Patent Grant
11217604
In recent years, since performance of semiconductor integrated circuits has been improved and power consumption of semiconductor integrated circuits has been reduced, it has been examined to use a silicon-on-insulator (SOI) substrate. An SOI substrate is a substrate in which a thin semiconductor layer is formed on an insulation layer, and complete isolation between elements is enabled by forming an element isolation film that reaches the insulation layer. Moreover, a junction leakage current or a junction capacitance can be largely reduced by forming an impurity diffusion layer in a region that extends to the insulation layer. Therefore, SOI substrates are suitable for semiconductor devices that are required to operate at high speed operation.
On the other hand, in a MOSFET using an SOI layer, a potential of a body region is in a floating state, and therefore, change in the potential of the body region influences an operation of the MOSFET. Fluctuations of the body potential (a floating body effect) cause variations of element characteristics and makes margin design of circuits difficult. Various measures have been considered to cope with the floating body effect, and a method in which an electrode is provided in the body region to fix a potential is a most reliable measure and has been commonly used.
As a method for forming a contact in the body region, a method in which a region (a body contact region) of a conductivity type reverse to a conductivity type of source/drain regions of the MOSFET is provided in the same element region in which the MOSFET is formed and a boundary therebetween is covered by a gate electrode formed into a T-shape, an L-shape, or an H-shape to isolate the element region and the body contact portion from each other is described in Japanese Unexamined Patent Publication No. 2002-134755 (Patent Document 1).
In the semiconductor device described in Patent Document 1, the gate electrode 108 extends to isolate the source region 102 or the drain region 104 from the body contact region 106 in consideration of salicide (self aligned silicide) process. That is, when the salicide process is employed, in a region in which the gate electrode 108 and a sidewall insulation film formed on side walls of the gate electrode 108 are not provided, an upper surface of the element region 100 is covered by a silicide film. Therefore, unless the gate electrode 108 is formed so as to isolate the source region 102 or the drain region 104 from the body contact region 106, these regions are electrically connected to each other via the silicide film. As described above, the body contact region can be isolated from the source region or the drain region by providing the gate electrode extending in the above described manner.
In the semiconductor device described in Patent Document 1, each of a width W1 of the connection portion with the body contact region 106 and a width W2 of the body contact region 106 is larger than a distance L between contact portions of a source and a drain of the transistor, and furthermore, a width W3 of a gate portion 108b that isolates the body contact region 106 from the source and the drain is larger than the widths W1 and W2.
As another method for forming a contact in a body region, a semiconductor device having a configuration in which a body contact region is led out from a body region of a transistor is described in Japanese Unexamined Patent Publication No. H09-252130 (Patent Document 2).
In a circuit used for a switch circuit or the like, a configuration in which transistors are connected in series in order to increase its breakdown voltage is used. An example of the configuration is described in Japanese Unexamined Patent Publication No. 2011-249466 (Patent Document 3). A circuit configuration is illustrated in FIG. 6 of Patent Document 3 and, as illustrated in FIG. 19 of Patent Document 3, a layout configuration in which respective sources and drains of transistors connected in series are connected via interconnects and which is not formed of one active region is employed.
In the semiconductor device described in Patent Document 1, the gate electrode extends also on the gate electrode 108b that isolates the body contact region 106 from the source region 102 or the drain region 104 via the gate insulation film, and therefore, a capacitance of a MOSFET, such as a capacitance of this region with a body portion via the gate insulation film, capacitances of a contact and an interconnect which are connected to the source or the drain via the sidewalls at sides of the gate, or the like, is increased. Therefore, in the semiconductor device including the body contact region 106, an extra gate capacitance or junction capacitance is increased, and an effect of reduction in parasitic capacitance which is an advantage of use of the SOI substrate cannot be sufficiently achieved.
One end of a gate length of the MOSFET is defined by the gate electrode 108 and the other end of the gate length of the MOSFET is defined by the element region 100. Therefore, there is a problem in which, in a lithography step performed in forming the gate electrode 108, when a position of the gate electrode 108 relative to the element region 100 is displaced, the gate length fluctuates.
There is also a problem in which, as illustrated in
In the semiconductor device described in Patent Document 2, the width W2 of the lead portion 202 that connects a body region 201 of the transistor and the body contact region 203 to each other is narrow, and therefore, a capacitance of a lead portion via the gate insulation film is smaller than that of the T-shaped gate described in Patent Document 1. However, the width W1 of the gate 206 that isolates the body contact region 203 from the source 204 and the drain 205 is three or more times wider than the width W2 of the lead portion 202, and therefore, a capacitance between the gate region and the body contact region or a wafer substrate is increased. Therefore, there is a problem in which the effect of reduction in parasitic capacitance which is an advantage of use of the SOI substrate cannot be sufficiently achieved.
In the present disclosure, a semiconductor device which includes a connection portion (a body contact) to which a potential of a body region in which a transistor is formed is connected and in which a gate capacitance can be reduced and deterioration of speed performance of the transistor can be suppressed will be described.
A semiconductor device according to the present disclosure is a semiconductor device including a first transistor and a second transistor formed in a same active region defined by an element isolation region, and the active region includes a body region in which the first transistor and the second transistor are formed, a connection portion to which a potential of the body region is connected, and a lead portion that connects the body region and the connection portion.
Each of the first transistor and the second transistor formed in the body region includes a channel region, a gate electrode formed on the channel region via a gate insulation film, and a source region and a drain region formed with the channel region interposed therebetween, and the source regions or the drain regions of the first transistor and the second transistor are formed in a common region and have a same potential.
Each of the lead portions extends from a corresponding one of the channel regions of the first transistor and the second transistor in a direction perpendicular to a channel direction such that the lead portions are isolated from each other, and each of the gate electrodes extends on a corresponding one of the lead portions, a width of each of the lead portions is narrower than a distance between corresponding ones of contact portions of the source regions and the drain regions of the first transistor and the second transistor, and a width of each of the connection portions is equal to or narrower than a width of a corresponding one of the gate electrodes extending on the lead portions.
According to the present disclosure, a semiconductor device which includes a body contact and in which a gate capacitance can be reduced and deterioration of speed performance of the transistor can be suppressed can be provided.
Embodiments of the present disclosure will be described in detail below with reference to the accompanying drawings. Note that the technology disclosed herein is not limited to the embodiments below. The embodiments of the present disclosure can be appropriately modified without departing from the scope of the present disclosure in which advantageous effects of the present disclosure can be achieved.
In the semiconductor device in this embodiment, a first transistor 11 and a second transistor 21 are formed in the same active region 1 defined by an element isolation film 303. The active region 1 includes a body region 10 in which the first transistor 11 and the second transistor 21 are formed, connections portions 18 and 28 to which a potential of the body region 10 is connected, and lead portions 17 and 27 that connect the body region 10 and the connection portions 18 and 28.
Each of the first transistor 11 and the second transistor 21 formed in the body region 10 includes a corresponding one of channel regions 12 and 22, a corresponding one of gate electrodes 14 and 24 which is formed on the corresponding one of the channel regions 12 and 22 via a corresponding one of gate insulation films 13 and 23, and a corresponding one of source regions 15 and 25 and a corresponding one of drain regions 16 and 26 with a corresponding one of the channel regions 12 and 22 interposed therebetween. The drain regions 16 and 26 of the first transistor 11 and the second transistor 21 are formed in a common region and have the same potential. Note that, in this embodiment, an N+ diffusion layer that forms the drain regions 16 and 26 is made common. In this embodiment, the drain regions 16 and 26 are formed in the common region, but the source regions 15 and 25 may be formed in a common region.
Each of the lead portions 17 and 27 extends from a corresponding one of the channel regions 12 and 22 of the first transistor 11 and the second transistor 21 in a direction perpendicular to a channel direction so as to be isolated from each other. Each of the gate electrodes 14 and 24 extends on a corresponding one of the lead portions 17 and 27.
In this embodiment, a width W1 of each of the lead portions 17 and 27 is narrower than a distance L between corresponding ones of contact portions 306 of the source regions 15 and 25 and the drain regions 16 and 26 of the first transistor 11 and the second transistor 21. A width W3 of each of the connection portions 18 and 28 is equal to or narrower than a gate width W2 of a corresponding one of the gate electrodes 14 and 24 that extend on the lead portions 17 and 27, respectively. Note that, as in this embodiment, when a sidewall insulation film 304 is formed on side surfaces of the gate electrodes 14 and 24, the gate width W2 of each of the gate electrodes 14 and 24 means a width including the sidewall insulation film 304.
With reference to
The SOI substrate includes an insulation layer 302 formed of a silicon oxide film formed on a silicon substrate 301 and an SOI layer formed of a single-crystal silicon layer formed on the insulation layer 302. In the SOI layer, an element isolation film 303 that defines the active region 1 is formed. The gate electrodes 14 and 24 are formed on the active region 1 via the gate insulation films 13 and 23, respectively.
The first transistor 11 and the second transistor 21 are formed of transistors of the same channel type. In this embodiment, an example in which N-channel transistors are used is described, but the first transistor 11 and the second transistor 21 may be formed of P-channel transistors.
The channel regions 12 and 22 of the first transistor 11 and the second transistor 21 are formed of a P− diffusion layer, and the source regions 15 and 25 and the drain regions 16 and 26 are formed of an N+ diffusion layer. Note that the N+ diffusion layer preferably reaches the insulation layer 302. The lead portions 17 and 27 are formed of a P− diffusion layer, and the connection portions 18 and 28 are formed of a P+ diffusion layer. The connection portions 18 and 28 are connected to each other by an interconnect layer 307 via the contact portions 306.
The element isolation film 303 is preferably formed using a so-called shallow trench isolation (STI) method in which, after a shallow trench is formed, an insulation film is buried in the trench.
In this embodiment, the width W1 of each of the lead portions 17 and 27 is equal to or narrower than the distance L between corresponding ones of the contact portions 306 of the source regions 15 and 25 and the drain regions 16 and 26 of the transistors 11 and 21, and thus, a configuration in which the gate capacitance has been reduced as compared to a known configuration is achieved.
It is sufficient that the gate width W2 of each of the gate electrodes 14 and 24 on the lead portions 17 and 27 is a width enlarged in accordance with a width of mask displacement with respect to a corresponding one of the lead portions 17 and 27, and therefore, the gate width W2 is equal to or narrower than the width enlarged by an amount corresponding to the width of mask displacement. Herein, the width of mask displacement can be equal to or narrower than ½ of a minimum processing dimension. For example, assuming that the minimum processing dimension is the width W1 of the lead portions 17 and 27, when the width W1 is 200 nm, the width of mask displacement can be made 100 nm or narrower.
As described above, the gate width W2 of the gate electrodes 14 and 24 on the lead portions 17 and 27 is made as narrow as possible, and thus, a capacitance of the gate between the gate and the silicon substrate 301 or the like can be reduced.
In consideration of a case in which an arrangement pitch of the first transistor 11 and the second transistor 21 is limited by an isolation width for the gate electrodes 14 and 24 on the lead portions 17 and 27, the layout area is set minimum, and therefore, the width W3 of the connection portions 18 and 28 is equal to or narrower than the gate width W2 of the gate electrodes 14 and 24 on the lead portions 17 and 27. Thus, the arrangement pitch of the first transistor 11 and the second transistor 21 can be made minimum. Moreover, the width W3 of the connection portions 18 and 28 is set narrow, and therefore, a capacitance with the corresponding gate can be set small.
According to this embodiment, the gate capacitance can be reduced, and also, the arrangement pitch of the transistors can be reduced, so that the layout area can be reduced. Thus, a semiconductor device in which deterioration of speed performance of the transistors can be suppressed can be provided.
Note that, in the example of
Herein, each of the connection portion 18 and the connection portion 28 extends to an upper portion and is connected to the interconnect layer 307 via the corresponding contact portion 306. That is, the connection portion 18 and the connection portion 28 are connected to each other via the interconnect layer 307.
In contrast, the connection portion 18 and the connection portion 28 may be directly connected to each other via an active region. The reference sign 310 denotes a non-active region and, in fabrication steps of fabricating a semiconductor device, the non-active region needs to have a certain area for convenience of processing. Therefore, the connection portions having the width W3 are arranged with a certain distance therebetween in many cases. The connection portion 18 and the connection portion 28 can be directly connected via an active region with a certain distance between the connection portion 18 and the connection portion 28.
In the first embodiment, the width W3 of the connection portions 18 and 28 is wider than the width W1 of the lead portions 17 and 27. In the first modified example, the width W3 of the connection portions 18 and 28 is the same as the width W1 of the lead portions 17 and 27. Thus, the layout can be simplified, and therefore, stable processability can be achieved. Furthermore, a configuration in which the gate capacity has been further reduced is employed, and therefore, further increase in operation speed can be achieved.
In the first embodiment, the connection portion 18 in the first transistor 11 and the connection portion 28 in the second transistor 21 are connected to each other in the interconnect layer 307 via the contact portions 306. In the second modified example, the connection portions 18 and 28 are connected to each other in a P+ diffusion layer 30. Thus, there is no need to provide the contact portion 306 and the interconnect layer 307 in one of the connection portions 18 and 28, that is, the connection portion 28 herein, and therefore, the connection portion 28 can be also used as another interconnect region. Accordingly, the degree of freedom of layout design can be increased.
In this application example, using transistors having the configuration described in the first embodiment, a logic circuit is configured. Specifically, in this application example, a configuration in which two three-input NAND circuits 41 and 42 are arranged is employed. The reference sign 43 denotes a ground voltage signal and the reference sign 44 denotes a power supply voltage signal. The circuit 41 is a circuit in which an output 40D is provided for three inputs 40A, 40B, and 40C.
In this application example, in each of four body regions 10A to 10D, three transistors are formed, and source regions and drain regions of the transistors are made common via a diffusion layer. Thus, the arrangement pitch of the transistors is minimized, and the layout area can be designed to be small.
In this application example, the three-input NAND circuits 41 and 42 are not isolated by an element isolation region but are connected via the body regions 10A and 10B, and gate electrodes 51 and 52 that turn off the transistors are formed on the body regions 10A and 10B. Thus, the two NAND circuits 41 and 42 are electrically isolated from each other. Note that the gate electrode 51 is connected to the ground voltage signal 43 and the gate electrode 52 is connected to the power supply voltage signal 44. The body regions 10A and 10B can be simplified by employing the above described layout. Therefore, increased process stability can be achieved, and furthermore, a product yield can be increased.
In this application example, using transistors having the configuration described in the first embodiment, a logic circuit is configured. Specifically, in this application example, a configuration in which two inverter circuits 61 and 62 are connected in series is employed. The reference sign 63 denotes a ground voltage signal and the reference sign 64 denotes a power supply voltage signal.
In this application example, drive capability of a transistor of the inverter circuit 62 is twice drive capability of a transistor of the inverter circuit 61. As the transistor of the inverter circuit 62, a transistor divided into two is used, and respective gates thereof are connected via a gate layer.
In this application example, a configuration in which a P-channel transistor and an N-channel transistor are connected to each other in a side in which respective regions thereof are opposed to each other is employed, but a layout in which the P-channel transistor and the N-channel transistor are connected to each other in a side in which respective connection portions thereof are arranged may be employed.
In the first embodiment, the first transistor 11 and the second transistor 21 are arranged in a perpendicular direction to a gate direction. In this embodiment, a third transistor 31 is further arranged in the gate direction with respect to the first transistor 11. Note that, in this embodiment, the third transistor 31 is formed in an active region that is the same as the active region 1 in which the first transistor 11 is formed.
The active region 1 includes a second body region 10B in which the third transistor 31 is formed, a second connection portion 38 to which a potential of the second body region 10B is connected, and a second lead portion 37 that connects the second body region 10B and the second connection portion 38. The second lead portion 37 extends from a channel region of the third transistor 31 in an opposite direction to the lead portion 17 of the first transistor 11, and the second connection portion 38 is formed with the connection portion 18 of the first transistor 11 in a common region so that the second connection portion 38 and the connection portion 18 have the same potential. In this embodiment, the connection portion 18 of the first transistor 11 and the second connection portion 38 of the third transistor 31 are formed of the same diffusion layer.
In this embodiment, the two connection portions 18 and 38 are made common, and thus, a layout area can be reduced. In some cases, the size of the element isolation regions cannot make a certain size or smaller than the certain size in terms of process. However, as described above, the two connection portions 18 and 38 are made common, and thus, the size of the element isolation regions can be ensured, so that the element isolation regions can be stably formed.
In this application example, using the configuration of the semiconductor device of the second embodiment, a logic circuit is configured. Specifically, in this application example, a configuration in which two three-input NAND circuits 41 and 43 are arranged is employed.
In this application example, the connection portion 18 of the transistor formed in the body region 10A in the circuit 41 and the connection portion 38 of a transistor formed in the body region 10B in the circuit 43 are made common, and thus, a layout area can be reduced. Note that, in this embodiment, only the connection portion 18 and the connection portion 38 are made common in a longitudinal direction, but the connection portion 18 and the connection portion 38 can be also made common with a connection portion of an adjacent transistor via an active region.
In the first embodiment, two transistors formed in a body region are transistors of the same channel type. In this embodiment, two transistors formed in a body region are complementary transistors. A semiconductor device according to this embodiment is an application example in which, using complementary transistors, a logic circuit (an inverter circuit) is configured.
In this embodiment, a P-channel transistor 11 and an N-channel transistor 21 are formed in the same active region 1 defined by the element isolation film 303. The active region 1 includes a body region 10 in which the transistors 11 and 12 are formed, connection portions 18 and 28 to which the potential of the body region 10 is connected, and lead portions 17 and 27 that connect the body region 10 and the connection portions 18 and 28 to each other.
Each of the transistors 11 and 12 formed in the body region 10 includes a corresponding one of channel regions 12 and 22, a corresponding one of gate electrodes 14 and 24 formed on the channel regions 12 and 22 via a gate insulation film, and a corresponding one of source regions 15 and 25 and a corresponding one of drain regions 16 and 26 formed with the corresponding one of the channel regions 12 and 22 interposed therebetween. The drain regions 16 and 26 of the transistors 11 and 21 are formed in a common region and have the same potential. Note that, in this embodiment, a silicide layer 305 is formed on the drain region 16 formed of an N+ diffusion layer and the drain region 26 formed of a P+ diffusion layer, and thus, the drain regions 16 and 26 have the same potential.
An input signal is connected to each of the respective gate electrodes 14 and 24 of the transistors, and the drain regions 16 and 26 that have been made common are outputs. In this embodiment, the connection portions 18 and 28 are led out in the same direction, and the connection portions 18 and 28 are connected to a power supply potential and a ground potential, respectively.
In this embodiment, a logic circuit can be formed in one active region 1, and the logic circuit can be configured in a compact region.
In this modified example, a configuration in which the connection portions 18 and 28 of the two transistors are led out in different directions is employed. Thus, the power supply potential and the ground potential can be led out in different directions. Therefore, when a plurality of logic circuits are arranged, respective connection portions in the logic circuits can be made common and thus arranged in a simple manner.
In this application example, two P-channel transistors and two N-channel transistors form a two-input NAND circuit. Gate electrodes 140A and 140D are first input signals, and gate electrodes 140B and 140C are second input signals. This configuration allows a compact layout with reduced dimensions in a height direction.
In this application example, two two-input NAND circuits 151 and 152 are arranged in a folded manner. This configuration allows a compact layout.
In the first embodiment, as illustrated in
In terms of a transistor, both of the lead portions 17 and 17B as channels also contribute to an operation a little. Therefore, the lead portions 17 and 17B are arranged in a direction perpendicular to the channel direction so as to be symmetrical with respect to the body region 10. Thus, even when a mask is displaced in the direction perpendicular to the channel direction in gate processing, fluctuations of transistor characteristics can be reduced. Thus, it is possible to design with stable transistor characteristics.
In this modified example, a configuration in which a connection portion 18B to which the potential of the body region 10 is connected is further connected to the lead portion 17B is employed. Thus, the potential of the body region 10 can be made common by the connection portions 18 and 18B formed at both sides of the body region 10, and therefore, more stable transistor characteristics can be achieved.
In the first embodiment, the width of the gate electrode 14 formed on the channel region and the width of the gate electrode 14 extending on the lead portion 17 are the same. In this embodiment, a width of a gate electrode 14A formed on a channel region and a width of a gate electrode 14B extending on the lead portion 17 are different. In
In this embodiment, the gate electrode 14A formed on the channel region is perpendicular to the boundary of the body region 10. Thus, even when a mask is displaced in the direction perpendicular to the channel direction in gate processing, fluctuations of transistor characteristics can be reduced.
Moreover, as illustrated in
In this embodiment, the width of the gate electrode 14A formed on the channel region and the width of the gate electrode 14B extending on the lead portion 17 are different, and a boundary S between the gate electrode 14A and the gate electrode 14B is positioned in an inner side than the boundary of the body region 10 in which transistors are formed.
In this embodiment, the boundary S between the gate electrode 14A formed on the channel region and the gate electrode 14B extending on the lead portion 17 is tilted by an angle of 135 degrees or more. Thus, an angle of each of the source region 15 and the drain region 16 of the transistor with respect to the gate electrode 14A is equal to or larger than 135 degrees. Therefore, even when a high voltage is applied between the source and the drain, occurrence of breakdown in an edge portion of the gate can be suppressed.
In this embodiment, a boundary S1 between the gate electrode 14A formed on the channel region and the gate electrode 14B extending on the lead portion 17 and a boundary S2 between the body region 10 in which transistors are formed and the lead portion 17 are perpendicular to each other. Thus, even when a mask is displaced in the direction perpendicular to the channel direction in gate processing, fluctuations of transistor characteristics can be reduced. Furthermore, even when a high voltage is applied between the source and the drain, occurrence of breakdown in an edge portion of the gate can be suppressed.
In a switch circuit that isolates a signal to an antenna, a high voltage is applied in some cases. To cope with this, a configuration in which a plurality of transistors are connected in series is employed. However, even in such switch circuits, it is required to reduce a capacitance in each position and ensure high speed characteristics.
As in this application example, source regions and drain regions of adjacent ones of the transistors are connected to each other not via an interconnect but via a diffusion layer, and thus, a capacitance in each of respective contacts connected to the source regions and the drain regions, a capacitance between an interconnect and a gate, and a capacitance between wafer substrates can be largely reduced.
As illustrated in
In the eighth embodiment, one transistor group including four transistors connected in series has been described. In this embodiment, as illustrated in
In
Although not illustrated in
In this embodiment, as illustrated in
In this embodiment, as illustrated in
In this embodiment, as illustrated in
In this embodiment, as illustrated in
A capacitance between Source 0 and Drain 3 illustrated in
The preferred embodiments of the present disclosure have been described above. However, the description herein is not limiting the present disclosure, but needless to say, various modifications can be made. For example, in the above described embodiments, examples in which transistors are formed on an SOI substrate have been described, but the present disclosure is not limited thereto. Transistors may be formed on a general silicon substrate.
In this case, a plan view of a semiconductor device according to the present disclosure is the same as that of the configuration illustrated in
The element isolation film 303 that defines the active region 1 is formed on the P− silicon substate 301, and the gate electrodes 14 and 24 are formed in the active region 1 via the gate insulation films 13 and 23. The channel regions 12 and 22 of the first transistor 11 and the second transistor 21 are formed of a P− silicon substate (or a P− well region formed in a silicon substate), and the source regions 15 and 25 and the drain regions 16 and 26 are formed of an N+ diffusion layer. The lead portions 17 and 27 are formed of the P− silicon substate (or a P− well region formed in a silicon substrate), and the connection portions 18 and 28 are formed of a P+ diffusion layer.
| Number | Date | Country | Kind |
|---|---|---|---|
| JP2017-152333 | Aug 2017 | JP | national |
| JP2017-206510 | Oct 2017 | JP | national |
This is a continuation of International Application No. PCT/JP2018/028741 filed on Jul. 31, 2018, which claims priority to Japanese Patent Application No. 2017-152333 filed on Aug. 7, 2017 and Japanese Patent Application No. 2017-206510 filed on Oct. 25, 2017. The entire disclosures of these applications are incorporated by reference herein.
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| International Search Report for PCT Application No. PCT/JP2018/028741, dated Oct. 23, 2018 in 4 pages. |
| Number | Date | Country | |
|---|---|---|---|
| 20200176476 A1 | Jun 2020 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/JP2018/028741 | Jul 2018 | US |
| Child | 16785035 | US |
