WO2006090445A1 - Semiconductor circuit device, and method for manufacturing the semiconductor circuit device - Google Patents

Abstract

To provide a semiconductor integrated circuit device, which has components of a fin-type FET suited for a high integration LSI and formed on a supporting substrate and which uses wires buried in trenches of the supporting substrate for connecting the components, and a method for manufacturing the semiconductor integrated circuit device. The semiconductor integrated circuit device comprises a MOS transistor element or the fin-type FET having a stereoscopic isolation area of silicon formed on a supporting substrate and a gate electrode formed on the surface of the stereoscopic isolation area of silicon, buried wires buried in trenches formed in self-alignment in the stereoscopic isolation area of silicon of the supporting substrate, and on-substrate wires on the supporting substrate. The MOS transistor elements are connected by the buried wires and the on-subsrate wires.

Description

 Specification

 Semiconductor circuit device and method of manufacturing the semiconductor circuit device

 Technical field

 TECHNICAL FIELD [0001] The present invention relates to a semiconductor integrated circuit device having a fin-type FET formed on a support substrate as a constituent element, suitable for highly integrated LSIs, and a method for manufacturing the same. In particular, the present invention relates to a semiconductor integrated circuit device using a wiring embedded in a groove in a support substrate and a manufacturing method thereof for connecting constituent elements.

 Background art

 [0002] Today's highly integrated LSI is composed of a huge number of logic macrocells. Therefore, the power required to increase the integration density of LSIs for improving the functions of LSIs is directly demanded for downsizing to logic macro cells. Here, the logic macrocell is a logic circuit such as a NOT circuit or a NAND circuit, and is formed into a cell as a result of patterning the circuit layout. Therefore, the reduction of the logic macrocell is a component of it.

 MOSFET (Metal

 Oxide Semiconductor Field-Effect-Transistor) Device size is greatly reduced.

By the way, reducing the size of the MOSFET involves increasing the current between the source and drain when the MOSFET is cut off, and decreasing the drive current when active. It was difficult to maintain the improvement. Therefore, a three-dimensional silicon (Si) region (hereinafter referred to as `` fin region '') is provided on the insulating support substrate as a region for the MOSFET, except for the surface of the Fin region that is in contact with the insulating support substrate. MOSFET structures (hereinafter referred to as “fin-type FETs”) in which the gate electrode is arranged in a band state are being adopted. This is because the current between the source and the drain caused by the substrate can be reduced by isolating the MOSFET region. In addition, the current path between the source and the drain on the surface of the fm region can be cut off by arranging the gate electrode in a band state. Furthermore, since the side of the three-dimensional Fin region can also be used as a current path, the drive current of the fm type FET increases. [0003] Therefore, in order to achieve both reduction in the size of the logic circuit and maintenance of performance improvement, an LSI configured with a logic circuit using a Fin-type FET on a support substrate has been proposed. For example, Patent Document 1 describes a processor configured by a conventional logic circuit using an fm type FET. In the following, we will explain the processor configured with a conventional logic circuit using fin-type FETs, using Fig. 1. The processor 1 of FIG. 1 includes at least one chip 2, which has a logic circuit 3 on its surface. These mouth circuit 3 include fm type FET4. The processor 1 is configured by interconnecting logic circuits 3.

 Therefore, since the fm type FET is used in the logic circuit 3 used for the processor 1 in FIG. 1, the logic circuit 3 is reduced in size. In addition, high integration of the processor 1 in FIG. 1 is realized.

 Patent Document 1: JP 2004-266274 A

 Disclosure of the invention

 Problems to be solved by the invention

However, the reduction in the layout area of the logic macro cell has a problem that it is greatly influenced not only by the reduction in the size of the MOSFET device but also by the structure and arrangement of the wirings connecting the circuit elements.

 Therefore, an object of the present invention is to provide a semiconductor circuit device that can reduce the layout area by making connections between circuit elements using wiring embedded in a groove in a support substrate. Another object of the present invention is to provide a method for manufacturing the semiconductor integrated circuit device.

 Here, examples of the structure and arrangement of wirings connecting circuit elements hinder the reduction of the layout area of the logic macrocell include the following.

First, when wiring MOSFET devices, wiring belonging to the same wiring layer cannot be crossed. It is also necessary to maintain the minimum wiring width and wiring spacing in the same wiring layer. Therefore, in the logic macrocell, there is a problem that it is necessary to secure a wiring area for connecting circuit elements while avoiding the crossing of wirings belonging to the same wiring layer. On the other hand, in order to solve the above problem, it may be possible to use two wiring layers. It is necessary to secure an alignment area for the connection between the path element and the wiring of each wiring layer, or the connection between the first layer wiring and the second layer wiring, and this does not necessarily reduce the size of the logic macro cell. There's a problem.

 Furthermore, it is necessary that the pattern shape of the wiring connecting the circuit elements be a shape that can be easily resolved in the photolithography process. If the pattern shape of the wiring is difficult to resolve, there is a problem that it is necessary to widen the interval between the wiring patterns in consideration of this point, and the size of the logic macrocell cannot be reduced.

 In addition, today, the interlayer insulating film of the wiring on the substrate tends to be thin, and there is a problem that the capacitance between wirings of the first layer wiring and the second layer wiring cannot be reduced. If this is done, the first layer wiring and the second layer wiring will be avoided, so there is a problem that the logic macrocell cannot be reduced. Means to solve the problem

[0005] In order to solve the above-mentioned problem, the first invention provides a support that is formed in a self-aligned manner with the fm type FET as a wiring for connecting a circuit element such as a fin type FET formed on a support substrate. Provided is a semiconductor circuit device characterized by using a buried wiring carried in a groove in a substrate.

 That is, the first invention provides a MOS transistor element having a silicon three-dimensional isolated region formed on a support substrate and a gate electrode formed on the surface of the three-dimensional isolated region, and a groove in the support substrate. Provided is a semiconductor device provided with embedded embedded wiring and on-substrate wiring on the support substrate. The semiconductor device is characterized in that connection between the MOS transistor elements is performed using the embedded wiring and the wiring on the substrate. In addition, it is desirable that the above-mentioned carrier wiring is formed in a self-aligned manner with the three-dimensional isolated region of the above-mentioned MOSFET element.

[0006] In order to solve the above-described problem, the second invention is the semiconductor device described in the first invention, wherein the carrier wiring is aligned in the first direction, and the wiring on the substrate is in the first direction. A semiconductor circuit device is provided that is aligned in a second direction orthogonal to the first direction.

That is, the second invention is the semiconductor circuit device according to the first invention, wherein the embedded wiring is arranged in the first direction, and the connection portion of the circuit element connected by the wiring on the substrate is Providing a semiconductor circuit device characterized by being arranged linearly in a second direction The Note that the first direction and the second direction are preferably orthogonal to each other.

[0007] In order to solve the above problems, a third invention is a method for manufacturing the semiconductor circuit device according to the first invention or the second invention, and is embedded in a self-aligned manner with an fm type FET. Provided is a method for manufacturing a semiconductor circuit device, characterized in that a wiring groove is formed and a buried wiring is formed in a self-aligning manner.

 That is, a third invention is a method of manufacturing the semiconductor circuit device according to the first invention or the second invention, wherein the solid isolated region forming step of forming the solid isolated region of the MOS transistor element and the method A groove forming process for forming a buried wiring groove in a substrate in a self-aligned manner with a three-dimensional isolated region; and a filling process for loading silicon and an etching selective carrier material into the carrier wiring groove. A gate electrode forming step for forming a gate electrode of the MOS transistor element; and a filling material in the groove for the carrier wiring is removed; a metal material is loaded in the groove for the carrier wiring; Provided is a method for manufacturing a semiconductor circuit device, comprising: a buried wiring forming step for forming a wiring; and an on-substrate wiring forming step for forming the on-substrate wiring. Silicon (GeGe) is the preferred material for etching with silicon.

 (The invention's effect)

 [0008] In the first invention, after the fin type FET formed on the support substrate is formed, the trench for the buried wiring is formed using the Fin type FET as an etching mask. Then, wiring between circuit elements can be performed using two wiring layers of the carrier wiring and the wiring on the board. Therefore, compared to connecting with the same wiring layer, the wirings belonging to the same wiring layer are crossed. Avoid wiring area for connecting circuit elements. In addition, since the positional relationship between the fin-type FET and the embedded wiring is determined in a self-aligning manner, it is not necessary to provide an area for positioning the fin-type FET and the embedded wiring. In addition, since the interlayer insulating film between the embedded wiring and the wiring on the substrate is thicker than the interlayer insulating film between the first wiring and the second wiring on the substrate, the inter-wiring capacitance is reduced. Then, the carrier wiring and the on-board wiring can be brought close to each other. Therefore, a reduced semiconductor circuit device can be provided.

[0009] Further, in the second invention, since the carrier wiring is arranged in the first direction, the arrangement interval between the carrier wiring and the Fin-type FET can be set to the minimum interval. The second direction orthogonal to the first direction Since the connection points of the circuit elements connected in the direction by the wiring on the substrate are aligned, the shape of the wiring on the substrate can be made linear. Further, when the wiring on the substrate is arranged in parallel, the wiring on the substrate can be arranged with a minimum interval. Furthermore, when the circuit pattern is formed by photolithography, the pattern is easily resolved if it is a linear pattern. Therefore, it is possible to provide a semiconductor circuit device that is further reduced in size than the semiconductor circuit device described in the first invention.

 [0010] Further, in the third invention, the trench for the buried wiring is formed in a self-aligned manner, and silicon 'genorenium (SiGe) is once loaded. Then, a process step to which heat treatment is applied after that, for example, the gate electrode of the fin-type FET can be formed of the poly-thincon layer. After the completion of the process step to which heat treatment is applied, the embedded wiring is formed by removing the silicon 'germanium (SiGe) from the buried wiring trench and placing the metal material in the buried wiring trench. I can do it. Therefore, after the embedded wiring is formed, no thermal stress is generated in the carrier wiring that is not subjected to heat treatment.

 Brief Description of Drawings

 FIG. 1 is a diagram illustrating a processor configured by a conventional logic circuit.

 FIG. 2 is a diagram showing a circuit layout of logic macrocells of a Not circuit, a Nand circuit, and a Nor circuit using the fin-type FET according to the first embodiment as circuit elements.

 FIG. 3 is a diagram showing a circuit layout of an SRAM macro cell in which an SRAM memory circuit according to Embodiment 2 having a fin-type FET as a circuit element is arranged.

 [Fig. 4] Fig. 4 shows the circuit layout of an SRAM macrocell that is a cell-type SRAM memory circuit according to the third embodiment, characterized by having a fin-type FET as a circuit element and using a shared contact. FIG.

 [FIG. 5] FIG. 5 shows a flowchart of the manufacturing process of the logic macro cell or SRAM macro cell.

 FIG. 6 is a diagram showing the detailed manufacturing process of the fin-type region forming process, which includes FIG. 6A, FIG. 6B, FIG. 6C, FIG. 6D, FIG. 6E, and FIG.

[FIG. 7] FIG. 7 is a diagram showing the details of the process for forming a trench for embedded wiring, which is composed of FIG. 7G, FIG. 7H, FIG. 71, FIG. 7], FIG. 7K, and FIG. is there. [FIG. 8] FIG. 8 is composed of FIG. 8M, FIG. 8N, FIG. 80, FIG. 8P, FIG. 8Q, and FIG. 8R, and shows the details of the groove forming process for the loading wiring.

 [FIG. 9] FIG. 9 is composed of FIG. 9R, FIG. 9S, FIG. 9T, FIG. 9U, FIG. 9V, and FIG. 9W. The details of the loading wiring process and the on-board wiring formation process (part 1) FIG.

 [Fig. 10] Fig. 10 is composed of Fig. 10R, Fig. 10SS, Fig. 10TT, Fig. 10UU, Fig. 10VV, and Fig. 10 stomach, and the loading wiring process and on-board wiring formation process (part 2) It is a diagram showing details.

 [FIG. 11] FIG. 11 is composed of FIG. 11XX, FIG. 11YY, and FIG. 11ZZ, and shows the details of the loading wiring process and the on-board wiring formation process (part 2).

 BEST MODE FOR CARRYING OUT THE INVENTION

 [0012] Hereinafter, Example 1, Example 2, Example 3, and Example 4 of the present invention will be described. Example 1

 (Logic macro sensing using fm type FET in Not circuit, Nand circuit, and Nor circuit) FIG. 2 shows a Not circuit having a fin type FET according to the first embodiment as a circuit element, a Nand circuit, and The circuit layout of the logic macrocell of the Nor circuit is shown. Note that fin means “fish carp”, and at the beginning, the fm region meant a three-dimensional region created by laying a triangular prism sideways. Today, however, the fm region is used to include an isolated three-dimensional region such as a rectangular parallelepiped. In addition, the fm-type FET has a three-dimensional fin region of silicon (Si) for MOSFET that is isolated on an insulating support substrate, and strips the gate electrode except for the surface of the fin region that contacts the insulating support substrate. This is the MOSFET placed in

 [0014] The upper and lower stages of FIG. 2A are circuit pattern examples of logic macrocells of Not circuits that use embedded wiring and wiring on a substrate for connecting circuit elements.

In the upper Not circuit in Fig. 2A, 5 is the wiring on the board that connects to the positive power supply, 6 is the P-channel inductor fin type FET, 7 is the N-channel fm type FET, 8 is the wiring on the board that connects to the input terminal, and 9 is Wiring on the board connected to the output terminal, 10 on the board connected to the ground power supply, 11 the carrier wiring, and 13 the contact Via. The on-board wirings 5, 8, 9, and 10 do not necessarily have to belong to a single wiring layer. For example, the on-board wiring 10 connected to the ground power supply and the on-board wiring 5 connected to the positive power supply belong to the second wiring layer and are connected to the input terminals. The subsequent on-board wiring 8 and the on-board wiring 9 connected to the output terminal may belong to the first wiring layer.

 The drain of the P-channel fin-type FET 6 and the on-substrate wiring 5 connected to the positive power supply are connected via a contact vial 3. The substrate 9 connected to the source of the P-channel fm type FET6, the drain of the N-channel fin-type FET7, and the output terminal is connected via the contact vial3. The gate electrode of the P-channel fin-type FET 6 and the gate electrode of the N-channel fin-type FET 7 are connected via the buried wiring 11 and the contact vial 3. The embedded wiring 11 and the on-board wiring 8 connected to the input terminal are connected via a contact vial 3. The source of the N-channel fin-type FET 7 is connected to the substrate wiring 10 connected to the ground power supply via the contact Via23.

 Therefore, the P-channel fin-type FET 6 and the N-channel fm-type FET 7 are connected in series between the positive power supply and the ground power supply, forming a not circuit, that is, an inverter circuit. The upper not circuit in Figure 2 outputs the logic signal received at the input terminal and the logic signal having inverted logic from the output terminal.

 In the upper circuit layout of Fig. 2A, the interlayer insulation layer between the carrier wiring 11 and the board wiring 5, 8, 9, 10 includes circuit elements such as fm type FETs. It is thicker than the insulating layer between the wiring layers that form 8, 9, and 10. Accordingly, the wiring capacity between the embedded wiring 11 and the on-board wirings 5, 8, 9, 10 is smaller than the wiring capacity between the plurality of wiring layers forming the on-board wirings 5, 8, 9, 10.

In the Not circuit layout at the bottom of Figure 2A, 15 is the wiring on the board connected to the positive power supply, 16 is the P-channel fin type FET, 17 is the N-channel fm type FET, 18 is the wiring on the board connected to the input terminal, 19 is On-board wiring connected to the output terminal, 20 on-board wiring connected to the ground power supply, 21 embedded wiring, 23 contact Via, and 24 wiring connection area. The on-board wirings 15, 18, 19, and 20 do not necessarily belong to the same wiring layer, but have the power S to belong to a plurality of wiring layers, as in the upper circuit layout of FIG. 2A.

The connection relationship of each component is the same as that of the upper Not circuit in FIG. 2A. The function of the lower Not circuit in FIG. 2A is the same as the function of the upper Not circuit in FIG. 2A. However, the gate electrode of P-channel f _ln type FET16 and the gate electrode of N-channel fm type FET17 are embedded. Force S connected via wiring 21 and contact via 23 are not connected, and embedded wiring 21 and the gate electrode of each fm type FET are connected directly via wiring connection area 24. Become. Also, the embedded wiring 21, the source contact via23 of the P-channel fin-type FET16, and the drain contact _v of the N-channel fin-type FET17 so that the embedded wiring 21 and the on-board wiring 19 intersect at right angles. It is also different in that ia23 is arranged. Furthermore, N channel fin type

FET 17 and P-channel fm type FET 16 and embedded wiring 21 are also different in that they are self-aligned. Therefore, it is possible to omit the area for alignment between the carrier wiring and the fm type FET gate electrode and the carrier wiring and the fin type FET fm area. Further, the carrier wiring 21 and the on-substrate wirings 15, 18, 19, and 20 are linear, and the pattern can be easily resolved when the pattern is formed by the photolithography technique. Furthermore, the embedded wiring 21 and the on-board wiring 19 can be arranged so as to overlap each other. Then, the layout area of the lower Not circuit in FIG. 2A is reduced compared to the layout area of the upper Not circuit in FIG. 2A.

 The upper and lower parts of Fig. 2B are examples of logic macrocell patterns of Nand circuits that use embedded wiring and wiring on the board to connect circuit elements.

In the layout of the upper Nand circuit in Figure 2B, 25 is the on-board wiring connected to the positive power supply, 26 and 33 are P-channel fm type FETs, 27 and 34 are N-channel fm type FETs, and 28 is connected to input terminal 1. Wiring on board, 36 is wiring on board connected to input terminal 2, 29 is wiring on board connecting to output terminal, 30 is wiring on board connecting to ground power supply, 31 and 35 are loading wiring, 38 is board The upper wiring 39 indicates a contact Via. Note that the on-board wirings 25, 28, 36, 29, and 30 do not necessarily belong to the same wiring layer, and may belong to a plurality of wiring layers, similar to the upper circuit layout of FIG. 2A.

The drain of the P-channel fin-type FET 26 is connected to the on-substrate wiring 25 connected to the positive power supply via the contact Via 39. The source of the P-channel fin-type FET 26 is connected to the drain of the N-channel fin-type FET 27 and the source of the P-channel f _ln- type FET 33 via the contact Via 39 and the substrate wiring 29 connected to the output terminal. The gate electrode of the P-channel fm type FET 26 is connected to the gate electrode of the N-channel fm type FET 27 and the on-substrate wiring 28 connected to the input terminal 1 through the carrier wiring 31 and the contact Via 39. The gate electrode of the P-channel fin type FET33 is connected to the gate electrode of the N-channel fm type FET34 through the buried wiring 35 and the contact Via39. Connect to the board wiring 36 connected to the pole and input terminal 2. The drain of the P-channel fin-type FET33 is connected to the substrate wiring 25 connected to the positive power supply via the contact Via39. The drain of the N-channel fin-type FET 34 is connected to the source of the N-channel fin-type FET 27 via the substrate wiring 38 and the contact Via 39. The source of the N-channel fm type FET 34 is connected to the on-board wiring 30 connected to the ground power supply via the contact Via 39.

 That is, the P-channel fin-type FETs 26 and 33 are connected in parallel between the on-board wiring 25 connected to the positive power supply and the drain of the N-channel fin-type FET 27, and the N-channel fin-type FET 27, 34 is connected in series between the source of the P-channel fm type FETs 26 and 33 and the on-board wiring 30 connected to the ground power source. Therefore, the P channel fm type FETs 26 and 33 and the N channel fin type FETs 27 and 34 constitute a so-called nand circuit. In addition, the Nand circuit in the upper part of Fig. 2B sends a logical signal indicating the inversion of the logical product (i.e., nand) from the input terminal 1 and the logical signal input from the input terminal 2 from the output terminal. Output.

 [0018] In the Nand circuit at the bottom of Figure 2B, 40 is on-board wiring connected to the positive power supply, 41 and 48 are P-channel fin FETs, 42 and 49 are N-channel fm FETs, and 43 is connected to input terminal 1. Wiring on the board to be connected, 56 is wiring on the board to be connected to the input terminal 2, 44 is wiring on the board to be connected to the output terminal, 45 is wiring on the board to be connected to the ground power supply, 46 and 50 are embedded wiring, 53 is the board Upper wiring 54 is a contact via, and 55 is a wiring connection region. The connection relationship of each component is the same as that of the upper Nand circuit in Fig. 2B. The function of the lower Nand circuit in Fig. 2B is the same as that of the upper Nand circuit in Fig. 2B.

 [0019] However, although the gate electrode of the P-channel fm type FET 41 and the gate electrode of the N-channel fm type FET 42 are connected via the embedded wiring 21, they are connected to the embedded wiring 21 without using the contact Via54. This differs from the fin type FET gate electrode in that it is directly connected in the wiring connection region 55. The gate electrode of P-channel fin-type FET48 and the gate electrode of N-channel fin-type FET49 are connected via carrier wiring 50, but without via Via54, carrier wire 50 and the gate of each fin-type FET It differs from the electrode in that it is connected directly in the wiring connection region 55. Carrier wiring 46, P channel fin type FET41 source contact Via54, N channel fm type so that the carrier wiring 46 and the upper layer wiring 47 intersect at right angles

FET42 drain contact Via54 and P channel fm type FET48 source contact Via54 is different in that it is placed.

 Furthermore, the P-channel fin-type FET 41 and the N-channel fm-type FET 42 are different from the carrier wiring 46 in that they are self-aligned. Also, the P-channel fin-type FET 48 and N-channel fin-type FET 49 are different from the embedded wiring 50 in that they are self-aligned.

 [0020] Accordingly, it is possible to omit the area for alignment between the carrier wiring and the fm FET gate electrode, and between the carrier wiring and the fm area of the fin FET. In addition, the carrier wirings 43 and 50 and the on-substrate wirings 40, 43, 44, 45, 53, and 56 are linear, and the pattern can be easily resolved when the pattern is formed by photolithography. Further, the embedded wiring 46 and the on-substrate wiring 44 can be arranged so as to overlap each other. As a result, the layout area of the lower Nand circuit in Figure 2B is reduced compared to the layout area of the upper Nand circuit in Figure 2B.

 [0021] The upper and lower stages of FIG. 2C are examples of Norma logic macrocell patterns using the carrier wiring and the wiring on the substrate for connecting circuit elements.

 In the upper Nor circuit of Fig. 2C, 57a is on-board wiring connected to the positive power supply, 57b and 63 are P-channel fin type FETs, 57c and 64 are N-channel fin type FETs, 58 is connected to input terminal 1 on the board Wiring, 66 on board wiring connected to input terminal 2, 59 on board wiring connected to output terminal, 60 on board wiring connected to ground power supply, 61 and 65 embedded wiring, 67 on board wiring 69 represents a contact Via. Note that the on-board wirings 57a, 58, 66, 59, 60, and 67 do not necessarily belong to the same wiring layer, and may belong to multiple wiring layers, as in the upper circuit layout of FIG. 2A. .

[0022] The drain of the P-channel fm type FET 57b is connected to the on-substrate wiring 57a connected to the positive power supply via the contact Via69. The gate electrode of the P-channel fm type FET 57b is connected to the gate electrode of the N-channel fin type FET 57C and the substrate wiring 58 connected to the input terminal 2 through the embedded wiring 61 and the contact Via 69. The source of the P-channel fin-type FET 57b is connected to the drain of the P-channel fin-type FET 63 via the substrate wiring 67 and the contact Via69. The source of the P-channel fin type FET 63 is connected to the drain of the N-channel fm type FET 57c and the drain of the N-channel fm type FET 64 via the substrate wiring 59 connected to the output terminal and the contact Via69. The gate electrode of the P-channel fin-type FET 63 is connected to the gate electrode of the N-channel fin-type FET 64 and the input terminal 2 through the buried wiring 65 and the contact Via 69. Connect to on-board wiring 66. The source of N-channel fin-type FET 57 and the source of N-channel fin-type FET 64 are connected to the on-board wiring 60 connected to the ground power supply. That is, the N-channel fin-type FET 57 and the N-channel fin-type FET 64 are connected in parallel between the substrate wiring 60 connected to the ground power supply and the source of the P-channel fin-type FET 63. The P-channel fin type FET 56 and the P-channel fm type FET 63 are connected in series between the on-board wiring 55 connected to the positive power supply and the drains of the N-channel fin type FET 57 and the N-channel fin type FET 64. Therefore, the N-channel fm FET 57, the N-channel fin FET 64, the P-channel fm FET 56, and the P-channel fin FET 63 constitute a so-called nor circuit. The upper NOT circuit in Fig. 2C outputs the inverted signal of the logical sum of the logical signals input from the on-board wiring 58 connected to the input terminal 1 and the on-board wiring 66 connected to the input terminal 2 from the output terminal. To do.

 [0023] In the Nor circuit at the bottom of Figure 2C, 70 is the on-board wiring connected to the positive power supply, 71 and 78 are P-channel fm type FETs, 72 and 79 are N-channel fm type FETs, and 73 is connected to input terminal 1. Wiring on board, 81 is wiring on board connecting to input terminal 2, 74 is wiring on board connecting to output terminal, 75 is wiring on board connecting to ground power supply, 76 and 80 are embedded wiring, 77 is board Upper wiring 82 represents a wiring connection region, and 83 represents a contact Via. Note that the on-board wirings 70, 73, 81, 74, 75, and 77 do not necessarily belong to the same wiring layer, and may belong to a plurality of wiring layers, similar to the circuit layout in the upper stage of FIG. 2A.

 The connection relationship of each component is the same as the Nor circuit in the upper part of Fig. 2C. The function of the lower Nor circuit in Fig. 2C is the same as that of the upper Nor circuit in Fig. 2C.

[0024] However, although the gate electrode of the P-channel fin-type FET 71 and the gate electrode of the N-channel fm-type FET 72 are connected via the embedded wiring 76, they are connected to the embedded wiring 76 without using the contact Via 83, respectively. The fin type FET gate electrode is directly connected in the wiring connection region 82. The gate electrode of the P-channel fin-type FET78 and the gate electrode of the N-channel fin-type FET79 are connected via the carrier wire 80, but without the contact Via83, the carrier wire 80 and each fm type It is directly connected to the gate electrode of the FET in the wiring connection region 82. Embedded wiring 80, P-channel fin type FET78 source contact Via83, N-channel fm type FET72 drain contact Via83 so that embedded wiring 80 and on-board wiring 74 connected to the output terminal intersect at right angles And the source contact Via83 of the N-channel fin-type FET79 Has been placed. Furthermore, the P-channel fm type FET 71 and N-channel fin type FET 72 and the embedded wiring 76 are self-aligned. Also, P channel fin type FET78 and N channel fin type

The FET 79 and the carrier wiring 80 are self-aligning.

Therefore, it is possible to omit the area for alignment between the buried wiring and the fin FET gate electrode and the buried wiring and the fin area of the fin FET. In addition, the embedded wirings 76 and 80 and the on-substrate wirings 70, 73, 74, 75, 77, and 81 are linear, and the pattern can be easily resolved when the pattern is formed by photolithography. Further, the embedded wiring 80 and the on-substrate wiring 74 can be arranged so as to overlap each other.

Therefore, compared with the layout area of the Nor circuit in the upper part of FIG. 2C, the layout area of the Nor circuit in the lower part of FIG. 2C is reduced.

 According to the circuit pattern shown in the upper part of FIGS. 2A, 2B, and 2C according to the first embodiment, the interlayer insulating film between the carrier wiring and the wiring on the substrate is thick because it includes each fin type FET. Therefore, the capacity between the carrier wiring and the on-board wiring is smaller than the capacity between the wiring layers to which the on-board wiring belongs. In this case, it is not necessary to avoid the embedded wiring and the board-shaped wiring from being close to each other. In addition, according to the circuit pattern shown in the lower part of FIGS. 2A, 2B, and 2C according to Example 1, the carrier wiring is connected to the fin region of each fin-type FET (the silicon formed on the support substrate). It is not necessary to secure the alignment area between the fin area and the loading wiring because it is formed in a self-aligned manner.

 In addition, the direction in which the carrier wiring is wired is aligned, and the contact via of each fm type FET is arranged so that the wiring on the board is straight. Therefore, in the formation of the wiring pattern on each substrate, the pattern can be easily resolved. Then, the interval between the wiring patterns on the substrate can be reduced.

 Furthermore, the embedded wiring and the on-board wiring are arranged so that there is a portion where the wiring direction of the embedded wiring and the substrate wiring are orthogonal to each other and the embedded wiring and the on-board wiring intersect. Therefore, the wiring can be arranged in a superimposed manner.

 From the above, according to the circuit patterns shown in FIGS. 2A, 2B, and 2C according to the first embodiment, the logic macrocell can be reduced.

Example 2 [0026] (SRAM macrocell using Fin-type FET)

 FIG. 3 is a diagram showing a circuit layout of an SRAM macro cell in which the SRAM memory circuit according to the second embodiment having a fin-type FET as a circuit element is used. 3A, 3B, 3C, and 3D.

 FIG. 3A is a circuit showing a part of the SRAM memory element. In some of the SRAM memory elements in Figure 3A, 85 and 86 are inverters, 87 is an input terminal, and 88 is an output terminal. One inverter inverts and amplifies the logic signal input from the input terminal 87 and outputs an output signal from the output terminal. The other inverter further inverts and amplifies the logic signal having the inverted logic from the output terminal, and feeds feedback to the input terminal 87 side. That is, a part of the SRAM memory element has a function of storing the logic of the logic signal from the input terminal 87.

FIG. 3B is a diagram showing a circuit layout including a fin-type FET that constitutes a part of the SRAM memory element of FIG. 3A, and embedded wiring and on-substrate wiring connecting the fin-type FET. . In Fig. 3B, 90 is on-board wiring connected to the positive power supply, 91 and 93 are P-channel fin type FETs, 92 and 94 are N-channel fin type FETs, 95 and 96 are carrying wirings, and 97 is ground power supply. On-board wiring to be connected, 98 is on-board wiring to be connected to the input terminal, 99 is on-board wiring to be connected to the output terminal, and 100 is a contact via.

 Note that the above-mentioned wirings 90, 97, 98, 99 on the substrate do not necessarily need to be composed of one wiring layer. For example, the board wiring 98 connected to the input terminal and the board wiring 99 connected to the output terminal are the first layer board wiring, the board wiring 90 connected to the positive power supply, and the board connected to the ground power supply. The wiring 97 may have a plurality of wiring layer forces such as a second-layer wiring on the substrate.

Then, the gate electrode of the P-channel fin type FET 91 is connected to the gate electrode of the N-channel fm type FET 92 via the buried wiring 95 and the contact vial OO, the carrier wiring 95, the on-board wiring 98 connected to the input terminal, and The contacts are connected to the source of P-channel fin-type FET93 and the drain of N-channel fin-type FET94 via vialOO. The drain of the P-channel fin-type FET 91 is connected to the on-board wiring 90 connected to the positive power supply. The source of the P-channel fin-type FET91 is N-channel via the substrate wiring 99 connected to the output terminal and the contact vialOO. Connect to the drain of fin type FET 92 and connect to the output terminal on the board wiring 99, buried wiring 96, and contact vial OO, the gate electrode of P channel fin type FET 93 and the gate electrode of N channel fin type FET 94 Connecting. The drain of the P-channel fin-type FET 93 is connected to the on-substrate wiring 90 connected to the positive power supply via the contact vialOO. N channel fin type

 The source of FET94 is connected to the on-board wiring 97 connected to the ground power supply via the contact vialOO. The source of the N-channel fm type FET92 is connected to the on-board wiring 97 that is connected to the ground power supply via the contact vialOO.

Therefore, the P-channel fin type FET 91 and the N-channel fm type FET 92 are connected in series between the positive power source and the ground power source, and form a not circuit, that is, an inverter circuit.

The P-channel f _ln type FET 93 and the N-channel fin type FET 94 are connected in series between the positive power supply and the ground power supply, and form a not circuit, that is, an inverter circuit. As a result, as explained in FIG. 3A, the entire circuit has the same function as a part of the SRAM memory element.

 Here, in the circuit layout of FIG. 3B, since circuit elements such as fin-type FETs are included, the interlayer insulation layer between the embedded wiring 95, 96 and the wiring 90, 97, 98, 99 on the board is It is thicker than the insulating layer between the plurality of wiring layers constituting the upper wiring 90, 97, 98, 99. Therefore, the wiring capacity between the embedded wiring 95, 96 and the on-board wiring 90, 97, 98, 99 is smaller than the wiring capacity between the plurality of wiring layers forming the on-board wiring 90, 97, 98, 99. .

 [0029] FIG. 3C is a diagram showing a circuit layout including the fm type FET constituting a part of the SRAM memory element of FIG. 3A, and the embedded wiring and the wiring on the substrate for connecting the fm type FET. The points are the same as in Fig. 3B. Some patterns of force-carrying wiring are formed in a self-aligned manner with the fin region of the fin-type FET, and the connection between the gate electrode of the fm-type FET and the loading wiring The circuit layout is different in that the connection is made without using the contact via.

[0030] In FIG. 3C, 105 is a substrate wiring connected to a positive power source, 106 and 107 are P channel fm type FETs, 108 and 109 are N channel fin type FETs, 110 is a substrate wiring connected to a ground power source, 111 Is the on-board wiring connected to the output terminal, 112 is the on-board wiring connected to the input terminal, 113 is the contact Via, 114 is the wiring connection area, and 115, 116, 117, and 118 are the carrier wiring. Note that the on-board wirings 105, 110, 111, and 112 belong to a plurality of on-board wiring layers. This is the same as the circuit layout in Fig. 3B.

 The drain of the P-channel fin-type FET 106 is connected to the on-substrate wiring 105 connected to the positive power source via the contact vial 13. The gate electrode of the P-channel fin type FET 106 is connected to one end of the gate electrode of the N-channel fm type FET 108 via the buried wiring 115. The other end of the N-channel fin-type FET 108 is connected to the source of the P-channel fin-type FET 107 and the N-channel fin-type FET 109 via the embedded wiring 117, the on-board wiring 112 connected to the input terminal, and the contact vial 13. It is connected to the drain. The source of the P-channel fm type FET 106 is connected to the drain of the N-channel fm type FET 108 via the substrate wiring 111 connected to the output terminal, and further, the substrate wiring 111 connected to the output terminal, the contact via, and Connected to one end of the gate electrode of P-channel fin-type FET 107 via buried wiring 116. The other end of the gate electrode of the P-channel fin-type FET 107 is connected to the N-channel fm type via the carrier wiring 118.

 Connect to the gate electrode of FET109. The drain of the P-channel fm type FET 107 is connected to the on-board wiring 105 that is connected to the positive power supply via the contact via. The source of the N-channel fm type FET 108 is connected to the on-board wiring 110 connected to the ground power supply via the contact via. The source of the N-channel fin type FET 109 is connected to the on-board wiring 110 connected to the ground power supply via the contact via.

 In the circuit layout of FIG. 3C, a part of the embedded wiring pattern is formed in a self-aligned manner with the fin region of the fm type FET, so that the interval between the fm type FET and the embedded wiring can be reduced.

 In addition, since the fin FET gate electrode and the carrier wiring were connected without a contact via, the positions of the fm FET gate electrode and the contact via and the buried wiring and the contact via in the alignment region. The alignment area can be omitted.

 Furthermore, the contact vias are aligned so that the embedded wiring and the fin region of the fin-type FET are aligned in one direction and the wiring on the substrate is linear. The resolution increases. As a result, the interval between patterns can be reduced.

 Therefore, the layout area can be reduced as compared with the circuit layout of FIG. 3B.

[0032] FIG. 3D is a diagram showing a circuit layout including an fm type FET that constitutes a part of the SRAM memory element of FIG. 3A, and embedded wiring and wiring on the substrate that connect the fm type FET. Is Similar to Fig. 3B, but the carrier wiring pattern is formed in a self-aligned manner with the fin region of the fin-type FET, and via the contact via when connecting the gate electrode of the fm-type FET and the carrier wire. The circuit layout is different in that they are connected. In addition, when comparing the circuit layout of Fig. 3C, the difference is that the entire pattern of the carrier wiring is formed in a self-aligned manner with the fin region of the fin-type FET.

 In Fig. 3D, 120 is the on-board wiring connected to the positive power supply, 121 and 122 are P-channel fin-type FETs, 123 and 124 are N-channel fin-type FETs, 125 is the on-board wiring connected to the ground power supply, and 126 is the output terminal , 127 is a contact via, 129 is a wiring connection region, and 130 and 131 are carrier wirings. It is to be noted that the on-board wirings 120, 125, 126, and 127 belong to a plurality of wiring layers on the substrate, which is the same as the circuit layout of FIG. 3B.

 In Fig. 3D, the connection relationship between the embedded wiring and the wiring on the substrate that connects the gate electrode of each fm FET, the source of each fin FET, the drain, input terminal, and output terminal of each fin FET is This is the same as the connection relationship in FIG. 3B. However, the connection between the gate electrode of each fm type FET 121, 122, 123, 124 and the carrier wiring 130, 131 is made by direct connection in the contact line connection region 129, not through the contact vial 28. It is different. Another difference is that embedded wirings 130 and 131 are formed in a self-aligned manner in the fm region of each fm type FET. Further, the contact Vial 28 is also arranged so that the on-board wiring 126 connected to the output terminal and the on-board wiring 127 connected to the input terminal are linear. In addition, the carrier wiring 130 and the on-board wiring 126 connected to the output terminal cross each other, and the carrier wiring 131 and the on-board wiring 127 connected to the input terminal cross each other. Is different.

The P channel fin type FET 121 and the N channel fm type FET 123 constitute an inverter, and the P channel f _ln type FET 122 and the N channel fin type FET 124 constitute an inverter as in FIG. 3B. Also, P channel fin type FET121, 122 and N channel fin type

Similarly, the FETs 123 and 124 constitute a part of the SRAM storage element.

According to the circuit patterns shown in FIG. 3B, FIG. 3C, and FIG. 3D according to the second embodiment, the interlayer insulating film between the carrier wiring and the wiring on the substrate becomes thick because each fin type FET is included. Therefore, buried The capacitance between the embedded wiring and the on-board wiring is smaller than the capacitance between the on-board wiring layers to which the on-board wiring belongs. In this case, it is not necessary to avoid the embedded wiring and the board-shaped wiring from being close to each other. In addition, according to the circuit patterns shown in FIG. 3C and FIG. 3D according to Example 2, the embedded wiring is connected to the fm region of each fin-type FET (the three-dimensional independent region of silicon formed on the support substrate) and self Since it is formed in a consistent manner, it is not necessary to secure an alignment region between the fm region and the embedded wiring.

 In addition, the wiring direction of the carrier wiring is aligned, and the contact via position of each fm type FET is arranged so that the wiring on the board is linear. Therefore, the pattern can be easily resolved in the formation of each pattern. Then, the interval between the wiring patterns on the substrate can be reduced.

 Furthermore, the embedded wiring and the on-board wiring are arranged so that there is a portion where the wiring direction of the embedded wiring and the substrate wiring are orthogonal to each other and the embedded wiring and the on-board wiring intersect. Therefore, the wiring is arranged in a superimposed manner.

 From the above, according to the circuit patterns shown in FIGS. 3B, 3C, and 3D according to the second embodiment, the logic macrocell can be reduced.

 Example 3

 [0034] (SRAM macrocell using fm type FET and using shared contact as contact)

 FIG. 4 is a diagram showing an SRAM macro cell circuit layout in which the SRAM memory circuit according to the third embodiment is made into a cell, which has an fm type FET as a circuit element and uses a squired contact. is there. 4A, 4B, 4C, and 4D. FIG. 4A is a circuit showing a part of the SRAM memory element. In a part of the SRAM memory element of FIG. 4A, 130 and 131 are inverters, 132 is an input terminal, and 133 is a wiring on a substrate connected to an output terminal.

 The operation and function of the circuit showing part of the SRAM memory element in FIG. 4A are the same as those of the circuit showing part of the SRAM memory element in FIG. 3A.

[0035] FIG. 4B is a circuit layout including an fm type FET constituting a part of the SRAM memory element of FIG. 4A, a buried wiring connecting the fin type FET, and a wiring on the substrate. Share the best It is the figure which showed the circuit layout characterized by using a contact.

 As in Fig. 3C, part of the embedded wiring pattern was formed in a self-aligned manner with the fm region of the fm type FET, and when connecting the gate electrode of the fm type FET and the carrier wiring, the contact via was used. The circuit layout is characterized in that it is connected to each other, and the circuit layout is characterized in that a shared contact is used.

 [0036] In FIG. 4B, 135 is a substrate wiring connected to a positive power source, 136 and 137 are P-channel fin type FETs, 138 and 139 are N channel fin type FETs, 140 is a substrate wiring connected to a ground power source, 141 Is the on-board wiring connected to the output terminal, 142 is the on-board wiring connected to the input terminal, 143 is the contact via, 144 is the wiring connection area, 145, 146, 147, 148 are embedded wiring, 149 is the shared contact Respectively. Note that the above-mentioned wirings 135, 140, 141, 142 on the substrate do not necessarily have to be configured with a single wiring layer force. For example, the board wiring 142 connected to the input terminal and the board wiring 141 connected to the output terminal are the first layer board wiring, the board wiring 135 connected to the positive power supply, and the board wiring connected to the ground power supply. 140 may have a plurality of wiring layer forces such as a second layer wiring on the substrate.

[0037] In FIG. 4B, each fm type FET, each power source, and each terminal are connected by a buried wiring, a wiring on a substrate, and the like as in FIG. 3C. However, if the drain of the N-channel fm FET 138 and the carrier wiring 146 are connected via the on-board wiring 141 that connects to the output terminal, the carrier wiring 146 and the drain of the N-channel fm FET 138 are close to each other. Therefore, the difference is that the shared contact 149 is used to connect to the on-board wiring 141 connected to the output terminal. Also, when the P-channel fm type FET137 source and embedded wiring 147 are connected via the on-board wiring 142 that connects to the input terminal, the carrier wiring 147 and the drain of the P-channel fin type FET137 are close to each other. Therefore, it is different in that the shared contact 149 is used to connect to the on-board wiring 142 connected to the input terminal. Here, the shared contact means that when two or more patterns are connected to the same wiring pattern, the same wiring pattern and the contact via position of one pattern and the contact of the same wiring pattern and the other pattern are used. A contact that is made close to and connected to a via position to form a single contact via. That is, the same wiring pattern and one pattern are connected to a part of the shared contact, and the same wiring and the other pattern are connected to the remaining shared contact part. It becomes the form where the screen connects.

Accordingly, it is possible to reduce the area for obtaining the minimum interval between the contacts via. For example, in FIG. 4B, a force that normally requires a contact via on the carrier wiring 146 and a contact via on the drain of the N-channel fm FET 138 connects the above two contact vias to form a side contact. As a result, the necessary area between the contacts via can be reduced, and the distance between the drain of the N-channel fm type FET and the buried wiring 146 can be reduced. Therefore, the circuit layout area can be further reduced as compared with the circuit layout of FIG. 3C.

 [0039] FIG. 4C is a circuit showing an SRAM memory element. In the SRAM memory element of Figure 4C,

 152 and 153 are signal lines, 154 and 155 are inverters, 156 and 157 are transfer gate transistors, 158 is an input terminal, and 159 is an output terminal.

 The SRAM storage element in FIG. 4C has a configuration in which transfer gate transistors 156 and 157 are added to a circuit showing a part of the SRAM storage element in FIG. 4A. In addition, in the operation and function of the circuit showing the SRAM memory element in FIG. 4C, the parts of the inverters 154 and 155 having the same configuration as the circuit showing a part of the SRAM memory element in FIG. Has the same operations and functions as 4A.

On the other hand, the transfer gate transistor 156 of the circuit showing the SRAM storage element of FIG. 4C is a signal line indicating whether or not to receive the logic signal stored in the inverters 154 and 155 from the input terminal 158. It has a function to select according to the logic of 152. That is, when a potential of logical value “H” is applied to the gate electrode of the transfer gate transistor 156, the circuit showing the SRAM memory element in FIG. 4C accepts the input signal. In addition, when the potential of the logical value “L” is applied to the gate electrode of the transfer gate transistor 156, the circuit showing the SRAM memory element in FIG. 4C does not accept the input signal. On the other hand, the transfer gate transistor 157 in the circuit showing the SRAM memory element in FIG. 4C selects whether or not to output the logic signal stored in the inverters 154 and 155 by the logic of the signal 153. That is, when a potential of logical value “H” is applied to the gate electrode of the transfer gate transistor 158, the circuit showing the SRAM memory element in FIG. 4C outputs an output signal. When a potential of logical value 'L' is applied to the gate electrode of the transfer gate transistor 157, the circuit showing the SRAM memory element in FIG. 4C outputs an output signal. I do not power.

 [0042] FIG. 4D is a circuit layout including a fin-type FET constituting the SRAM memory element of FIG. 4C and a carrier wiring and a wiring on the substrate for connecting the fm-type FET, and a shared contact is partly included in the circuit layout. It is the figure which showed the circuit layout characterized by using this.

 In Figure 4D, 160 is on-board wiring connected to the positive power supply, 161 and 162 are P-channel fin type FETs, 163, 164, 165 and 166 are N-channel fm type FETs, 167 is on-board wiring connected to the ground power supply, 168 is the on-board wiring connected to the output terminal, 169 is the on-board wiring connected to the input terminal, 170 and 171 are the on-board wiring, 172 and 173 are the embedded wiring, 174 is the contact Via, 175 is the shared contact, 176 Is the wiring connection area, and 177 and 178 are the wirings on the board that are connected to the signal lines. The on-board wiring 160, 167, 168, 169, 170, 171 need not be composed of one wiring layer, and may be composed of a plurality of wiring layers.

[0043] The drain of the P-channel fin-type FET 161 is connected to the on-substrate wiring 160 connected to the positive power source via the contact vial 74. The source of the P-channel fm type FET 161 is connected to the drain of the N-channel fm type FET 164 through the substrate contact 170 at the shared contact 175. The source of the P-channel fin type FET161 is the board wiring 170 through a contact _v Ial74, connected to the drain of N-channel fm type FET 165. Furthermore, the source of the P-channel fm type FET 161 is connected to the gate electrode of the P-channel fin type FET 162 and the N-channel via the on-board wiring 170 and the carrier wiring 173 via the shade contact 175, the contact vial 74, and the wiring connection region 176 It is connected to the gate electrode of fin type FET166.

The gate electrode of the P-channel fin type FET 161 is connected to the gate electrode of the N-channel fm type FET 165 through the wiring connection region 176 by the embedded wiring 172. The gate electrode of the P-channel fm type FET161 is by Tankomi wiring 172 and the board wiring 171, the wiring connection area 176, is connected to the source of P-channel fin type FET162 through contact _{v ial74.} Furthermore, the gate electrode of the P-channel fin-type FET 161 is connected to the drain and N of the N-channel fin-type FET 166 via the buried wiring 172 and the on-substrate wiring 171 via the contact line connection region 176, the contact vial 74, and the shared contact 175. Connected to the source of channel fm type FET163.

[0044] The source of the N-channel fin-type FET 164 is connected to the input terminal 168 via a contact vial 74. N channel fin type FET165, 166 source is grounded via contact vial74 Connected to on-board wiring 167 connected to The drain of the P-channel fin-type FET 162 is connected via a contact vial 74 to a substrate wiring 160 that is connected to the positive power supply. The drain of the N-channel fin type FET 163 is connected to the on-board wiring 168 connected to the output terminal via the contact vial 74. The gate electrode of the N-channel fm type FET163 is connected to the on-substrate wiring 178 that is connected to the signal line. The gate electrode of the N-channel fm type FET 164 is connected to the substrate wiring 177 connected to the signal line.

 By using the shared contact 175, it is not necessary to provide a space for arranging two normal contact vials 74, so that the space between the N-channel fm type FET164 and the P-channel fin-type FET161 can be further reduced. Similarly, by using the shared contact 175, the distance between the N-channel fin-type FET 163 and the N-channel fm-type FET 166 can be further reduced. Therefore, the circuit layout of the SRAM memory element can be reduced by using the shared contact 175.

 Example 4

 [0045] (Manufacturing process of logic macro cell or SRAM macro cell using Fin type FET)

 Using FIG. 5, FIG. 6, FIG. 7, FIG. 8, FIG. 9, FIG. 10, and FIG. 11, as the fourth embodiment, manufacturing the logic macro cell or SRAM macro cell shown in the first, second, and third embodiments A process is shown.

 Figure 5 shows a flowchart of the manufacturing process of a logic macrocell or SRAM macrocell.

 In FIG. 5, 180 is a fin region forming process, 181 is an fm region, 182 is an insulating support substrate, 183 is a groove forming step, 184 is a groove for buried wiring, and 185 is silicon-germanium (SiGe) loaded Process, 186 is silicon, germanium (SiGe), 187 is a gate electrode formation process, 188 is a polysilicon (P-Si) layer, 189 is a loading wiring process, 190 is a cavity, 191 is a metal (metal), 192 is a substrate Each upper wiring formation process is shown.

 [0047] The flowchart of FIG. 5 shows that the manufacturing process of the logic macro cell or SRAM macro cell is the fm region forming process 180, the groove forming process 183, the silicon germanium (SiGe) embedding process 185, the gate electrode forming process 187, and the embedding process. It shows that it consists of a wiring process 189 and a wiring formation process 192 on the substrate.

[0048] The fm region forming step 180 is a three-dimensional region made of a semiconductor on the insulating support substrate 182. This is a process for forming the fin region 181. The above semiconductor is preferably silicon (Si). In addition, the insulating support substrate 182 preferably has a silicon oxide film at an insulating portion desired by SOI (Silicon on insulator). The groove forming step 183 is a step of forming the groove 184 for the carrier wiring on the insulating support substrate 182. The SiGe loading process 185 is a process in which silicon germanium (SiGe) 186 is embedded in the trench 184 for embedded wiring in the insulating support substrate 182.

[0049] The gate electrode forming step is a step of forming the gate electrode of the fm type FET by using, for example, polysilicon (P-SD188 or other conductive material. The first procedure is as follows: First, an insulating film is deposited on the gate electrode, and then a contact via is formed on the silicon 'germanium trapped in the trench. Then, contact is made by depositing metal 191. Next, heat treatment is performed to form a buried wiring by utilizing the substitution phenomenon of silicon and metal by the heat treatment. The metal used for metal replacement is preferably aluminum (A1), and the second step in the embedded wiring process is as follows: First, silicon germanium (SiGe) 186 is used for loading wiring. Selectively remove from groove 184. Next, groove 1 for buried wiring 84 is a cavity 190, and then metal (metal) 191 is embedded, and tungsten is preferred as the above metal.

 [0050] When the embedded wiring process 189 is performed in the first procedure, the on-board wiring forming process 192 leaves the metal (metal) layer used for the replacement of the silicon and the metal as it is, and the metal (metal) layer A wiring pattern is formed on the resist pattern, and wiring is formed by etching. On the other hand, when the carrier wiring process 189 is performed by the second procedure, in the on-substrate wiring forming process 192, first, an insulating layer is formed, a contact via is formed with respect to the embedded wiring, etc. (Metal) After depositing 191, a wiring pattern is formed by a resist pattern, and wiring is formed by etching. In addition, the wiring on the substrate is not always formed by only one wiring layer. Moreover, aluminum (Al), tungsten (W), etc. are desirable for the metal used for wiring on the substrate.

[0051] FIG. 6 is a diagram showing the detailed manufacturing process of the fin-type region forming process, which includes the force shown in FIGS. 6A, 6B, 6C, 6D, 6E, and 6F. . FIG. 6 is a diagram showing a cross section between A and B in FIG. 2A. In FIG. 6, 195 is a silicon oxide film (Si02) layer, 196 is a single crystal layer of silicon, 197 is a silicon oxide film (Si02) layer, 198 is a polysilicon (P-Si) layer, 199 is a resist pattern, 200 Denotes an isolated region of polysilicon, 201 denotes an interlayer insulating film of a silicon oxide film (Si02), 202 denotes a sidewall of the silicon oxide film, and 203 denotes an isolated region of the silicon oxide layer.

 [0052] FIG. 6A shows that a silicon oxide film 197 and a polysilicon (P_Si) layer 198 are formed on a S0I substrate including a silicon oxide film layer 195 and a silicon single crystal layer 196 by a chemical vapor deposition (CVD) method. FIG. The SOI substrate was prepared by forming a silicon oxide layer on a silicon substrate and then sticking the silicon substrate on the silicon oxide layer. Therefore, a single crystal layer of silicon has a structure in which a silicon oxide film is sandwiched. In addition, in the SOI substrate, the silicon single crystal layer on the circuit element forming side is thinned by polishing or the like compared to the silicon single crystal side on the opposite side. That is, FIG. 6A shows a silicon single crystal layer 196 and a silicon oxide film 195 on the circuit element forming side of the silicon single crystal layer. Here, the thickness of the silicon oxide film layer 195 in the SOI substrate is preferably 70 nm or more, and preferably about lOO nm. The thickness of the silicon single crystal layer 196 is preferably about 30 nm. Further, it is desirable that the silicon oxide film 197 is about 10 nm, and the thickness of the polysilicon (P-Si) layer 198 is about 30 nm.

 FIG. 6B is a diagram showing a resist pattern 199 formed by applying a resist on the polysilicon (P-Si) layer 198 and using a photolithography technique. Since the width of the resist pattern 199 determines the interval between the fm regions of the fm type FET, it is preferably about 80 nm to 150 nm.

 FIG. 6C shows an isolated region 200 of polysilicon obtained by anisotropically etching the polysilicon (P_Si) layer 198 using the resist pattern 199 as an etching mask. Similar to the width of the resist pattern 199, the width of the polysilicon isolated region 200 is about 80 nm to 150 nm. The height of the isolated region 200 of polysilicon is preferably about 20 nm to 30 nm. This is because the width of the side wall 202 of the silicon oxide film formed on the side wall of the polysilicon isolated region 200 is set to about 20 nm to 30 nm.

FIG. 6D is a view showing a state where an interlayer insulating film 201 of a silicon oxide film (Si02) is deposited on the polysilicon isolated region 200 and the silicon oxide film 197 by the CVD method. silicon The thickness of the interlayer insulating film 201 of the oxide film (Si02) is preferably about 50 nm to about lOO nm so that the width of the side wall 202 of the silicon oxide film is about 20 nm to 30 nm.

 FIG. 6E is a diagram showing that the side wall 202 of the silicon oxide film is formed by anisotropically etching the interlayer insulating film 201 of the silicon oxide film (Si02). The width of the side wall 202 of the silicon oxide film is determined to be about 20 nm to 30 nm because the width of the fin region of the fin-type FET will be determined later.

 FIG. 6F shows that the isolated region 200 of polysilicon is removed by isotropic etching, and the silicon oxide film (Si02) layer 197 is anisotropically etched using the side wall 202 of the silicon oxide film as an etching mask. It is the figure which showed the place which formed the isolation region 203 of the silicon oxide layer. Thereafter, the silicon single crystal layer 196 is anisotropically etched using the isolated region 203 of the silicon oxide layer as an etching mask to form a fin region of the fin-type FET.

 FIG. 7 is a diagram showing the details of the step of forming a trench for embedded wiring, which includes the forces of FIGS. 7G, 7H, 71, 7J, 7K, and 7L. . FIG. 7 is a diagram showing a cross-section between Α and Α in FIG.

 In FIG. 7, 195 is a silicon oxide film (Si02) layer, 202 is a sidewall of the silicon oxide film, 203 is an isolated region of the silicon oxide layer, 204 is a three-dimensional isolated region of silicon, that is, fm of the fm type FET The region, 205 is a silicon oxide film layer, 206 is a sidewall of the silicon oxide film, 207 is a resist pattern, 208 is a trench for buried wiring, and 209 is a silicon germanium (SiGe) layer.

 [0059] FIG. 7G shows that after the step of FIG. 6F is completed, the silicon single crystal layer is anisotropically etched using the sidewall 202 of the silicon oxide film and the isolated region 203 of the silicon oxide layer as an etching mask. FIG. 6 is a diagram showing a place where the fm region 204 is obtained. Here, as described with reference to FIG. 6D, the width of the side wall 202 of the silicon oxide film is about 20 nm to 30 nm, so that the width of the fm region 204 is also about 20 nm to 30 nm. In addition, since the thickness of the silicon single crystal is about 30 nm, the height of the fm region 204 is about 30 nm.

 FIG. 7H is a diagram showing a state where the sidewall 202 of the silicon oxide film is removed by isotropic etching after the step of FIG. 7 is completed.

FIG. 71 shows that the silicon oxide film 205 was deposited after the process of FIG. 7H was completed. FIG. The width of the silicon oxide film 205 is desirably about 40 nm to 60 nm. This is because the width of the side wall 206 of the silicon oxide film to be formed later is about 20 nm to 30 nm.

 FIG. 7J is a diagram showing a state where the silicon oxide film 205 is anisotropically etched to form the silicon oxide film sidewall 206 after the process of FIG. 71 is completed. Further, after forming the side wall 206 of the silicon oxide film, a resist is applied, and a resist pattern 207 is formed by a photolithography technique. The interval between the resist patterns 207, that is, the opening of the resist pattern 207 is wider than the interval between the fin regions 204, and the end of the resist pattern 207 is located above the fm region 204.

 In FIG. 7K, after completing the step of FIG. 7J, anisotropic etching was performed to form a trench 208 for embedded wiring in the silicon oxide film layer 195 of the support substrate, and the resist pattern 207 was removed. FIG. Since the spacing between the fin regions 204 is about 80 nm to 150 nm, considering that the width of the sidewall 206 of the silicon oxide film is about 20 nm to 30 nm, the width of the groove 208 for the carrier wiring is about 40 nm to 90 nm. It becomes. Further, the groove 208 for embedded wiring is preferably 50 nm or less in consideration of loading the metal for carrying wiring into the groove.

 [0064] FIG. 7L shows silicon germanium in the trench 208 for the carrier wiring after the process of FIG. 7K is completed.

FIG. 6 is a view showing a state where a silicon-germanium (SiGe) layer 209 is deposited by a CVD method to embed (SiGe). The thickness of the silicon 'germanium (SiGe) layer is preferably about 75 nm to lOOnm because the purpose is to contain silicon germanium (SiGe) in the trench 208 for the carrier wiring. In addition, since the metal 208 is buried in the trench 208 for embedded wiring later, in order to prevent diffusion of the metal, the silicon nitride film is deposited with an lnm force of about 5 nm. It is desirable to deposit a silicon 'germanium (SiGe) layer 209. However, the deposition of the silicon nitride film can be omitted if the metal (metal) is not sufficiently heated so that the metal (metal) diffuses after the metal is placed in the groove. Since the silicon nitride film is thin, it is not shown below.

By the way, silicon 'germanium (SiGe) is used as an embedding material because when silicon' genorenium (SiGe) is isotropically etched, silicon (Si) or silicon constituting the fin region 204 or the gate electrode is used. This is because it has selectivity for polysilicon (P-Si). The selection The fm region 204 or the gate electrode must be covered with the silicon oxide (Si02) film side 206 or the silicon oxide film (Si02) film layer, etc.The side wall of the silicon oxide (Si02) film This is because, due to the nature of the formation process such as 206, it does not necessarily cover all of the silicon (Si) part.

FIG. 8 includes FIG. 8M, FIG. 8N, FIG. 80, FIG. 8P, FIG. 8Q, and FIG. 8R, and is a diagram showing details of the groove formation process for the embedded wiring. FIG. 8 is a diagram showing a cross section between A and B in FIG. 2A.

 In FIG. 8, 195 is a silicon oxide film (Si02) layer, 203 is an isolated region of the silicon oxide layer, 204 is a three-dimensional isolated region of silicon, that is, an fm region of an fm type FET, and 206 is a side of the silicon oxide film. Wall 209 is a silicon germanium (SiGe) layer, 210 is a polysilicon (P-Si) layer, 211 is a silicon oxide film, 212 is a resist pattern, and 213 is a gate electrode of a fin-type FET.

 [0066] FIG. 8M is a diagram showing the silicon germanium (SiGe) layer 209 of FIG. 7L flattened at the upper part of the fm region. Here, the planarization of the silicon 'germanium (SiGe) layer 209 can be achieved, for example, by performing a chemical mechanical polishing (CMP) process, that is, a chemical and mechanical polishing process. .

 FIG. 8N is a diagram showing that isotropic etching is performed on the silicon / germanium (SiGe) layer 209 after the process of FIG. 8M is completed. By performing isotropic etching for a certain period of time, the silicon / germanium (SiGe) layer 209 other than the trench for the buried wiring can be removed. When a silicon nitride film is deposited as a diffusion prevention film in the process of FIG. 7L, the silicon 'germanium (SiGe) layer 209 is removed and isotropic etching is performed for the buried wiring. The silicon nitride film other than the trench is removed.

 FIG. 80 is a view showing a state where the sidewall 206 of the silicon oxide film and the isolated region 203 of the silicon oxide layer are removed after the process of FIG. 8M is completed. By performing isotropic etching on the silicon oxide film, the silicon oxide film can be removed.

FIG. 8P is a diagram in which a polysilicon (P-Si) layer 210 and a silicon oxide film 211 are deposited after the process of FIG. For the deposition of the polysilicon (P-Si) layer 210 and the silicon oxide film 211, for example, a CVD method can be used. Note that the polysilicon (P-Si) layer 210 and the buried wiring trench Silicon 'Germanium (SiGe) is in direct contact with no contact via. Here, the thickness of the polysilicon (P-Si) layer 210 is preferably about 30 nm to 50 nm. Further, since the silicon oxide film 211 serves as an etching stopper, it is preferably about 10 nm.

 FIG. 8Q is a diagram showing a state where a resist is applied after the process of FIG. 8P is completed, and a resist pattern 212 is formed by a photolithography technique.

 FIG. 8R is a diagram showing the fm FET gate electrode 213 formed by etching the silicon oxide film 211 and the polysilicon (P_Si) layer 210 by anisotropic etching using the resist pattern 212 as an etching mask. It is.

 [0069] FIG. 9 includes FIG. 9R, FIG. 9S, FIG. 9T, FIG. 9U, FIG. 9V, and FIG. 9W, and shows details of the embedded wiring process and the on-board wiring formation process (part 1). It is a figure. FIG. 9 is a view showing a cross section between A and B in FIG. 2A. The on-substrate wiring formation step (part 1) is a detailed description of the step described as the first procedure in the description of the flowchart of FIG.

 In FIG. 9, 195 is a silicon oxide film (Si02) layer, 204 is a three-dimensional isolated region of silicon, that is, fin region of fin type FET, 209 is a silicon 'germanium (SiGe) layer, and 213 is a gate of fin type FET. Reference numeral 214 denotes an interlayer insulating film made of a silicon oxide film, 215 denotes a contact via, 216 denotes an aluminum (AL) layer, and 217 denotes substituted aluminum (AL) after the silicon-germanium (SiGe) layer is replaced.

 FIG. 9R is a diagram similar to FIG. 8R.

 FIG. 9S is a diagram showing a state where the silicon oxide interlayer insulating film 214 is deposited by the CVD method after the process of FIG. 9R is completed. The thickness of the interlayer insulating film 214 of silicon oxide film is preferably about lOOnm to 200nm. This is because a sufficient thickness is required to include the fin-type FET gate electrode 213 when the silicon oxide interlayer insulating film 214 is planarized.

FIG. 9T is a diagram showing a state where the interlayer insulating film 214 of the silicon oxide film has been flattened by polishing using the CMP method after completing the step of FIG. 9S. Here, the thickness of the interlayer insulating film 214 of the silicon oxide film is preferably about 80 nm to lOOnm from the surface of the silicon oxide film (Si02) layer 195. Considering that the height force of the fm region 204 of the fm type FET is about 20 nm to 30 nm and the thickness of the gate electrode of the fin type FET is about 20 nm to 30 nm, the entire fin type FET is included. This is necessary. In addition, when there are multiple wiring layers on the substrate, considering that the thickness of the interlayer insulating film between these wiring layers is about 30 nm to 50 nm, the silicon oxide interlayer insulating film 214 The thickness is greater than the thickness of the interlayer insulation film between the wiring layers on the substrate.

 FIG. 9U is a diagram showing a contact via 215 formed in the interlayer insulating film 214 of the silicon oxide film after the process of FIG. 9T is completed. The contact via 215 is formed by the following procedure. First, a resist is applied on the upper surface of the interlayer insulating film 214 of the silicon oxide film. Next, an opening pattern for the contact via 215 is formed by photolithography. Next, using the resist pattern as a mask, the silicon oxide film is etched by anisotropic etching to form a through hole up to the silicon germanium (SiGe) layer 209, which is used as a contact via 215. In FIG. 9T, the reason why the contact via 215 is represented by a dotted line is that the contact via 215 does not actually appear in the A-B cross section of FIG. 2A. A contact via 215 represents a contact vai24 that connects the embedded wiring 21 and the input terminal 18 in FIG. 2A. Therefore, since the contact via 215 is hidden behind the gate electrode of the fm type FET, the contact via 215 is represented by a dotted line.

 FIG. 9V is a diagram showing a state where the aluminum (AL) layer 216 is deposited by the CVD method or the sputtering method after the process of FIG. 9U is completed. The thickness of the aluminum (AL) layer 216 is preferably about lOOnm to 500nm. This is to ensure the wiring resistance of the wiring on the substrate. The aluminum (AL) layer 216 is then replaced with silicon (germanium) (SiGe) 209 embedded in the groove for receiving wiring. It is necessary to remove the insulating layer at the connection point between 216 and silicon-germanium (SiGe) 209. This is because the substitution phenomenon does not occur when the insulating layer is sandwiched. Therefore, in order to deposit the aluminum (AL) layer 216, it is usual to perform pretreatment, for example, isotropic etching to remove the insulating layer.

[0074] FIG. 9W, after finishing the process of FIG. 9W, replaces aluminum (AL) in the aluminum (AL) layer 216 with silicon 'germanium (SiGe) in the trench for the loading wiring. FIG. 5 is a view showing a state where buried wiring is formed by embedding aluminum (AL) in a groove for a buried wiring. Aluminum (AL) in Alminum (AL) layer 216 and silicon in the groove for loading wiring. In order to cause a substitution phenomenon with SiGe (SiGe), it can be achieved by applying heat treatment. Here, the heat treatment should be at 450 ° C for about 60 minutes.

 Next, details of the embedded wiring process and the on-substrate wiring forming process (part 2) will be described with reference to FIGS. 10 and 11. FIG. The on-substrate wiring forming step (part 2) is a detailed description of the step described as the second procedure in the description of the flowchart of FIG.

 FIG. 10 is a diagram composed of FIG. 10R, FIG. 10SS, FIG. 10TT, FIG. 10UU, FIG. 10VV, and FIG. FIG. 10 is a view showing a cross section between A and B in FIG. 2A.

 In FIG. 10, 195 is a silicon oxide (Si02) layer, 204 is a three-dimensional isolated region of silicon, that is, an fm region of an fm type FET, 209 is a silicon 'germanium (SiGe) layer, and 213 is a gate of a fin type FET. Electrode, 218 is a hollow state, 219 is a tungsten (W) layer, 220 is a resist pattern, and 221 is a silicon oxide film layer.

 FIG. 10R is a diagram similar to FIG. 8R and FIG. 9R, and branches between the loading wiring process and the on-board wiring formation process (part 1) and the embedded wiring process and the on-board wiring formation process (part 2). Indicates that it is after the process of FIG. 10R is completed.

 FIG. 10SS shows a state where the silicon-germanium (SiGe) layer 209 is removed by being etched into the trench for the carrier wiring by performing isotropic etching.

 FIG. 10TT is a diagram showing a state in which a tungsten (W) layer is deposited by the CVD method, a resist is applied, and a resist pattern 220 covering the buried wiring region is formed by a photolithography technique. The thickness of the tungsten (W) layer 219 is preferably about lOOnm to about 500nm. This is because tungsten (W) is sufficiently loaded in the trench for the embedded wiring.

 FIG. 10UU is a diagram showing a state in which the resist pattern 220 is removed by performing anisotropic etching on the tungsten (W) layer using the resist pattern 220 as an etching mask. The reason why the process shown in Fig. 10UU is necessary is as follows. First, when there is a tungsten (W) layer in a wide area, it is easy to control the isotropic etching so that tungsten (W) remains in the trench for the buried wiring by performing isotropic etching. Well then ... Therefore, if the process of FIG. 10UU is performed so that tungsten (W) remains only in the periphery of the trench for the carrier wiring, control of the subsequent isotropic etching becomes easy.

[0078] FIG. 10VV shows that tanning is performed by performing isotropic etching after the process of FIG. FIG. 6 is a view showing a state where tungsten (W) of the dusten (W) layer 219 is left only in the groove for the loading wiring. As a result, a carrier wiring is formed.

 FIG. 10WW is a diagram showing a silicon oxide film layer 221 deposited by the CVD method after the process of FIG. 10W is completed. The thickness of the silicon oxide layer 221 is preferably from lOOnm to 200nm in consideration of planarization after that. This is because it is necessary to include the fm region 204 of the fm type FET and the gate electrode of the fm type FET. If a heat treatment that is expected to diffuse tungsten (W) is applied after this step, it is desirable to deposit a silicon nitride film as a diffusion preventive film before the silicon oxide film layer 221 is deposited. In addition, the thickness of the silicon nitride film for the diffusion prevention film is preferably about 5 to 10 mm. However, the silicon nitride film for the diffusion barrier film is a thin film and is not shown in Figure 10WW.

FIG. 11 is a diagram configured from FIG. 11XX, FIG. 11YY, and FIG. 11ZZ. FIG. 11 is a diagram showing a cross-section between Α and Α in FIG.

 In FIG. 11, 195 is a silicon oxide (Si02) layer, 204 is a three-dimensional isolated region of silicon, that is, an fm region of an fm type FET, 209 is a silicon 'germanium (SiGe) layer, and 213 is a gate of a fin type FET. Electrode, 219 is a tungsten (W) layer, 221 is a silicon oxide film layer, 222 is a contact via, and 223 is a tungsten (W) layer.

 FIG. 11XX is a diagram showing a state where the silicon oxide film layer 221 is flattened by chemical and mechanical polishing by the CMP method after the process of FIG. 10WW is completed. Here, the thickness of the interlayer insulating film 221 of the silicon oxide film is desirably about 80 nm to lOO nm from the surface of the silicon oxide film (Si02) layer 195. Considering that the height force of the fm region 204 of the fm type FET is about 20 nm to 30 nm, the thickness force S of the gate electrode of the fin type FET, and about 20 nm to 30 nm, it is necessary to include the entire fin type FET It is. When the wiring layer on the substrate is a plurality of wiring layers, considering that the thickness of the interlayer insulating film between these wiring layers is about 30 nm to 50 nm, the thickness of the interlayer insulating film 214 of the silicon oxide film The thickness is larger than the thickness of the interlayer insulating film between the wiring layers on the substrate.

FIG. 11YY is a diagram showing a contact via 222 formed in the interlayer insulating film 221 of the silicon oxide film after the process of FIG. 11XX is completed. Contact via222 is as follows To form. First, a resist is applied on the upper surface of the interlayer insulating film 221 of the silicon oxide film. Next, an opening pattern for the contact via 222 is formed by photolithography. Next, using the resist pattern as a mask, the silicon oxide film is etched by anisotropic etching to form a through hole up to the tungsten (W) layer 209 to be a contact via 222. In FIG. 11YY, the contact via 222 is represented by a dotted line because the contact via 222 does not actually appear in the A-B cross section of FIG. 2A. A contact via 222 represents a contact vai24 that connects the embedded wiring 21 and the input terminal 18 in FIG. 2A. Therefore, the contact via 222 is hidden behind the gate electrode of the fm type FET, and the contact via 222 is represented by a dotted line.

FIG. 11ZZ is a view showing a state where the tungsten (W) layer 223 is deposited by the CVD method or the sputtering method after the process of FIG. 11YY is completed. The thickness of the tungsten (W) layer 223 is preferably about lOOnm to 500nm. This is to ensure the wiring resistance of the wiring on the substrate. Industrial applicability

The present invention provides a semiconductor integrated circuit device having a Fin-type FET formed on a support substrate as a constituent element, suitable for highly integrated LSIs, and a method for manufacturing the same.

 Explanation of symbols

[0083] 1 processor

 2 chips

 3 Logic circuit

 4 fm type FET

 5, 15, 25, 40, 57a, 70 Wiring on board to connect to positive power supply

 6, 16, 26, 33, 41, 48, 57b, 63, 71, 78 P-channel fin type FET

 7, 17, 27, 34, 42, 49, 57c, 64, 72, 79 N-channel fin type FET

 8, 18 Wiring on board connected to input terminal

 9, 19, 29, 44, 59, 74 On-board wiring connected to output terminals

 10, 20, 30, 45, 60, 75 Wiring on board to connect to ground power supply

 11, 21, 31, 35, 46, 50, 61, 65, 76, 80

13, 23, 39, 54, 69, 83 Contact Via , 55, 82 Wiring connection area

, 43, 58, 73 On-board wiring connected to input terminal 1, 56, 66, 81 On-board wiring connected to input terminal 2, 53, 67, 77 On-board wiring

, 86 inverter

 Input terminal

 Output terminal

, 105, 120 On-board wiring connected to positive power supply, 93, 106, 107, 121, 122 P-channel fin type FET, 94, 108, 109, 123, 124 N-channel fin type FET, 96, 115, 116, 117 118, 130, 131 Embedded wiring 110, 125 On-board wiring connected to ground power supply 112, 127 On-board wiring connected to input terminal 111, 126 On-board wiring connected to output terminal 0, 113, 128 Contact Via

4, 129 Wiring connection area

0, 131 inverter

2 Input terminal

3 Output terminal

5, 160 Wiring on board connected to positive power supply

6, 137, 161, 162 P-channel fm type FET

8, 139, 163, 164, 165, 166 N-channel fm type FET0, 167 On-board wiring connected to ground power supply

1, 168 Wiring on board connected to output terminal

2, 169 On-board wiring connected to input terminal

3, 174 contacts Via

4, 176 Wiring connection area

5, 146, 147, 148, 172, 173 149, 175 Shared contact

 152 and 153 are signal lines

 154, 155 Inno Coutor

 156, 157 Transfer gate transistor

 158 input terminal

 159 Output terminal

 170, 171 On-board wiring

 177, 178 On-board wiring connected to signal line

180 fin region formation process

 181 fin region

 182 Insulation support substrate

 183 Groove formation process

 184 Groove for loading wiring

 185 Silicon 'Germanium (SiGe) loading process

186 Silicon 'Germanium (SiGe)

187 Gate electrode formation process

 188 Polysilicon (P-Si)

 189 Loading wiring process

 190 cavity

 191 Metal

 192 On-board wiring formation process

 195 Silicon oxide (Si02) layer

 196 Single crystal layer of silicon

 197 Silicon oxide (Si02) layer

 198 Polysilicon (P-Si) layer

 199 resist pattern

 200 Polysilicon isolated region

201 Interlayer insulation film of silicon oxide film (Si02) 202 Silicon oxide sidewall

 203 Isolated region of silicon oxide layer

 204 fin type fm region (three-dimensional isolated region of silicon)

205 Silicon oxide layer

 206 Side wall of silicon oxide film

 207 resist pattern

 208 Groove for lead-in wiring

 209 Silicon 'Germanium (SiGe) layer

 208 Groove for lead-in wiring

 209 Silicon 'Germanium (SiGe) layer

 210 Polysilicon (P-Si) layer

 211 Silicon oxide film

 212 resist pattern

 213 fin FET gate electrode

 214 Interlayer insulation film of silicon oxide film

 215 Contact Via

 216 Aluminum (AL)

 218 Hollow state

 219 Tungsten (W)

 220 resist pattern

 221 Silicon oxide layer

 222 Contact Via

 223 Tungsten (W) layer

Claims

The scope of the claims

 [1] A MOS transistor element having a three-dimensionally isolated region of silicon formed on a support substrate and a gate electrode formed on the surface of the three-dimensionally isolated region of silicon.

 A carrier wiring carried in a groove in the support substrate;

 A wiring on a substrate on the support substrate;

 The semiconductor circuit device is characterized in that the connection between the MOS transistor elements is performed using the carrier wiring and the wiring on the substrate.

[2] The semiconductor circuit device according to [1], wherein the three-dimensional isolated region of silicon and the embedded wiring are formed in a self-aligning manner.

3. The semiconductor circuit device according to claim 1, wherein the carrier wiring is connected to a gate electrode of the MOS transistor element.

4. The semiconductor circuit device according to claim 1, wherein the carrier wiring is made of a material containing aluminum.

 5. The semiconductor circuit device according to claim 1, wherein the carrier wiring is made of a material containing tungsten.

 [6] Arrange the carrier wiring in the first direction,

 2. The semiconductor circuit device according to claim 1, wherein the connection portions of the circuit elements connected by the wiring on the substrate are linearly arranged in the second direction.

 7. The semiconductor circuit device according to claim 6, wherein the first direction and the second direction are orthogonal to each other.

 [8] A solid isolated region forming step for forming the solid isolated region of the MOS transistor element;

 Forming a groove for embedded wiring in a support substrate in a self-aligned manner with the three-dimensional isolated region; and

 An embedding step of loading a carrier material having etching selectivity with silicon into the groove for the carrier wiring;

A gate electrode forming step of forming a gate electrode of the MOS transistor element; a carrier wiring forming step of forming the carrier wire; 2. The method of manufacturing a semiconductor circuit device according to claim 1, further comprising: an on-substrate wiring forming step for forming the on-substrate wiring.

 9. The method for manufacturing a semiconductor circuit device according to claim 8, wherein the loading material has a material force including silicon and germanium.

[10] The carrier wiring forming step includes:

 Removing the carrier material;

 9. The method for manufacturing a semiconductor circuit device according to claim 8, further comprising a step of loading a metal material into the groove for the loading wiring.

11. The method for manufacturing a semiconductor circuit device according to claim 10, wherein the metal material is tungsten (W).

[12] The carrier wiring forming step includes:

 Forming an insulating layer on the embedded material in the groove for the carrier wiring;

 Opening a contact via for the embedded material in the insulating layer;

 Depositing a metal material on the insulating layer;

 The semiconductor according to claim 8, further comprising a step of bringing the embedded material and the metal material in the groove for the carrier wiring into contact with each other and applying heat treatment to replace the metal material and the carrier material. A method of manufacturing a circuit device.

13. The method for manufacturing a semiconductor circuit device according to claim 12, wherein the metal material includes aluminum.