KR100523918B1 - Method of manufacturing a flash device - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method of fabricating a flash device, and more particularly, to patterning a floating gate electrode by increasing the thickness of the first polysilicon formed through the self-aligned cell trench isolation process and decreasing the thickness of the second polysilicon. It is possible to facilitate the etching, secure the etching margin of the subsequent gate etching process, reduce the burden of the etching process by lowering the height of the protrusion of the device isolation layer through a separate etching or cleaning process, sufficient cell coupling Provided is a method of manufacturing a flash device that can secure a ratio.

Description

Method of manufacturing a flash device

The present invention relates to a method of manufacturing a flash device, and more particularly, to a method of forming a floating gate electrode.

In the operation of a NAND flash EEPROM cell, data is programmed or erased through an F-N tunneling of an electron of a floating gate electrode to record information. As such, a flash device requires a floating gate electrode isolated from each device to store information. In order to form a conventional isolated floating gate electrode, a first polysilicon film is formed through a device isolation process, a second polysilicon film is formed on the upper portion thereof, and a second polysilicon film is patterned to form a floating gate electrode pattern. At this time, the second polysilicon film should be formed thick due to the problem of coupling ratio of the cell, and the first polysilicon film should be formed thin due to the problem of device isolation process. As the size of the cell gradually decreases, the area to be etched to isolate the floating gate electrode pattern is reduced, and the step to be etched increases. This causes a problem that polysilicon remains during the etching process to isolate the floating gate electrode, which adversely affects the operation of the device. In order to solve this problem, it is advantageous to reduce the thickness of the second polysilicon film, but it is also difficult due to the problem of the coupling ratio of the cell described above.

Accordingly, the present invention increases the thickness of the first polysilicon formed through the self-aligned narrow trench isolation process and reduces the thickness of the second polysilicon to solve the above problem, thereby reducing the etching margin of the subsequent gate etching process. The present invention provides a method for manufacturing a flash device, which can ensure a and can secure a sufficient coupling ratio of a cell.

Forming a tunnel oxide film, a first polysilicon film, and a pad nitride film on the semiconductor substrate according to the present invention; and forming a trench by patterning the pad nitride film, the first polysilicon film, the tunnel oxide film, and the semiconductor substrate. A step of forming a device isolation film by performing a first planarization process using the pad nitride film as a stop layer after filling the trench with an HDP oxide film and forming a device isolation film; and removing the remaining pad nitride film by performing a nitride film strip process. Forming a second polysilicon layer on the entire structure, patterning the second polysilicon layer, and patterning the floating gate electrode. Forming a dielectric film and a control gate over the entire structure; It provides a method for manufacturing a flash device characterized in that.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various forms, and only the embodiments are intended to complete the disclosure of the present invention, and to those skilled in the art to fully understand the scope of the invention. It is provided to inform you. Like numbers refer to like elements in the figures.

1A to 1F are cross-sectional views illustrating a method of manufacturing a flash device according to the present invention.

Referring to FIG. 1A, a screen oxide film (not shown) is formed on the semiconductor substrate 110 to suppress crystal defects on the surface of the substrate or to perform surface treatment and ion implantation, followed by ion implantation to perform well implantation. And an ion layer (not shown) for controlling the threshold voltage. It is preferable to use a P type substrate as a semiconductor substrate. The well is preferably a formation in which a P type well is formed in an N type well. After removing the screen oxide layer, the tunnel oxide layer 112, the first polysilicon layer 114, and the pad nitride layer 116 are deposited.

SC-1 consisting of DHF (Dilute HF) and NH ₄ OH, H ₂ O ₂ and H ₂ O where the mixing ratio of H ₂ O and HF is 50: 1 for cleaning the semiconductor substrate 110 before forming the screen oxide layer SC- consisting of BOE (Buffered Oxide Etch) and NH ₄ OH, H ₂ O ₂ and H ₂ O with (Standard Cleaning-1) or a mixing ratio of NH ₄ F and HF of 100: 1 to 300: 1 It is effective to carry out the pretreatment washing step using 1. It is preferable to form the screen oxide film having a thickness of 30 to 120 Pa by performing dry or wet oxidation within a temperature range of 750 to 800 ° C.

The screen oxide film may be removed through a cleaning process before depositing the tunnel oxide film 112. After ion implantation, it is preferable to etch the screen oxide film using SC-1 composed of DHF having a mixing ratio of H ₂ O and HF of 50: 1, and NH ₄ OH, H ₂ O _2, and H ₂ O.

The tunnel oxide film 112 was formed to a thickness of 85 to 110 kPa by a wet oxidation method at a temperature of 750 to 800 ° C., and after the tunnel oxide film 112 was deposited, heat-treated for 20 to 30 minutes using N ₂ at a temperature of 900 to 910 ° C. By performing the process, the defect density at the interface between the tunnel oxide film 112 and the semiconductor substrate 110 is minimized.

The first polysilicon film 114 is formed using an undoped amorphous silicon film having a thickness of 150 to 1500 Å through a CVD-based deposition method. It is preferable to form the first polysilicon film 114 to a thickness of 600 to 1500 mW to secure the margin of the subsequent process, the isolation of the floating gate, and the margin during gate etching. Moreover, it is most preferable to form 1000 micrometers thick with a 1st polysilicon film. Meanwhile, the first polysilicon film 114 is preferably formed within a temperature range of 550 to 670 ° C. As a result, it is effective that the first polysilicon film 114 is minimized in size to prevent electric field concentration. When the thickness of the first polysilicon film 114 is increased, the effective field height of the protrusion of the device isolation film formed by the subsequent process is increased. However, to overcome this problem, a predetermined etching process will be described later.

The pad nitride film 116 is formed on the first polysilicon film 114 with a high thickness of about 1500 to 20,000 kPa by the CVD deposition method. The first polysilicon layer 114 may determine the overlap of the floating gate. The pad nitride film 116 is preferably formed in consideration of the thickness and the coupling reduced by a subsequent etching or chemical mechanical polishing process.

Referring to FIG. 1B, the pad nitride layer 116, the first polysilicon layer 114, the tunnel oxide layer 112, and the semiconductor substrate 110 may be sequentially etched through ISO (Isolation) mask patterning. A trench 118 having a shallow trench isolation (STI) structure is formed to define an active region and a field region.

The threshold of the ISO mask is preferably controlled to satisfy the ISO BV. In order to form the trench 118, a photoresist film is coated on the entire structure, and then a photolithography process using a photoresist mask is performed to form a photoresist pattern (not shown). An etching process using the photoresist pattern as an etching mask is performed to etch the pad nitride layer 116, the first polysilicon layer 114, the tunnel oxide layer 112, and the semiconductor substrate 110 to form the trench 118 having an STI structure. Form. In forming the trench 118, the semiconductor substrate 110 is etched to have a 75 to 85 ° inclination. The pad nitride layer 116 may have a vertical shape to be advantageous to a loop of a subsequent floating gate poly layer and to secure an etching margin.

Referring to FIG. 1C, a corner of the trench 118 is rounded by performing a dry oxidation process to compensate for etch damage of sidewalls of the trench 118 of the STI structure. A high density plasma (HDP) oxide film is deposited on the entire structure to fill the trench 118. A first planarization process using the pad nitride film 116 as a stop layer is performed to remove the HDP oxide film on the pad nitride film 116. As a result, the device isolation layer 120 for isolation between devices is formed.

In the dry oxidation process, the oxidation process is preferably performed, followed by a rapid thermal process (RTP) under a nitrogen (N 2) atmosphere. Accordingly, it is preferable to round the angled moss portions of the upper and lower portions of the trench 118 by using the automatic silicon migration (Si Atomic Migretion) phenomenon to form a more stable device isolation layer 120.

The HDP oxide layer may be formed to a thickness of about 4000 to 10000 kPa in order to fill the gaps in the trench 118, and may be buried so that voids are not formed in the trench.

The first planarization step is preferably performed by a chemical mechanical polishing (CMP) process using the pad nitride film 116 as a stop film. Proceeding by the method of leaving a nitride film of a desired thickness by the CMP process, an HDP oxide film having an appropriate thickness is left. The CMP process may be over-polishing to adjust the height of the effective field thickness (EFT) (protrusion height of the device isolation layer) targeting the cell region. The HDP oxide layer fills the inside of the trench 118, and the upper portion of the HDP oxide layer protrudes to form a device isolation layer 120 that isolates the floating gate electrodes formed by a subsequent process from each other.

Referring to FIG. 1D, the pad nitride layer 116 is etched by performing a nitride strip process using phosphoric acid (H ₃ PO ₄ ). It is preferable to reduce the effective field height of the device isolation layer 120 by removing the upper region of the device isolation layer 120 protruding due to the etching of the pad nitride layer 116. The protruding portion of the device isolation layer 120 may be formed lower than the step of the first polysilicon layer 114 or may be formed higher.

A portion of the protrusion of the device isolation layer 120 may be removed by performing a separate wet etching process or a cleaning process before forming the second polysilicon layer 122. Since the protrusion of the device isolation layer 120 may cause a mote problem, the protrusion of the device isolation layer 120 may be removed in consideration of the aspect ratio allowed when the trench 118 is buried. In the present exemplary embodiment, the height of the protrusion (see H in FIG. 1D) of the device isolation layer 120, which protrudes above the first polysilicon layer 114 through the removal of the pad nitride layer 116, may be applied to the first polysilicon layer 114. It is desirable to be lower than the height. The present invention is not limited thereto, and it is most preferable that the effective field thickness (EFT) is 2000 to 4000 mV by removing the protrusion of the device isolation layer 120. To this end, the protrusion of the device isolation layer 120 may protrude higher than the surface of the first polysilicon layer 114 or may protrude low.

The removal of a part of the protrusion of the device isolation layer 120 is to secure an effective thickness of the second polysilicon layer 122 which directly affects the coupling ratio of the cell while the NAND flash element is directly applied. This is to compensate for a phenomenon in which the effective field thickness of the device isolation layer 120 is increased by increasing the thickness of the 114. In addition, by removing a part of the protrusion of the device isolation layer 120, a sufficient margin can be secured when forming a contact layer between the cell region and the peripheral circuit region.

Referring to FIG. 1E, a second polysilicon film 122 is formed over the entire structure. The second polysilicon layer 122 is patterned to form the floating gate electrode 130. After forming the second polysilicon layer 122, a planarization process may be performed to remove the topology due to the underlying structure.

The second polysilicon film 122 forms a doped polysilicon film having a thickness of 150 to 2000 microseconds by using a CVD-based deposition method. The second polysilicon layer 122 is formed to have a thickness for facilitating securing the etching margin of the subsequent patterning process, and to form a thickness for facilitating isolation of the floating gate electrode 130 during the subsequent gate etching process. to be. In addition, the height of the entire floating gate electrode 130 (see K in FIG. 1D) is preferably formed in proportion to the deposition thickness of the first polysilicon film 114. Therefore, it is preferable that the second polysilicon film 122 be formed to a thickness of 500 to 1000 Å. On the other hand, the second polysilicon film 122 is preferably formed in the temperature range of 550 to 670 ℃.

In the patterning of the second polysilicon layer 122, a photosensitive layer is coated on the entire structure, and then a photolithography process is performed using a mask for a floating gate electrode to form a photosensitive layer pattern (not shown). An etching process using the photoresist pattern as an etching mask is performed to remove the second polysilicon layer 122 to form a floating gate electrode 130 formed of the first and second polysilicon layers 114 and 122.

After forming the second polysilicon film 122 to reduce the step of the second polysilicon film 122 by the thick first polysilicon film 144 and to form the thickness of the floating gate electrode 130 described above. A planarization process using a chemical mechanical smoke screen process or an etching back process is performed. Thereby, the process margin of the patterning process using a subsequent photosensitive film can be easily ensured.

Referring to FIG. 1F, a dielectric film 140 is formed on a semiconductor substrate 110 on which the floating gate electrode 130 is formed along a step, and a material film for forming a control gate on the dielectric film 140. The third polysilicon film 150 and the tungsten silicide film (WSi _x ; 152) are sequentially formed, and then the dielectric film 140, the third polysilicon film 150, and the tungsten silicide film 152 are patterned and controlled. The gate electrode 160 is formed.

As the dielectric film 140, various types of dielectric films used for semiconductor devices are deposited. In this embodiment, an ONO (oxide / nitride / oxide film (SiO ₂ -Si ₃ N ₄ -SiO ₂ ) or ONON structure dielectric film ( 140) After the ONO deposition, the monitoring wafer is heated at a temperature of about 750 to 800 ° C. by a wet oxidation method to improve the quality of the oxide film constituting the ONO and to enhance the interface between the layers. Steam annealing may be performed to oxidize to a thickness of about 150 to 300 kPa as a reference. Proceed to prevent contamination by natural oxide film or impurities.

The third polysilicon film 150 may be substituted with the dielectric film 140 during deposition of tungsten silicide 152 to prevent the diffusion of hydrofluoric acid, which may increase the thickness of the oxide film. As a double structure of doped and undoped, it is preferable to deposit an amorphous silicon film by LP-CVD at a temperature of about 510 to 550 ° C. and a pressure of 0.1 to 3 torr. At this time, the ratio of the doped film and the undoped film is 1: 2 to 6: 1 ratio, and the amorphous silicon film is formed to a thickness of about 500 to 1000Å so that the space between the floating gate electrode 130 is sufficiently filled. As a result, the gap formation may be suppressed during the subsequent deposition of the tungsten silicide 152 to reduce the word line resistance Rs. When forming the double layered third polysilicon layer 150, a doped film is formed using SiH ₄ or Si ₂ H ₆ and PH ₃ gas, and then the PH ₃ gas is blocked and is not continuously doped. It is preferable to form a film.

The tungsten silicide layer 152 may be prepared by using a reaction of MS (SiH ₄ ) or DCS (SiH ₂ CL ₂ ) with WF ₆ having low fluorine content, low post annealed stress, and good adhesive strength. It is preferable to realize proper step coverage at a temperature between 500 ° C. and grow to about 2.0 to 2.8, which is a stoichiometric ratio that can minimize the word line resistance (Rs).

A hard mask film (not shown) and an ARC layer (not shown) are deposited on the tungsten silicide layer 152 using SiO _x N _y or Si ₃ N ₄ , and a gate mask and etching is performed. It is preferable to form the control gate electrode 160 by performing a) process and a self aligned mask and etching process.

As described above, the present invention can facilitate the patterning of the floating gate electrode by increasing the thickness of the first polysilicon and lowering the thickness of the second polysilicon formed through the self-aligned narrow trench isolation process. In addition, the etching margin of the subsequent gate etching process may be secured.

In addition, the etching or cleaning process may be performed to reduce the height of the protrusion of the device isolation layer, thereby reducing the burden of the etching process and ensuring a sufficient coupling ratio of the cells.

In addition, the uniform floating gate electrode can increase program and erase speeds by reducing the difference in coupling ratio between devices.

1A to 1F are cross-sectional views illustrating a method of manufacturing a flash device according to the present invention.

<Explanation of symbols for the main parts of the drawings>

110 semiconductor substrate 112 tunnel oxide film

114, 122, 150: polysilicon 116: pad nitride film

118 trench 120 element isolation film

130: floating gate electrode 140: dielectric film

152 tungsten silicide film 160 control gate electrode

Claims (5)

Forming a tunnel oxide film, a first polysilicon film and a pad nitride film on the semiconductor substrate; Patterning the pad nitride film, the first polysilicon film, the tunnel oxide film, and the semiconductor substrate to form a trench; Filling the trench with an HDP oxide film, and then forming a device isolation film by performing a first planarization process using the pad nitride film as a stop layer; Performing a nitride film strip process to remove the remaining pad nitride film so that a part of the device isolation film protrudes; Removing a portion of the protruding device isolation layer through a cleaning process performed before the second polysilicon film forming process, and flattening an upper surface of the removed device isolation film; Forming a second polysilicon film on the entire structure; Patterning the second polysilicon layer to form a floating gate electrode; And And forming a dielectric film and a control gate over the entire structure. The method of claim 1, A method of manufacturing a flash device for forming the first polysilicon film to a thickness of 600 to 1500 Å. The method of claim 1, Method for manufacturing a flash device for forming the second polysilicon film to a thickness of 500 to 1000Å The method of claim 1, wherein after removing the protruding device isolation layer, A method of manufacturing a flash device such that the effective field height of the device isolation film is 2000 to 4000 mW. The method of claim 1, wherein after the deposition of the second polysilicon film, And a flattening process using a chemical mechanical polishing process or an entire surface etching process to alleviate the step caused by the first polysilicon film.