A semiconductor device includes a semiconductor substrate, an element-isolating region formed in the semiconductor substrate, a real element region formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof, and a dummy element region formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof. The ratio of the sum of pattern areas of the real element region and dummy element region occupied in a 1 μm-square range of interest including the element region is 25% or more.
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0. 39. A semiconductor, comprising:
a semiconductor substrate;
an element-isolating region formed in the semiconductor substrate;
a real element region formed in the semiconductor substrate, isolated by the element-isolating region and having a metal silicide layer; and
means for decreasing an area occupied by said element-isolating region in a 1 micron square region containing said real element region if an area of said real element region is less than 25% of an area of said square region.
0. 28. A semiconductor device, comprising:
a semiconductor substrate;
an element-isolating region formed in the semiconductor substrate;
an element region formed in the semiconductor substrate, isolated by the element-isolating region, and having a metal silicide layer with a first area; and
at least one dummy region formed in the semiconductor substrate, and having a metal silicide layer with a second area,
wherein a ratio of a sum of the first and second areas occupied in said in a 1 μm square region containing the element region and at least a portion of said at least one dummy region, is at least 25%.
1. A semiconductor device comprising:
a semiconductor substrate;
an element-isolating region formed in the semiconductor substrate; and
a plurality of element regions formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof, said plurality of element regions including a real element region and at least one dummy element region,
wherein the ratio of the sum of pattern areas of the real element region and said at least one dummy element region occupied in a 1 μm square range of interest including the element region is 25% or more.
0. 9. A semiconductor device, comprising:
a semiconductor substrate;
an element-isolating region formed in the semiconductor substrate; and
a plurality of element regions formed in the semiconductor substrate, isolated by the element-isolating region and having a metal silicide layer, including a real element region and
at least one dummy element region,
wherein a ratio of a sum of an area of the real element region and an area of said at least one dummy element region occupied in a 1 μm square region containing the real element region and at least a portion of said at least one dummy element region is at least 25%.
0. 37. A semiconductor device having a semiconductor substrate, an element-isolating region formed in the semiconductor substrate, a plurality of element regions formed in the semiconductor substrate, isolated by the element-isolating region and having a metal silicide layer, including a real element region and at least one dummy element region, formed by a method comprising:
forming said real element region and at least a portion of said dummy element region in a 1 μm square region where a ratio of a sum of an area of the real element region and an area of said at least one dummy element region occupied in said square region is 25% or more.
2. The semiconductor device according to
a well having a channel region;
a first impurity diffusion layer formed in a surface region of the well;
a gate electrode formed on the channel region of the well via a gate insulating film; and
a metal silicide layer formed on each of the first impurity diffusion layer and the gate electrode.
3. The semiconductor device according to
a well;
a first impurity diffusion layer formed over an entire surface of the surface region of the well; and
the metal silicide layer formed on an upper surface of the first impurity diffusion layer.
4. The semiconductor device according to
a well; and
the metal silicide layer formed on the well.
5. The semiconductor device according to
a well;
a second impurity diffusion layer for well contact formed in a surface region of the well; and
the metal silicide layer formed on the well and the second impurity diffusion layer.
6. The semiconductor device according to
7. The semiconductor device according to
8. The semiconductor device according to
a trench formed in the semiconductor substrate; and an insulating film burying within the trench.
0. 10. The semiconductor device according to
a plurality of dummy element regions, wherein portions of a plurality of said dummy element regions are included in said square region, and a ratio of a sum of an area of the real element region to a sum of areas of said portions of said dummy element regions is 25% or more.
0. 11. The semiconductor device according to
at least one of said dummy regions having a shape different than a shape of said real element region.
0. 12. The semiconductor device according to
an area of at least one of said dummy regions being larger than an area of said real element region.
0. 13. The semiconductor device according to
at least one of said dummy regions having a shape different than a shape of said real element region.
0. 14. The semiconductor device according to
an area of at least one of said dummy regions being larger than an area of said real element region.
0. 15. The semiconductor device according to
said real element region comprises a first transistor; and
said dummy element region comprises a second transistor.
0. 16. The semiconductor device according to
each of said first and second transistors includes a gate electrode.
0. 17. The semiconductor device according to
a channel region;
a gate electrode formed on the channel region via a gate insulating film;
a diffusion region; and
a metal silicide layer formed on each of the diffusion region and the gate electrode.
0. 18. The semiconductor device according to
0. 19. The semiconductor device according to
0. 20. The semiconductor device according to
0. 21. The semiconductor device according to
0. 22. The semiconductor device according to
0. 23. The semiconductor device according to
said square region being approximately centered on the real element region and including at least a portion of said at least one dummy region.
0. 24. The semiconductor device according to
said at least one dummy region surrounding said real element region.
0. 25. The semiconductor device according to
said at least one dummy region surrounding said real element region.
0. 26. The semiconductor device according to
0. 27. The semiconductor device according to
said ratio being approximately 25%.
0. 29. The semiconductor device according to
a plurality of dummy element regions, wherein portions of a plurality of said dummy regions are included in said square region.
0. 30. The semiconductor device according to
at least one of said dummy regions having a shape different than a shape of said real element region.
0. 31. The semiconductor device according to
an area of at least one of said dummy regions being larger than an area of said real element region.
0. 32. The semiconductor device according to
at least one of said dummy regions having a shape different than a shape of said real element region.
0. 33. The semiconductor device according to
an area of at least one of said dummy regions being larger than an area of said real element region.
0. 34. The semiconductor device according to
said square region being approximately centered on the real element region and including at least a portion of said at least one dummy region.
0. 35. The semiconductor device according to
said dummy region surrounding said real element region.
0. 36. The semiconductor device according to
0. 38. The semiconductor device according to
forming a trench;
filling said trench with an insulating layer;
forming a first diffusion region in said real element region;
forming a second diffusion region in said at least one dummy element region;
forming a Ni layer over said first and second diffusion regions and said insulating layer; and
forming a silicide layer on said first and second diffusion regions.
0. 40. The semiconductor device according to
0. 41. The semiconductor device according to
0. 42. The semiconductor device according to
an area of said at least one dummy element region being larger than an area of said real element region.
0. 43. The semiconductor device according to
0. 44. The semiconductor device according to
0. 45. The semiconductor device according to
0. 46. The semiconductor device according to
forming a trench;
filling said trench with an insulating layer;
forming a first diffusion region in said real element region;
forming a second diffusion region in said at least one dummy element region;
forming a Ni layer over said first and second diffusion regions and said insulating layer; and
forming a silicide layer on said first and second diffusion regions.
0. 47. The semiconductor device according to
said means having a shape different than a shape of said real element region.
0. 48. The semiconductor device according to
0. 49. The semiconductor device according to
said square region being approximately centered on the real element region.
0. 50. The semiconductor device according to
said means surrounding said real element region.
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This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2003-385425, filed Nov. 14, 2003, the entire contents of which are incorporated herein by reference.
1. Field of the Invention
The present invention relates to a semiconductor device and a method of manufacturing the semiconductor device, and more particularly, to a semiconductor device having a metal silicide layer on an element region and a method of manufacturing the semiconductor device. For example, the present invention is applied to a complementary metal-oxide-semiconductor (CMOS) logic large-scale integration (LSI).
2. Description of the Related Art
For example, in the CMOS logic LSI, a self-aligned silicide (salicide) technique is used to suppress a parasitic resistance, which increases as a device is miniaturized. In the salicide technique, a reaction product between a metal and a semiconductor such as Si, namely, a silicide compound (hereinafter, referred to as a “metal silicide”), is formed on the source/drain region (an impurity diffusion layer formed in a semiconductor substrate) of a metal oxide semiconductor field-effect transistor (MOSFET) and on the gate electrode formed of a polycrystalline Si. By virtue of the presence of the metal silicide, the resistivity of each of the source/drain region and the gate electrode can be reduced. In this case, the metal to be used in the metal silicide is chosen based on a desired resistance value in consideration of conditions such as a thermal design of a CMOS process, the dimension of the gate electrode, and the depth of the diffusion layer.
Incidentally, in a CMOS technique developed after a 65 nm-node technology, a low temperature processing is required for a process forming a metal silicide in order to suppress a metal material from causing thermal diffusion, thereby suppressing contact current leakage taking place in the impurity diffusion layer and in order to suppress the doped n-type and p-type impurities from being activated. To reduce the temperature, attention has been focused on Ni. This is because Ni monosilicide can reduce the resistivity, unlike Ti and Co. Therefore, Ni is a metal material, which attains film formation at low temperature.
However, the diffusion coefficient of Ni in Si is large, which means that the chemical reaction between Si and Ni proceeds while Ni is being diffused in Si during the silicide formation process. Accordingly, when unreacted Ni is present excessively around the reaction region, the thickness of a Ni film around the reaction region increases. When a silicide is formed, excessive Ni is diffused into the element region, with the result that a silicide reaction excessively takes place in the contact region. It follows that contact current leakage takes place in the gate electrode or the impurity diffusion layer in the source/drain region. In short, current leakage occurs due to the presence of a metal silicide formed in the contact region.
When a Ni silicide is formed on the gate electrode and the source/drain region of a MOSFET by a conventional salicide technique, contact current leakage sometimes occurs depending upon the area ratio between the silicide reaction region, which is formed on the gate electrode and the source/drain region, and the silicide unreaction region, which is formed on a shallow trench isolation (STI).
In
As shown in
Note that U.S. Pat. No. 6,180,469 discloses a technique for reducing contact current leakage and resistance. The technique includes selectively forming a Ni layer on the surfaces of the gate electrode and the source/drain region by electroless plating, doping N ions in the Ni layer to form a barrier layer, which divides the Ni layer into upper and lower layers, and applying heat treatment to the lower Ni layer, thereby converting only the lower Ni layer into a silicide layer.
As described, a conventional semiconductor device has a problem in that when Ni silicide is formed in the element region surrounded by the STI by the salicide technique, more specifically, in the element region formed discretely like an island in a large STI region, Ni excessively present in an unreaction region diffuses into the element region during the silicide process, suppressing an excessive silicide reaction in the contact region, thereby causing contact current leakage.
According to an aspect of the present invention, there is provided a semiconductor device including:
a semiconductor substrate;
an element-isolating region formed in the semiconductor substrate; and
a plurality of element regions formed in the semiconductor substrate and outside the element-isolating region and having a metal silicide layer formed on the surface thereof, the plurality of element regions including a real element region and at least one dummy element region,
in which the ratio of the sum of pattern areas of the real element region and said at least one dummy element region occupied in a 1 μm-square range of interest including the element region is 25% or more.
According to another aspect of the present invention, there is provided a method of manufacturing a semiconductor device including:
forming an element region surrounded by an element-isolating region in a semiconductor region;
depositing a metal layer over an entire surface of the semiconductor region;
removing part of the metal layer on the element isolating thereby setting the ratio of the sum of pattern areas of the metal layer formed on the element region and element-isolating region occupied in a 1 μm-square range of interest including the element region at 25% or more; and
performing heat processing to form a metal silicide layer including the metal layer on the element-isolating region.
<Semiconductor Device and Manufacturing Method of First Embodiment>
In
In
On an n-type Si substrate 21, a p-well 41 is formed in which the real element region 11 and the dummy element regions 13 shown in
As a metallic material forming the metal silicide layer 48, a metal that forms a silicide by reacting with the impurity diffusion layer 47 of the Si substrate 21 or the gate electrode 44 (formed of polycrystalline silicon) at a temperature lower than that of Ti or Co, more specifically, Ni or Pt, may be used. In this embodiment, the metal silicide layer 48 is formed of a Ni silicide or a Ni/Ti silicide in which Ti stacked on Ni.
Next, a method of manufacturing an LSI according to the first embodiment will be explained sequentially in accordance with manufacturing steps with reference to.
First, as shown in
Next as shown in
Furthermore, using the SiO2 pattern 35 as a mask, the SiN film 32 is etched by anisotropic dry-etching in which the SiN film 32 has a satisfactory etch selectivity to an oxide film (SiO2 film 31), thereby forming a SiN film pattern 36. Furthermore, thin SiO2 film 31 is etched to form a SiO2 film pattern 37.
As shown in
As shown in
Thereafter, as shown in
Thereafter, the SiO2 film 37 on the Si substrate is etched away by NH4F and then a sacrificial oxide film 40 is formed of SiO2 by thermal oxidation at 800° C. Subsequently, boron (B) ions are implanted to the real element region and dummy element regions at an acceleration voltage of e.g., about 200 KeV and in a dose amount of about 8E12 cm−2, and further B ions are implanted to the real element region and dummy element regions at an acceleration voltage of e.g., about 50 KeV and in a dose amount of about 1E13 cm−2 to control the threshold voltage of an n-MOSFET formed in these regions. The impurities thus doped are activated by thermal processing at 1000° C. for 30 seconds to form a p-well 41 in the real element region and dummy element regions.
Next, a shown in
After that, the resist pattern 43 is removed and a SiO2 film of e.g., 2 nm thick is formed on the Si substrate by thermal oxidation. Furthermore, as shown in
Thereafter, as shown in
Thereafter, as shown in
Thereafter, as shown in
Next, as shown in
Thereafter, as shown in
Subsequently, for example, titanium (Ti) is deposited, by a sputtering method, on the bottom of the source/drain contact to a thickness of about 10 nm. Thereafter, thermal processing is performed at 600° C. for 30 minutes in a N2 atmosphere, thereby forming TiN on the surface of Ti. After that tungsten (W) of about 400 nm thick is deposited by a CVD method and then tungsten (W) on the BPSG film 50 is removed by CMP, thereby forming a buried contact 52 in the opening 51 of the source/drain contact, as shown in FIG. 8M. Thereafter, a wiring 53 is formed of, for example, Cu, so as to electrically in contact with the buried contact 52.
In the manufacturing method according to the first embodiment, in order to reduce the resistivity of each of the impurity diffusion layer of the source/drain region 47 formed in the substrate 21 and the gate electrode 44 of polycrystalline Si, a silicide process is performed to produce a reaction product of Ni and Si. At this time, a reaction region is defined in consideration of the diffusion (diffusion coefficient) of Ni in Si during the reaction, thereby suppressing an excessive amount of Ni supply and excessive diffusion of Ni into the reaction region. More specifically, a dummy element region 13 is formed such that the ratio of the reaction region to the region of interest, in other words, the ratio of the region where Si is present immediately under the Ni to the region of interest, is not less than a predetermined lowest value, about 25%, in this embodiment.
When the Ni silicide process is performed in this manner, the dummy element region 13 is formed to prevent an increase in area of the STI 12 (serves as a Ni supply source) surrounding the real element region 11. By virtue of this, excessive supply and diffusion of Ni to the reaction region can be suppressed, thereby preventing a silicide reaction from excessively proceeding in the contact region. As a result, a low resistant Ni silicide compound layer 48 free from contact current leakage is successfully formed.
The semiconductor device manufactured in accordance with the aforementioned method has the STI 12 formed in the Si substrate 21, and the real element region 11 and the dummy element regions 13 formed outside the STI 12. Furthermore, the semiconductor device is formed such that the ratio of the sum of pattern areas of the real element region 11 and the dummy element regions 13 occupied in the region of interest 10 is about 25%. Moreover, the Ni silicide compound layer 48 is formed in each surface of the real element region 11 and the dummy element region 13.
With this structure, a silicide reaction can be suppressed from excessively proceeding in the contact region when a Ni silicide process is performed. Since the presence of a low resistant silicide region causing no contact current leakage, the contact current leakage is suppressed from generating.
Note that, when the area of the real element region 11 is larger than the region of interest 10, as shown in
<Modified Examples of Semiconductor Device According of the First Embodiment>
In the LSI according to the first embodiment previously mentioned, the real element region 11 and the dummy element regions 13 having the same pattern areas are arranged lengthwise and crosswise at regular intervals, and the ratio of the sum of the pattern areas of the real element region 11 and the dummy element regions 13 occupied in the region of interest 10 is about 25%.
In contrast, a case where the sum of the pattern areas of the real element region 11 and the dummy element regions 13 occupies more than 25% of the region of interest 10 will be explained below as a modified example.
In this case, the sum of the pattern areas of the real element region 11 and the dummy element regions 13, 13a exceeds 25% of the area of the region of interest 10. As a result, more excellent effect than that of the first embodiment is expected.
In the dummy element region 13, the impurity diffusion layer 47 is formed over the entire surface of the well 41. On the upper surface of the impurity diffusion layer 47, a Ni silicide compound layer 48 is formed.
In the dummy element region 13, the Ni silicide compound layer 48 is formed on the surfaced of the well 41 itself. In this case, if the same conductivity-type impurity as used in the substrate 21 is used in the well 41, the potential of the Ni silicide compound layer 48 may be set at the same as that of the well 41. Therefore, different from the case where the conductivity-type of the impurities doped in the substrate 21 differs from that of the well 41, the well 41 is potentially floating. Therefore, an unstable parasitic capacitance is not produced and thus a highly controllable element can be designed.
<Semiconductor Device of Second Embodiment>
Even if such a structure is employed, excessive supply and diffusion to the reaction region of the real element region 11 can be suppressed during the silicide reaction, in the same manner as in the first embodiment, thereby suppressing excessive silicide reaction from taking place in the contact region. As a result, a low resistant silicide region free from contact current leakage can be formed.
<Semiconductor Device of Third Embodiment>
The dummy element region 13 is formed in the first embodiment in order to define the lowermost ratio of the reaction region occupied in the region of interest. The dummy electrode 14 is formed in the second embodiment in order to define the lowermost ratio of the reaction region occupied in the region of interest.
Whereas in the third embodiment, the first and second embodiments are combined. More specifically, the dummy element region 13 and the dummy electrode 14 are formed in order to define the lowermost ratio of the reaction region occupied in the region of interest.
Even if the structure shown in
<Other Embodiments of Method of Manufacturing Semiconductor Device>
When semiconductor devices according to the first to third embodiments are manufactured, the dummy element region 13 and/or the dummy gate electrode 14 are formed in order to define the lowermost ratio of the reaction region for Ni silicide process occupied in the region of interest.
Alternatively, after a metal causing an excessive Ni-silicide reaction is previously removed from an unreaction region, the Ni silicide process may be performed to define of the lowermost ratio of the reaction region occupied in the region of interest.
To describe more specifically, first, the steps shown in
Subsequently, before a Ni silicide compound is formed, a step for removing part of the Ni layer 15 formed on the STI 12 surrounding the real element region 11 is performed, as shown in FIG. 15. In this manner, the ratio of the pattern area of the Ni layer 15, which is formed on the real element region 11 and the STI 12, occupied in the region of interest (1 μm-square) including the real element region 11, is set at 25% or more.
Thereafter, in the same manner as in the manufacturing method of the first embodiment, heat processing is formed at 500° C. for 10 seconds in an N2 atmosphere to form a low resistant Ni silicide compound layer. Thereafter, the same steps as in the first embodiment are repeated.
According to the method of manufacturing a semiconductor device, a silicide process is performed after Ni causing an extra reaction is removed from the unreacted region such that the ratio of the reaction region occupied in the region of interest is the lowermost value or more. In this manner, in the same manner as in the manufacturing method of the first embodiment, excessive supply and diffusion of Ni to the reaction region can be suppressed during the silicide reaction. As a result, an excessive silicide reaction can be suppressed form taking place in the contact region, enabling the formation of a low resistant silicide region free from contact current leakage.
Additional advantages and modifications will readily occur to those skilled in the art. Therefore, the invention in its broader aspects is not limited to the specific details and representative embodiments shown and described herein. Accordingly, various modifications may be made without departing from the spirit or scope of the general inventive concept as defined by the appended claims and their equivalents.
Honda, Kenji, Oyamatsu, Hisato
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