Patent Grant
11798937
This application claims the priority benefit of French Application for Patent No. 2010686, filed on Oct. 19, 2020, the content of which is hereby incorporated by reference in its entirety to the maximum extent allowable by law.
Implementations and embodiments of the invention relate to electronic components, in particular bipolar transistors and the manufacturing methods thereof, for example heterojunction bipolar transistors (HBT transistors) having a base containing silicon and germanium, and more particularly the doping of the collectors of these bipolar transistors.
A bipolar transistor is a semiconductor-based electronic device whereof the operating principle is based on two PN junctions, one forward and the other reverse.
The doping of the collector in a bipolar transistor, particularly a heterojunction bipolar transistor, is important because it affects the values that define the performances of the transistor, particularly the operating frequency thereof, the maximum oscillation frequency thereof and the main capacities thereof.
Bipolar transistors have been the subject of many publications, in particular: United States Patent Application Publication No. 2020/0111890 (French Application for Patent No. 3087047); U.S. Pat. No. 10,224,423; Heinemann, et al., “SiGe HBT with fx/fmax of 505 GHz/720 GHz”, 2016 IEEE International Electron Devices Meeting (IEDM). IEEE, 2016; and Rúcker, et al., “High-performance SiGe HBTs for next generation BiCMOS technology”, Semiconductor Science and Technology 33.11 (2018): 114003 (all incorporated herein by reference).
In these publications, the doping of the collector region of the bipolar transistor is carried out, for example, by an in situ doping during the epitaxy of the collector or also by implantation of dopants after epitaxy of the collector.
The method constraints such as, for example, the duration, cost, type of dopant, selectivity are difficult to satisfy for in situ doping during epitaxy.
Furthermore, it is complicated to co-integrate in the same integrated circuit high-speed bipolar transistors and bipolar transistors with high collector-emitter breakdown voltage that require different doping of the respective collectors thereof because an in situ doping then involves performing different epitaxies.
Moreover, an implantation of the collector after epitaxy requires the use of mask(s).
Accordingly, there is a need for a collector doping technique having an industrially acceptable cost and complexity and that also optionally makes possible easy co-integration of high-speed transistors and high breakdown voltage transistors within the same integrated circuit.
According to one implementation and embodiment, it is proposed to use a diffusion of dopants, during the epitaxy, and activated by the epitaxy, from a dopant reservoir underlying the epitaxiated portion.
According to one aspect, it is thus proposed a method for manufacturing at least one bipolar transistor, for example a heterojunction bipolar transistor, within an integrated circuit.
This method comprises producing a collector region including an implantation of dopants within a semiconductor substrate so as to form a first doped portion of the collector region and a formation of a second doped portion of the collector region covering and in contact with an area of the first doped portion.
The formation of the second doped portion includes an epitaxy of a non-doped semiconductor material, for example non-doped single-crystal silicon, from said area and a diffusion of dopants in the epitaxiated material, from the first doped portion, said diffusion being activated at least by said epitaxy.
A non-doped semiconductor material, for example silicon, is in general, for example, a material having a concentration of dopants less than 1015 atoms per cm3.
Moreover, an epitaxy of semiconductor material, for example an epitaxy of single-crystal silicon, is generally carried out at a given temperature for a certain time. Therefore, this temperature makes it possible to activate the diffusion of dopants in the epitaxiated material from the underlying reservoir, that is to say from the first doped portion.
However, the diffusion may also continue during subsequent conventional steps of manufacturing of the bipolar transistor depending on the thermal budgets used.
Such a solution is therefore simple to implement at an industrially acceptable cost.
Moreover, as will be seen in more detail hereafter, it easily makes possible the co-integration of transistors of different types (high-speed transistor or high breakdown voltage transistor) because one and the same epitaxy is used.
The diffusion of dopants is advantageously controlled, and the method accordingly comprises preferably a control of this diffusion.
Several solutions are possible to carry out this control.
According to one implementation, the control may comprise an adjustment of the dose of dopants, for example of the phosphorus dose and/or of the depth of the quantity peak of dopants implanted in said area.
According to one implementation, the control may further include a carbon ion implantation in the substrates so as to include carbon in said first doped portion.
Indeed, carbon will make it possible to limit the diffusion of dopants.
According to one implementation, the control may comprise an adjustment of the carbon dose and/or of the depth of the quantity peak of carbon implanted in said area, relative to the adjustment of the dose of dopants and/or of the depth of the quantity peak of dopants, for example phosphorus, implanted in said area.
Of course, these various implementations making possible a control of the diffusion of dopants may be used alone or in combination, one with at least another.
The second collector portion comes into contact with a base region of the transistor.
In addition, according to one variant, the epitaxy of non-doped material (single-crystal silicon for example) is continued up to said base region.
However, it is also possible, according to another variant, that the epitaxy of the non-doped material (the single-crystal silicon, for example) stops at a distance from the base region and said control then comprises a continuation of the epitaxy with an in situ doping of carbon in the non-doped material so as to form in said second portion an upper layer of the semiconductor material containing carbon coming into contact with the base region.
The person skilled in the art will know how to choose the various possibilities for carrying out the control of the diffusion of dopants and the various quantities of dopants and/or of carbon and the relative positions of the peaks of dopants (phosphorus, for example, and of carbon) implanted depending on the final doping profile of the collector desired for the transistor given the thermal budgets implemented in the manufacture of the transistor.
According to one implementation, the method comprises a formation of a stack of layers covering said first doped portion, a formation of a cavity in said stack until uncovering the surface of an area Z of the first doped portion and the formation of said second doped portion in said cavity.
It is possible in some cases, that the formation of the stack, has due to the thermal budgets implemented up to then, affected the initial concentration of dopants implanted in the substrate and being used as a reservoir for the diffusion of the second portion of collector region.
Thus, it may be preferable, in some cases, that prior to the formation of said second portion, an additional, for example surface, implantation of said dopants be carried out in the first doped portion through said cavity.
It is also possible to provide an additional carbon ion implantation, for example a surface implantation, in the first doped portion through said cavity.
According to another aspect, it is proposed a method for manufacturing at least one first bipolar transistor, for example a high-speed transistor, and at least one second bipolar transistor, for example a high breakdown voltage transistor, within an integrated circuit.
This method comprises a joint manufacture of said at least one first transistor and of said at least one second transistor with the method as defined above, the implantation features in the substrate being different for said at least one first transistor and for said at least one second transistor.
According to another aspect, it is proposed an integrated circuit comprising a substrate and at least one bipolar transistor, for example a heterojunction bipolar transistor, including a collector region.
This collector region includes a first doped portion located in the substrate and a second doped portion covering and in contact with an area of the first doped portion.
The collector region has a doping profile having a peak in the first portion and a decrease from this peak up to in the second portion.
Moreover, the doping profile is advantageously devoid of plateau in the second portion.
According to one embodiment, the collector region may further comprise carbon.
According to one embodiment, the second portion may comprise, in the vicinity of the end thereof the furthest away from the first portion, a layer of semiconductor material containing carbon.
According to one embodiment, the integrated circuit comprises at least one first bipolar transistor and at least one second bipolar transistor, located in different places of the substrate, having identical topologies but different doping in the respective collector region thereof.
Transistors have identical topologies in particular when the respective structures of these transistors, in sectional view, (for example the geometry of the active regions thereof) have no significant difference apart from minor differences that may be due to a non-uniformity of manufacturing methods (for example a variability between the center and the edge of the wafer).
In other terms, the only ways to clearly distinguish between the two transistors are for example the analysis of the doping profile and the evaluation of the electric performance.
Thus, according to one embodiment, said at least one first transistor has a collector-emitter breakdown voltage-transition frequency pair different from the collector-emitter breakdown voltage-transition frequency pair of said at least one second transistor.
Said at least one first transistor may have, for example, a collector-emitter breakdown voltage of 1.5 Volts to the nearest 10% and a transition frequency of 400 GHz. Such a transistor may therefore be for example a high-speed transistor.
As to said at least one second transistor, it may have, for example, a collector-emitter breakdown voltage of 3 Volts to the nearest 10% and a transition frequency of 200 GHz. This second transistor may therefore be a high breakdown voltage transistor.
Other advantages and features of the invention will become apparent upon examination of the detailed description of non-limiting implementations and embodiments, and of the appended drawings, wherein:
In
Then, as illustrated in
Here, it should be noted that the bipolar transistor that will be formed is a NPN transistor. However, embodiments herein also apply to the formation of a PNP bipolar transistor. In this case, phosphorus can be replaced with boron.
The dose of dopants implanted and the implantation energy depend on the final desired profile of the collector region of the transistor.
By way of indication, it is possible to implant a dose of phosphorus between 1014 atoms per cm2 and 1015 atoms per cm2, for example in the order of 5×1014 atoms per cm2.
The depth of the implantation peak depends here also on the desired profile. By way of indication, it is possible to choose an implantation energy so as to have a phosphorus peak located in the substrate at a distance between 60 and 70 nanometers from the front face FAV.
It will be seen in more detail hereafter that it is also possible to carry out at this stage, in addition to the phosphorus implantation, a carbon ion implantation.
Then, as illustrated in
In this example, the stack 4 includes particularly a supplementary insulating layer 40 topped with a layer 41 of P-doped polysilicon, for forming a portion of the future extrinsic base of the transistor, a layer 42 of P-doped silicon for forming the future intrinsic base of the transistor, another insulating layer 43 (silicon nitride) topped with another insulating layer 44 (silicon dioxide). A layer of P-type silicon for forming after N-type implantation the emitter region of the bipolar transistor, is at this stage not yet present and will be deposited subsequently.
Then, as shown in
In the following step, illustrated in
This epitaxiated region 60 therefore covers the area Z and is in physical contact with the first doped portion 3.
The conditions for performing such an epitaxy are known per se.
The epitaxy generally occurs at a relatively high temperature, for example 700° C., and it also activates a diffusion 61 of dopants present in the first doped portion 3 that here acts as a dopant reservoir.
In other terms, the epitaxy and the diffusion occur jointly and make it possible to obtain a second portion 60 of the collector region also doped.
It should be noted here that in a conventional and known manner, air pockets 45 occur during the epitaxy, at the ends of the layer 41, which will reinforce the insulation between the collector and the extrinsic base.
By way of indication, in this example of embodiment, the thickness (height) of the second portion 60 of the collector region may be in the order of 45 nanometers.
So as to be able to accurately adjust the desired doping profile in fine, it is particularly advantageous to be able to control the diffusion of the dopants in the epitaxiated semiconductor material 60.
In this regard, as illustrated very schematically in
Thus, the control S10 may comprise an adjustment S100 of the dose of dopants (phosphorus for example), and/or of the depth of the peak of the quantity of dopants implanted in the first portion 3, and therefore in the area Z.
It is also possible that the control S10 of the diffusion comprises, as indicated above, a carbon ion implantation S101 in the substrate so as to include carbon in the first doped portion 3.
Indeed, carbon makes it possible to control the diffusion of phosphorus (or boron) in the epitaxiated non-doped semiconductor material.
By way of indication, it is possible to implant a carbon dose between 1014 atoms per cm2 and 1015 atoms per cm2, for example equal to 5×1014 atoms/cm2.
It is also possible to control the diffusion of dopants by carrying out an adjustment S102 of the carbon dose and/or of the depth of the quantity peak of carbon implanted in said area Z, relative to the dose of dopants (phosphorus for example) and/or of the depth of the quantity peak of dopants, phosphorus for example, implanted in said area Z.
Thus, with an implanted phosphorus dose of 1019 atoms per cm2 and an implanted carbon dose of 1020 atoms per cm2, it is possible to choose the implantation energy so as to have a phosphorus peak between 60 and 70 nanometers of the front face FAV of the substrate and a carbon peak between 50 and 60 nanometers.
It is also possible, as illustrated in
More specifically, as illustrated in
This epitaxy with an in situ doping is carried out conventionally, with the aid of silane and carbon and reinforces the presence of carbon at the top of the collector region.
By way of indication, the thickness of this layer 601 may be, in this embodiment, by way of indication in the order of 20 nanometers.
During the production of the stack 4, the thermal budgets used may already activate a certain diffusion of dopants and/or of carbon in the first doped portion 3.
Thus, in this case, it is advantageously intended, as illustrated in
By way of indication, it is again possible to implant a phosphorus dose of 1019 atoms per cm2 and a carbon dose of 1020 atoms per cm2 with an energy leading to a surface implantation.
Then, as illustrated in
After conventional subsequent steps of manufacturing a bipolar transistor, as illustrated in
The bipolar transistor includes a collector region including a first doped portion 70 located in the substrate SB and a second doped portion 71 covering and in contact with an area Z of the first doped portion 70.
Moreover, the bipolar transistor includes an extrinsic base region 81, an intrinsic base region 80 and an emitter region 9.
The transistor TR is here an NPN bipolar transistor, having for example a heterojunction intrinsic base 80 (including, for example, silicon and germanium).
In the embodiment of
However, embodiments herein are not limited to this embodiment and is perfectly compatible with other embodiments of bipolar transistors TR such as same schematically illustrated in
More particularly, in
In this regard, it can be noted in
In
As schematically illustrated in
Moreover, it can be seen that the doping profile has substantially the shape of a Gaussian and is devoid of plateau in the second portion.
Such a doping profile is therefore clearly distinguished from a doping profile according to the prior art such as illustrated in
In this case, the doping profile PRF1 of the prior art has a plateau and a peak PC1 located in the in situ doped epitaxiated region.
The profile PRF is also clearly distinguished from a profile PRF2 obtained by a transistor of the prior art whereof the collector region is an epitaxiated then implanted region.
It can be seen is this
Reference is now made more particularly to
More particularly, as illustrated in
Then, as illustrated on the right-hand side of
For the future transistor TRA, a first doped collector portion 3A is then obtained.
Then, steps similar to those described in
The transistor TRA and the transistor TRB have identical topologies (geometry of collector regions, etc.) but different doping in the collector. This makes it possible, for example, of jointly producing on the same substrate and by using a single epitaxy, a high-speed transistor, (for example the transistor TRA) and a high collector-emitter breakdown voltage transistor (for example the transistor TRB).
In this regard, as illustrated in
Moreover, the thickness e1 of the domain 711A is less than 50% of the total thickness e1+e2 of the epitaxy, for example in the order of 30% of this total thickness.
As regards the transistor TRB, the second portion 71B of the collector region thereof includes a first highly doped domain 710B, for example there again a concentration of dopants between 1018 and 1020 atoms per cm3, topped by a less highly doped domain 711B, for example with a concentration of dopants less than or equal to 1017 atoms per cm3.
However, this time, the thickness e4 of the domain 710B is less than 50% of the total thickness e3+e4 of the epitaxy, for example in the order of 10% of this total thickness.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2010686 | Oct 2020 | FR | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 10224423 | Gauthier et al. | Mar 2019 | B1 |
| 20020100917 | Chu et al. | Aug 2002 | A1 |
| 20050250289 | Babcock | Nov 2005 | A1 |
| 20060040453 | Bock et al. | Feb 2006 | A1 |
| 20090108300 | Gluschenkov | Apr 2009 | A1 |
| 20130092939 | Kim | Apr 2013 | A1 |
| 20150318384 | Boeck | Nov 2015 | A1 |
| 20180286968 | Jain | Oct 2018 | A1 |
| 20200203333 | Chen | Jun 2020 | A1 |
| 20210202717 | Jain | Jul 2021 | A1 |
| Number | Date | Country |
|---|---|---|
| 3087047 | Apr 2020 | FR |
| Entry |
|---|
| INPI Search Report and Written Opinion for FR Appl. No. 2010686 dated Jul. 1, 2021 (10 pages). |
| B.Heineman “SiGe HBT With FR/FMAX of 505 GHz/720 GHz” IHP Frankfurt (Germany) IEDM 16-51 2016 IEEE. |
| Holger Rucker an Bernd Heinemann “High-Performance Sige HTBs for Next <Generation Bicmos Technology” Semiconductor Science and Technology 2018 (114003). |
| Number | Date | Country | |
|---|---|---|---|
| 20220122969 A1 | Apr 2022 | US |
