KR20010064324A - Method for forming isolation layer of semiconductor device using trench technology - Google Patents

Abstract

A method of forming a shallow trench isolation (STI) device isolation film in a semiconductor device is disclosed. In the device isolation process of the present invention, a pad oxide film and a nitride film are sequentially stacked on a semiconductor substrate, and a photolithography and etching process using a device isolation mask is performed to pattern the nitride film and the pad oxide film, and then trenches are formed in the substrate to a predetermined depth. After the sidewall oxide film and the liner nitride film are sequentially formed inside the trench of the trench, an annealing process is performed at a temperature of 750 to 1200 ° C. and an O 2 atmosphere to nitrate the liner nitride film, fill the gap fill oxide film in the trench of the substrate, and then planarize it. The nitride film is removed and a cleaning process is performed to form a device isolation film made of a gap fill oxide film in the substrate. Accordingly, the present invention forms a surface of the liner nitride film as a nitride oxide (SiON) having excellent bonding with the gapfill oxide film by performing a high temperature heat treatment process, thereby preventing the bluing-up phenomenon of the liner nitride film during deposition of the gapfill oxide film and depositing the oxide film uniformly. can do.

Description

Method for forming isolation layer of semiconductor device using trench technology

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of forming a device isolation film of a semiconductor device, and in particular, to improve adhesion between a liner nitride film and a gapfill oxide film inside a trench during an STI type device isolation film manufacturing process for defining device isolation regions and active regions in a highly integrated semiconductor device. It is a skill.

Recently, as the development of semiconductor device manufacturing technology and the application of memory devices have been expanded, the development of large-capacity memory devices has been progressed. It has been promoted by a memory cell study. In particular, the reduction of the device isolation film that separates the devices has emerged as one of the important items in the technology of miniaturization of memory devices.

Conventional device isolation technology has mainly been a LOCal Oxidation of Silicon (LOCOS) technology to selectively grow a thick oxide film on the semiconductor substrate to form a device isolation film. However, the LOCOS technique cannot reduce the width of the device isolation region due to side diffusion and bird's beak of the device isolation layer. Therefore, the LOCOS technology cannot be applied to a large-capacity memory device whose device design dimension is reduced to submicron or less, so a new device isolation technology is required.

Accordingly, due to the necessity of a new device isolation technology and the development of etching technology, trenches capable of electrically separating devices by forming trenches having a width of 1 m or less and a depth of several tens to hundreds of m are on the semiconductor substrate. Device isolation technology has emerged. The device isolation technology using this trench can reduce the device isolation region by nearly 80% compared to the conventional LOCOS technology.

Moreover, recently, the STI (Shallow Trench Isolation) process, which greatly reduces the stress applied to the wafer substrate and improves the problem of the trench isolation layer, has emerged. In other words, the STI process is a technique of forming a device isolation film by forming a trench having a predetermined depth in the semiconductor substrate, depositing an oxide film on the trench by chemical vapor deposition, and etching an unnecessary oxide film by a chemical mechanical polishing process.

However, the STI process must remove the etch damage present on the inner surface of the trench to improve the junction leakage current characteristics. In order to compensate for the damage generated during the trench etching in the substrate and to obtain a profile of the interface between the etching surface and the device isolation layer, two high temperature oxidation processes are usually performed. That is, the sacrificial oxide film is formed in the trench of the substrate by first oxidizing and removing the sacrificial oxide film, and then the second oxidation process is performed again to form the sidewall oxide film to compensate for the etching damage on the substrate surface inside the trench.

FIG. 1 is a cross-sectional view illustrating a bluing-up phenomenon of a liner nitride film generated when a gap fill oxide film is formed after forming a liner nitride film in a trench in the STI type isolation film manufacturing process according to the prior art.

Referring to this, the manufacturing process of the STI type device isolation film of the prior art will be described.

First, a pad oxide film 12 is formed over a silicon substrate 10 as a semiconductor substrate, and a nitride film 14 is stacked thereon. The nitride layer 14 and the pad oxide layer 12 are patterned by a photolithography and an etching process using a device isolation mask, and the substrate exposed by the patterned layer is etched to form trenches having a predetermined depth.

In order to compensate for the trench etch damage, the sacrificial oxide film formed after the formation of the sacrificial oxide film in the trench is about 150 to 200 占 퐉 and the grown sacrificial oxide film is removed. Next, the sidewall oxide film 16 is grown to about 150 to 200 ∼ inside the trench.

The liner nitride film 18 is deposited on the entire surface of the substrate in order to suppress the generation of voids before the inside of the trench is filled with the insulating film.

Then, the gap fill oxide 20 is completely filled with a gap fill oxide film using a high density plasma method, and the nitride fill film 14 is used as an etch stop film to planarize the gap fill oxide film 20 by a chemical mechanical polishing process. When the nitride film is removed and the cleaning process is performed, an isolation layer in which the gap fill oxide film 20 is embedded in the trench of the substrate is formed.

However, in the STI type device separation process as described above, the compressive stress of the gap fill oxide film is largely about 220 Mpa due to the high density plasma method having excellent deposition characteristics. In this way, even if the stress is large, the liner nitride film 18 formed in the trench has the following advantages.

That is, since the stress applied to the silicon oxide film during the deposition of the gap fill oxide film of the high density plasma takes the tensile stress and the opposite stress to the nitride film, the liner nitride film 18 serves to reduce the stress by about 10 MPa. In addition, since the liner nitride layer of the device isolation layer acts as a mask during the contact etching process, it is possible to reduce the etch loss of the edge of the device isolation layer to prevent the junction leakage.

However, the liner nitride film 18 has a weak chemical defect between the nitride film 18 and the gap fill oxide film 20 in the deposition of a high density plasma type gap fill oxide film despite the above-mentioned advantages. It causes a blowing-up phenomenon (b). This bluing-up phenomenon has a problem in that the yield of the device is lowered because the deposition of the gap fill oxide film 20 becomes uneven and the width of the device isolation film is reduced.

An object of the present invention is to perform a high temperature heat treatment process on a substrate on which a liner nitride film is formed before depositing the gap fill oxide film in order to solve the problems of the prior art. The present invention provides a device isolation film forming method using a trench of a semiconductor device that can prevent the bluing-up phenomenon of the liner nitride film and uniformly deposit the oxide film when the gap fill oxide film is deposited.

1 is a cross-sectional view illustrating a bluing-up phenomenon of a liner nitride film generated when a gap fill oxide film is formed after forming a liner nitride film in a trench in a STI type isolation film manufacturing process according to the prior art;

Figure 2a to 2g is a process flow chart for explaining the STI type device isolation film manufacturing process according to the present invention.

* Description of the symbols for the main parts of the drawings *

100 silicon substrate 102 pad oxide film

104: pad nitride film 106: trench

108: sacrificial oxide film 110: sidewall oxide film

112 liner oxide film 114 gap fill oxide film

ISO: Device Separator

In order to achieve the above object, the present invention provides a method of forming a device isolation film having a trench structure for defining an active region and an isolation region of a device on a semiconductor substrate, the method comprising sequentially depositing a pad oxide film and a nitride film on the semiconductor substrate, and separating the device. Forming a trench to a predetermined depth in the substrate after patterning the nitride film and the pad oxide film by performing a photo-etching process using a mask; forming a sidewall oxide film inside the trench of the substrate; Forming a liner nitride film on the substrate, and performing an annealing process on the substrate on which the liner nitride film is formed at a temperature of 750 to 1200 ° C. and in an O ₂ atmosphere to nitrify the surface of the liner nitride film, and filling a gap fill oxide film in the trench of the substrate. Planarizing the substrate, removing the nitride film, and performing a cleaning process to In a step of forming an isolation film made of an oxide film gaeppil.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2A to 2G are process flow charts for explaining the STI type device isolation film manufacturing process according to the present invention. Referring to this, the device isolation film manufacturing method of the present invention is as follows.

First, as shown in FIG. 2A, a thin pad oxide film 102 and a thick nitride film 104 are sequentially stacked on the silicon substrate 100. Then, the photolithography and etching processes using the device isolation mask are performed to pattern the nitride film 104 and the pad oxide film 102, and the trench 106 having a predetermined depth is formed in the substrate 100 exposed by the patterned film. . At this time, the trench 106 etching depth is different depending on the design rules of the application device is about 2000 ~ 4000Å.

Next, the sacrificial oxide film is removed after the sacrificial oxide film is grown inside the trench of the substrate to compensate for the trench etching damage.

Next, as shown in FIGS. 2B and 2C, the sidewall oxide film 108 is grown in the trench 106 by about 150 to 200 Å. The liner nitride film 110 is deposited on the entire surface of the substrate to suppress the generation of voids before the inside of the trench is filled with the insulating film. At this time, the thickness of the liner nitride film 110 is about 30 to 500 kPa in order to relieve the stress of the subsequent process.

Next, as shown in FIG. 2D, the annealing process is performed at a temperature of 750 to 1200 ° C. and an O ₂ atmosphere before filling the trench inside with a gapfill oxide film using a high density plasma method. (110) Nitrify the surface. Here, the annealing process is carried out for 1 to 5 minutes using a rapid thermal anneal (or rapid thermal anneal), or 20 to 200 minutes or more if performed in a furnace (furnace). Preferably, the proper temperature of the annealing process is 900 to 1100 ° C.

Next, as shown in FIG. 2E, the gapfill oxide film 112 is buried in the trench of the substrate on which the liner nitride film 110 whose surface is nitrified by the annealing process is formed by a high density plasma method. In this case, the bluing-phenomena is minimized by the nitrided liner nitride film 110, so that the bonding force between the gapfill oxide film 112 and the nitride oxide film is large, so that the initial deposition of the gapfill oxide film 112 is uniform.

Subsequently, as shown in FIG. 2F, the gapfill oxide film 112 uniformly embedded in the trench is polished by a planarization process, and the process proceeds until the nitride film 104 is exposed. The nitride film 104 is removed using a phosphoric acid solution after etching the gap fill oxide film 112 ′ planarized by the entire surface etching process to be lower than the nitride film 104.

As shown in FIG. 2G, when the cleaning process is performed, the gapfill oxide film 112 ′ is embedded in the trench of the substrate to form the STI type device isolation film 114 defining the isolation region ISO of the device.

As described above, the present invention performs a high temperature heat treatment process on the substrate on which the liner nitride film is formed before depositing the gap fill oxide film to form the surface of the liner nitride film as a nitride oxide (SiON) having excellent bonding with the gap fill oxide film. The bluing-up phenomenon of the liner nitride film can be prevented and the oxide film can be deposited uniformly.

Accordingly, the present invention can secure the width of the device isolation film accurately and has the advantage of increasing the yield of the device isolation process.

Claims (4)

In forming a device isolation film having a trench structure to define an active region and an isolation region of a device on a semiconductor substrate, Sequentially depositing a pad oxide film and a nitride film on a semiconductor substrate; Performing a photolithography and etching process using a device isolation mask to pattern the nitride layer and the pad oxide layer, and then forming a trench in the substrate to a predetermined depth; Forming a sidewall oxide film inside the trench of the substrate; Forming a liner nitride film on an entire surface of the substrate on which the sidewall oxide film is formed; Nitrifying the surface of the liner nitride layer by performing an annealing process on a substrate having the liner nitride layer formed at a temperature of 750 to 1200 ° C. and an O ₂ atmosphere; Filling a gap fill oxide film into the trench of the substrate and planarizing it; And Removing the nitride film and performing a cleaning process to form a device isolation film made of a gapfill oxide film in the substrate. The method of claim 1, wherein the liner nitride film has a thickness of 30 to 500 kPa. The method of claim 1, wherein the annealing process is performed using a rapid heat treatment method for 1 to 5 minutes. The method of claim 1, wherein the annealing process is performed in an electric furnace and is performed for 20 to 200 minutes or more.