode  11 . The protection diode  9  serves to prevent damage of the RF power transistor  2  in case the voltage between collector  5  and base  3  increases to the breakdown level of the transistor. The protection diode  9  will clip at a lower level voltage V CE , before breakdown of the transistor occurs. 
     The circuit  1  according to the present invention is produced in a standard double poly-silicon process for bipolar transistor devices, without the application of additional processing steps. The protection diode  9  is formed during the same processing steps as required for the power transistor  2 . 
       FIG. 2  shows schematically an exemplary layout in plane view for a device comprising a RF power transistor  2  and protection diode  9  according to the present invention. On the n-type epitaxial surface layer  13  of substrate  6  a base region  3 , an emitter region  4 , a collector region  12  and a protection diode region  9  are defined. In this layout at the surface level of the substrate  6 , the base region  3  and emitter region  4  are located closely together in a common area. At some distance at the same surface level the diode region  9  is located. Below the surface level of the substrate  6 , a buried collector region  12  is defined, which extends from below the base and emitter regions  3 ,  4  to below the diode region  9 . In the collector region  12  a collector opening region  31  to connect the collector, is provided. Around these regions  3 ,  4 ,  5 ,  9 ,  31 , a channel stopper (depicted by a dashed line) is defined to isolate the device from neighboring devices. Outside of the collector region  12  the channel stopper locally dopes the n-type epitaxial surface layer  13  into p-type. The lines AA′ and BB′ indicate the locations of the cross-sectional views as shown in  FIGS. 3   a - 3   m  and  FIGS. 4   a ,  4   b  respectively. It is noted that the buried collector region  12  may extend under a plurality of base and emitter regions  3 ,  4 , that form, in a parallel connection, a single large power transistor. In that case, the channel stopper demarcates the area comprising this single large power transistor. 
     The processing steps required to form a circuit  1  according to the present invention are illustrated by the following  FIGS. 3   a - 3   m  which schematically show a cross-sectional area, defined by the line AA′ in  FIG. 2  wherein the power transistor  2  is formed in successive steps. 
       FIGS. 4   a  and  4   b  show a cross-sectional area of the protection diode  9 , defined by the line BB′ in  FIG. 2 , in two respective preferred embodiments after the step of metallization. 
       FIG. 3   a  shows a step F 1  of the formation of a collector region. In substrate  6  a buried collector region  12  is formed. An implantation process defines a laterally confined n +  region  12  in the p −  doped substrate  6  to form the collector  5 . As known to persons skilled in the art, the collector region  12  may comprise several areas which are separated during their formation in this step F 1  by means of a mask. 
       FIG. 3   b  illustrates a step F 2  of the formation of an n-type epitaxial silicon layer  13  on top of n +  region  12 . The dopant of n +  region  12  diffuses slightly into layer  13  due to the thermal exposure during the deposition process of n-type epitaxial silicon layer  13 . 
       FIG. 3   c  illustrates a step F 3  of lithographic formation of sacrificial masks  14 ,  15  that define the locations where in a later processing step base and emitter regions  3 ,  4  and a connection to the n +  region  12  (collector  5 ) will be formed. 
       FIG. 3   d  illustrates a step F 4  of the implantation of dopant regions which define channel-stoppers  17 ,  18  in n-type epitaxial silicon layer  13 . 
       FIG. 3   e  shows a cross-sectional view after LOCOS oxidation in a step F 5 . In the n-type epitaxial silicon layer  13  oxidized regions  21  are formed using the sacrificial masks  14  and  15 . The oxidized regions  21  isolate the areas  19 ,  20  to form, in a later processing step, base and emitter regions  3 ,  4  and a connection to the collector region  5 , respectively. Due to thermal exposure during the LOCOS oxidation process, p-type dopant diffuses further into the substrate  6  extending the channel-stoppers  17  and  18  into the substrate  6 . 
     In  FIG. 3   f  a step F 6  of the formation of the connection to the collector region  5  (n +  region  12 ) is illustrated. In the area  20  a deep n +  doped plug  22  is defined by an implantation process. The plug  22  connects the n +  region  12  to the surface of area  20 . 
       FIG. 3   g  illustrates a step F 7  of the formation of the base and emitter regions  3 ,  4 . A first p ++  doped poly-silicon layer  23  is deposited, and subsequently patterned on area  19  using lithographic and etching steps as known in the art. 
     To provide passivation and isolation of the structure, in a next processing step F 8  an oxide layer  24  is deposited on top of the structure, as shown in  FIG. 3   h . By means of a masked etch using processing steps as known in the art, the emitter opening in layer  23  and  24  to area  19  is defined. 
     In  FIG. 3   i  a step F 9  of the formation of nitride L-spacers  25  on the walls of the emitter opening is illustrated. During the formation of the L-spacers, p-type dopant (e.g. B) from the poly-silicon layer  23  diffuses into the n-type epitaxial silicon layer  13 , forming a shallow p +  doped region  26 . By local implantation an implanted shallow p +  doped region  26   a  is formed. Typically, the overall shallow p +  doped region, comprising both region  26  and region  26   a , has a length of 1-10 μm, a width of 0.3 μm and a depth of 0.2-0.25 μm. Also, by a local implantation step, a high doped n +  region  50  is formed in the n-type epitaxial silicon layer  13  to provide a lower collector series resistance. 
       FIG. 3   j  shows a step F 10  of forming a poly-silicon layer and plug using processing steps as known in the art. A second poly-silicon layer  28  is deposited and subsequently patterned as the connection to the emitter region  4  of the transistor. By diffusion of n-type dopant (e.g. As) from the poly-silicon layer  28 , a very shallow n +  doped region  27  is formed at the top of the implanted shallow p +  doped region  26   a.    
       FIG. 3   k  shows a step F 11  of forming the base region contact opening  29 ,  30  and the collector contact opening  31  by selective etching the oxide layer  24 . 
     Finally,  FIG. 3   l  shows a step F 12  of metallization, in which a metal layer is deposited on the structure. By a patterning step, metal connects  32 ,  33 ,  34 ,  35  are defined for connection to the base region  3  through the contact openings  29 ,  30 , to the collector region  5  through contact opening  31 , and to the emitter region  4  through poly-silicon plug  28 , respectively. 
       FIG. 3   m  shows schematically the cross-sectional view of the transistor part of the device to display the dopant regions  13 ,  26 ,  26   a ,  27  and  50 , in closer detail. In  FIG. 3   m , the base region  3 , the emitter region  4 , the n-type epitaxial silicon layer  13 , the oxidized regions  21 , the first p ++  doped poly-silicon layers  23 , the oxide layers  24 , the nitride L-spacers  25 , the shallow p +  doped region  26 , the implanted shallow p +  doped region  26   a , the very shallow n +  doped region  27  and the highly doped n +  region  50  are shown. Due to the geometry and the size of the contact area between the first p ++  doped poly-silicon layer  23  and the n-type epitaxial silicon layer  13 , a dopant profile for the shallow p +  doped region  26  as schematically shown in  FIG. 3   m , is created during the diffusion process. Also, due to the diffusion process, the shallow p +  doped region  26 , below the base region  3 , has a concentration profile of p-type dopant that extends deeper than the concentration profile of p-type dopant in the implanted shallow p +  doped region  26   a  below the emitter region  3 . 
     Simultaneously with the transistor  2  the protection diode  9  is formed. This is accomplished by a selective use of separate steps in the aforementioned processing steps F 1 -F 12  used to form the transistor. 
       FIG. 4   a  shows a protection diode  9  according to the present invention after the step of metallization. It is made in the following way. In step F 1 , in the substrate  6  the n +  region  12 , formed as buried collector region  5  for the transistor, is extended laterally as the cathode region  10  of the protection diode  9 . Subsequently, in step F 2  the n-type epitaxial silicon layer  13  is deposited. Dopant from the n +  region  12  diffuses slightly into the n-type epitaxial silicon layer  13  due to thermal exposure during epi growth. In step F 3 , a sacrificial mask is formed to define the area  41  where the anode  11  of the diode will be formed at a later stage. In step F 4 , a channel stopper  42  is formed. In step F 5 , oxidized regions  43  are formed using the LOCOS process to isolate the area of the anode  11 . Due to annealing during the LOCOS process, the channel stopper  42  now extends into the substrate  6 . In step F 7 , the first p ++  doped poly-silicon layer  23  is deposited and patterned as a p ++  doped poly-silicon contact  44  on top of the area of the anode  11 . Subsequently, in step F 8  the oxide layer  24  for passivation and isolation is deposited over the p ++  doped poly-silicon contact  44 . Due to annealing during step F 9 , p-type dopant from the p ++  doped poly-silicon contact  44  diffuses into the n-type epitaxial silicon layer to form a p-type doped region  45 . In step F 11 , the oxide layer  24  is opened to create an anode contact opening. In metallization step F 12 , the anode contact opening is filled with metal  46 . 
     In this preferred embodiment, the breakdown voltage level of the diode  9  is smaller than the breakdown voltage level between the base and the collector of the transistor, which is determined by the dopant profiles in the shallow p+ doped region  26  and the p-type doped region  45 , respectively, and their distances to the buried layer  12 . 
     In the present invention, the area of the anode  11 , as depicted by the p-type doped region has typically a length of 1-10 μm, a width of 10 μm and a depth of 0.3 μm. Compared to the length and width of the combined shallow p+ doped regions  26 ,  26   a  of the transistor shown in  FIG. 3   m  (length: 1-10 μm, width: 0.3 μm, depth: 0.2-0.25 μm), the areal size of the anode  11  of the diode  9  is much larger than the areal size of base and emitter regions  3 ,  4  of the transistor. 
     The difference in areal size influences the dopant profiles, in the shallow p +  doped region  26  and the p-type doped region  45 , as formed by the diffusion process. As known to persons skilled in the art, the kinetics of the dopant diffusion process in both the shallow p+ doped region  26  and the p-type doped region  45  will be identical: the thermal exposure of the transistor  2  and diode  9  is identical during the processing steps F 1 -F 12 , the source material is identical for the transistor and diode areas: p-type dopant from the first pa doped poly-silicon layer  23  and/or contact  44 . The target material is also identical: n-type epitaxial silicon grown in the same process step F 2 . 
     However, the dopant profile below the larger p ++  doped poly-silicon contact area  44  will extend slightly deeper into the n-type epitaxial silicon layer  13  due to a geometric effect: the dimensions of the dopant source as defined by the area  45  are larger. It is estimated that for a depth of the shallow p +  doped region  26  of 0.2-0.25 μm, the depth of the p-type doped region  45  is 0.30 μm. 
     Also, since the kinetics of the dopant diffusion process in both the shallow p+ doped region  26  and the p-type doped region  45  are identical, incidental process variations will influence the dopant profiles in both the shallow p +  doped region  26  and the p-type doped region  45  in a similar way: the method to manufacture a protection diode according to the present invention is self-defining. For example, if due to a higher annealing temperature in step F 9 , the diffusion depth for the dopant will be deeper for both the shallow p+ doped region  26  and the p-type doped region  45 , and all other things being equal, then the dopant profile of the p-type doped region  45  will still be the deeper one. Accordingly, the diode  9  will have a lower breakdown voltage than the base-collector transition of the transistor. 
     In devices comprising a transistor  2  and diode  9  according to the present invention, the breakdown voltage of the transistor between base and collector is 18-20 V, whereas the diode  9  has a breakdown voltage which is 2 V lower: 16-18 V. 
     The protection diode  9  comprises a capacitance which is present between the emitter  4  and collector  5 , in parallel with the parasitic transistor capacitance  7 . In order not to affect the efficiency of the transistor  2  too strongly, the capacitance of the diode  9  must be optimized by means of the areal size of the diode  9 . A large capacitance of the diode  9  reduces the transistor efficiency as defined by the power added efficiency (the conversion from dc input power to RF output power). A small capacitance of the diode  9  results in a (too) small current flow through the diode  9 , thus reducing the protection capability of the diode  9 . 
     In a second preferred embodiment, the protection diode  9  may exhibit a still lower breakdown voltage. In  FIG. 4   b  the protection diode  9  is shown in this second preferred embodiment. The protection diode  9  according to the second embodiment is formed in the same way as explained above with reference to  FIG. 4   a . Here, the channel stopper  42  as shown in  FIG. 4   a , is replaced by a channel stopper  47  which in comparison to channel stopper  42 , comprises a larger region extending under the p-type doped region  45  of the diode  9 . All other parts of the diode structure shown in  FIG. 4   b  are identical to the ones shown in  FIG. 4   a . Due to the extension of channel stopper  47  under the p-type doped region  45  of the diode  9 , the breakdown voltage level is advantageously reduced to approximately 10 V. However, due to the large size of the channel stopper  47 , the capacitance of the protection diode  9  is strongly increased (with an increase in current flow and a reduction of the power added efficiency). By optimizing the channel stopper area  47 , the breakdown voltage and the capacitance of the diode  9  can be tuned as required for the application of the device. 
     It will be appreciated that the method to manufacture a microelectronic device in a self-defining way is not restricted to the particular sequences of processing steps as described above. Other self-defining processing sequences, comprising the same technologies as above or others, may be conceivable. Also, the method is not limited to the described device comprising a power transistor  2  and a protection diode  9 , but may be applicable for other types of microelectronic devices as well. For example, the diode  9  may have a different function and may be used detached from the power transistor  2 . In general, the method of the present invention may be used in a double poly-Si process for the formation of diodes comprising a junction from poly-silicon to monocrystalline silicon. For example, the method of the present invention may be used to manufacture, in one processing sequence, a plurality of such diodes with slightly different breakdown voltages, in dependence of the areal size of each of the diodes. 
     Moreover, the principle that the diffusion of dopant into a matrix layer from a covering feed layer is dependent on the geometry of the interface area between that matrix layer and the covering feed layer, can be applied to modify the diffusional transport of a dopant to proceed in one, two or three dimensions by proper definition of the actual size and shape of the interface area: differences in diffusion length in one dimension can be achieved as described above by varying the area size of the interface area. Two dimensional differences in diffusion can be obtained by using narrow lines with various size as the interface area. By using point contacts with various size as the interface area, even three dimensional differences in diffusion may be obtained.