EP1472722A2

EP1472722A2 - Method for producing a memory cell

Info

Publication number: EP1472722A2
Application number: EP03737237A
Authority: EP
Inventors: Franz Hofmann; Erhard Landgraf; Hannes Luyken
Original assignee: Infineon Technologies AG
Current assignee: Infineon Technologies AG
Priority date: 2002-02-06
Filing date: 2003-01-23
Publication date: 2004-11-03
Also published as: DE10204873C1; WO2003067639A2; JP2005525695A; JP4093965B2; US20050032311A1; TW200308059A; US6982202B2; CN1628372A; WO2003067639A3

Abstract

The invention relates to NROM memory cells that are disposed in trenches that are etched into the semiconductor material. The memory layer composed of a nitride layer (3) that is interposed between two oxide layers (2, 4) is applied to the trench walls before the dopants for source and drain (7) are implanted. The implantation regions of source and drain are thus prevented from being damaged by the high temperature loads of the component during production of the memory layer as the respective dopant is introduced only later on. Polysilicon gate electrodes (5) are connected to word lines (11).

Description

description

Manufacturing process for memory cell

The present invention relates to a manufacturing method for an NROM memory cell.

In the publication by B. Eitan et al. : "NROM: A Novel Localized Trapping, 2-Bit Nonvolatile Memory Cell" in IEEE Electron Device Letters 21, 543 to 545 (2000) describes a non-volatile memory cell in which between the channel area and the gate electrode, which is a component of the Word line forms, an oxide-nitride-oxide layer sequence is present as a storage medium. This memory cell is programmed by "Channel hot electron injection" and erased by "tunneling enhanced hot hole injection". During programming, charge carriers are trapped in the nitride layer of the storage layer. This component has a storage capacity of 2 bits, each of which is stored at the transition from source or drain to the channel area.

This memory cell requires relatively high voltages at the drain and gate for storage. This can lead to the so-called punch-through of the transistor if it is designed with a short channel length. The previous memory cells still have channel lengths of more than 250 n; the punch-through does not yet occur so strongly.

The object of the present invention is to indicate how

NROM cells with reduced channel length and reduced space requirements can be designed to be functional.

This object is achieved with the method for producing a memory cell with the features of claims 1 and 2, respectively. Refinements result from the dependent claims. In the specified method, the NROM memory cells are arranged in trenches which are etched into the semiconductor material. The storage layer, which preferably consists of a nitride layer between oxide layers, is applied to the trench walls before the dopants for source and drain are implanted. In this way it is achieved that the high temperature load on the component during the production of the storage layer cannot impair the implantation regions of the source and drain, since the dopant in question is only introduced subsequently. This gives very sharp pn junctions as a junction of the source-drain regions. A precise transition between the source-drain regions and the channel region is required for effective programming with "channel hot electrons".

The electrical connection of the gate electrode of the memory transistor, which is preferably part of a word line of a memory cell array, is conducted via an insulation layer, which isolates this conductor from the source-drain

Separates areas. In a first embodiment of the method, this insulation layer replaces an upper layer portion of the semiconductor material; in a second exemplary embodiment, the gate electrode is formed so as to protrude higher above the semiconductor material, an auxiliary layer applied to the semiconductor material being used. In the latter second exemplary embodiment, however, there is a step between the area of the memory cell array and the area of the drive periphery.

The following is a more detailed description of examples of the production process with reference to FIGS. 1 to 8.

Figures 1 to 4 show cross sections of intermediate products of a first embodiment of the manufacturing process. Figures 5 to 7 show cross sections of intermediate products of a second embodiment of the manufacturing process.

FIG. 8 shows the layout of a memory cell array in supervision.

In the first exemplary embodiment, a hard mask, for example a first mask, is first applied to the upper side of a semiconductor body or a semiconductor layer structure. B. a nitride applied. The cell field is defined with this hard mask. This is followed by a photo mask technique, with which a mask is formed which has a window in the region of a trench to be produced. Using this mask, at least one trench is etched into the semiconductor material; a plurality of trenches aligned parallel to one another are preferably etched to form a memory cell array. The photoresist is removed.

1 shows a cross section of a section from the

Semiconductor body 1 shown, in which two trenches are produced in the area of the reference symbols T. The storage layer is then applied to the trench walls. The storage layer u preferably comprises a first oxide layer 2, the nitride layer 3 provided as the actual storage medium and a second oxide layer 4. Material which is provided for the gate electrode 5, preferably polysilicon, is deposited in the trench. This material is etched back to the height shown in FIG. 1. The hard mask is removed.

A cover layer is then deposited, which is preferably nitride. This cover layer is removed except for the portions of the cover layer 6 shown in FIG. 1. In the case of a nitride cover layer, this is preferably done by means of CMP (chemical mechanical polishing). After the material of the gate electrode 5 is covered in this way , the semiconductor material, preferably silicon, is removed in the area between the trenches down to an intended depth. Thereafter, spacers are produced on both sides of the trench filling, and a dopant provided for the source-drain regions is implanted in the semiconductor material located between the trenches. The semiconductor body preferably has a p-type basic doping. In this case, the implantation of the dopant for n ^{+ line is} carried out.

FIG. 2 shows the structure with the spacer elements 8 and the source-drain regions 7 produced by the implantation. These regions are also silicided. The insulation layer 9 is then produced, which can be done by applying TEOS and then CMP in a manner known per se.

When a memory cell array is formed, a multiplicity of memory cells arranged in a grid are produced, for which purpose the gate electrodes are interrupted at regular intervals transversely to the longitudinal direction of the trenches. In the areas present in the longitudinal direction of the trenches between the memory cells to be formed, the relevant portions of the cover layer 6 and the material of the gate electrodes 5 are removed by means of a further photomask technique. After the removal of the photoresist, these areas are filled with insulating material 10, preferably also by deposition of TEOS and CMP, in accordance with the structure shown in FIG. 3. The structures shown in FIG. 2 and in FIG. 3 correspond to cross sections through the component, which follow one another at uniform intervals in front of and behind the plane of the drawing.

According to FIG. 4, a word line 11 can be applied and structured over the remaining gate electrodes 5. The material provided for this can preferably Tungsten, which is siliconized on the polysilicon of the gate electrode.

In an alternative exemplary embodiment, according to FIG. 5, an auxiliary layer 12 is applied to the top of the semiconductor body 1 or a semiconductor layer structure. B. can be a pad nitride. A photomask technique then follows, with which a mask is produced which has openings in the region of the trenches to be produced. The auxiliary layer 12 is removed in these areas identified by the reference symbol T in FIG. The photoresist is then removed. Using the remaining portions of the auxiliary layer 12 as a mask, the trenches are then etched into the semiconductor material. The storage layer is then applied to the trench walls, which here too is preferably a nitride layer 3 between a first oxide layer 2 and a second oxide layer 4. According to the illustration in FIG. 5, the material provided for the gate electrodes 15, here also preferably polysilicon, is introduced into the trenches and, if necessary, removed and planarized on the surface. The auxiliary layer 12 is then removed in the area of the memory cell field to be produced, which is again done using suitable photomask technology.

After the photoresist has been removed, the spacer elements 8 shown in FIG. 6 are produced in a manner known per se, preferably by isotropic deposition and anisotropic etching back of a suitable material. The dopant is implanted for the source-drain regions 7, which are silicided as required. The insulation layer 9 is then applied, which can also be done here by deposition of TEOS and subsequent CMP. The structure shown in FIG. 6 thus results. When a memory cell array is formed, the material of the gate electrodes 15 is removed in the longitudinal direction of the trenches between the individual memory cells and is insulated by material, preferably by deposition of TEOS. However, the structure in these areas between the memory cells corresponds, with the exception of the material in the area designated by reference number 15, to the structure shown in FIG. 6, which is why a further drawing has been omitted here. Only the material of the gate electrodes 15 has been replaced at regular intervals in front of and behind the plane of the drawing by the insulating material.

FIG. 7 shows the structure of the memory cell array after the electrical connection of the gate electrodes 15 has been applied. In this example, too, a word line 13, preferably made of tungsten, is applied and structured in parallel strips.

The layout of the memory cell array is shown in a schematic plan view in FIG. The alignment of the word lines WL, which run parallel to one another, and the alignment of the bit lines BL, which also run parallel to one another, are shown here. The bit lines are formed by the doped regions of the source-drain regions 7 of the individual memory cells, which, however, are not interrupted in the longitudinal direction of the trenches. Since the areas are hidden under the insulation layer 9 in the plan view shown, their boundaries are drawn with hidden lines as hidden contours. The strip-shaped conductors 11/13 of the word lines are on the top. The respective gate electrodes of the individual memory cells are present below the strip-shaped conductors with the same lateral boundaries. In the trenches, the material of the gate electrodes is replaced by the insulating material 10 between the word lines.

The hatched areas 14 are available for programming possible on both sides in each memory cell Available. In these regions 14, in the vicinity of the pn junction between the source-drain regions 7 and the respective channel region, charge carriers are injected into the nitride layer 3 of the memory layer sequence when programming the memory cell. In principle, it is therefore sufficient if the nitride layer is present at least in these regions of the pn junction.

If in a single memory cell the doped region 7 on the left side of the relevant trench in the figure is referred to as the drain and on the right side of the relevant trench in the figure as the source, the programming of the memory cell on the left side can be carried out more typically by applying the following Voltages occur: 5 volts on the drain, 10 volts on the control gate and 0 volts on the source. When programming on the right-hand side, the voltages at the source and drain must be interchanged. To erase the cell, 5 volts are typically applied to the source and drain, while minus 5 volts are applied to the control gate. To read the left memory content, a voltage of typically 0 volts is applied to the drain area, 2 volts to the control gate and 1.2 volts to the source. To read out the memory content on the right, the voltages of the source and drain are interchanged.

LIST OF REFERENCE NUMBERS

1 semiconductor body

2 first oxide layer 3 nitride layer

4 second oxide layer

5 gate electrode

6 cover layer

7 source-drain regions 8 spacer

9 insulation layer

10 insulating material

11 word line

12 auxiliary layer 13 word line

14 highlighted area

15 gate electrodes

Claims

claims

1. A method for producing a memory cell, in which on a top side of a semiconductor body (1) or a semiconductor layer structure over a channel region provided between doped source-drain regions (7) a memory layer (2, 3, 4) which is suitable for a Programming is carried out by trapping charge carriers, and a gate electrode (5) electrically insulated from the semiconductor material is produced, characterized in that in a first step at least one trench is produced in the upper side, in a second step at least to the source to be produced Drain areas (7) adjacent portions of the trench walls are provided with the storage layer (2, 3, 4), in a third step a material provided for the gate electrode (5) is deposited in the trench, in a fourth step the gate -Electrode (5) covered and removed on both sides of the trench and the semiconductor material to a specified depth e dopant is implanted to form the source-drain regions (7) and in a fifth step an insulation layer (9) is applied to the source-drain regions (7) and an electrical connection for the gate electrode (5 ) will be produced.

2. A method for producing a memory cell, in which on a top side of a semiconductor body (1) or a semiconductor layer structure over a channel region provided between doped source-drain regions (7) a memory layer (2, 3, 4) which is suitable for a Programming is carried out by trapping charge carriers, and a gate electrode (15) electrically insulated from the semiconductor material is produced, characterized in that, in a first step, an auxiliary layer (12) is applied to the upper side, in a second step, at least one trench is produced in the auxiliary layer and the semiconductor material underneath, in a third step at least portions of the trench walls adjacent to the source-drain regions (7) to be produced are provided with the storage layer (2, 3, 4) , in a fourth step, a material provided for the gate electrode (15) is deposited in the trench, in a fifth step the auxiliary layer is removed and dopant is implanted on both sides of the trench to form the source-drain regions (7) and in In a sixth step, an insulation layer (9) is applied to the source-drain regions (7) and an electrical connection is made for the gate electrode (15).

3. The method according to claim 1 or 2, in which a cell array is produced, the source-drain regions (7) are provided as bit lines and the electrical connections of the gate electrodes are formed as word lines.

4. The method according to any one of claims 1 to 3, in which the storage layer (2, 3, 4) is applied as an oxide-nitride-oxide layer sequence.