KR20170116156A - Optimization of metal planarization process - Google Patents

Abstract

The present invention removes the bulk metal layer on the upper surface of the interconnect structure by a stressed polishing process until the thickness of the remaining metal layer reaches the predetermined value Y, Wherein the residual metal layer has a first average surface roughness Ra1 induced by a stressed polishing process; The upper surface of the metal layer in the recessed region of the interconnect structure is interconnected by a dicing value H2 after the unstressed polishing process to remove the residual metal layer on the upper surface of the interconnect structure by an unstressed polishing process, Wherein the metal layer in the recessed region has a second average surface roughness Ra2 induced by the unstressed polishing process and the removed thickness of the unstressed polishing process is Ra2 ≪ / RTI > to obtain a ratio alpha; When the dicing value H2 for obtaining the minimum metal surface roughness after the polishing step not subjected to the stress is set, the thickness Y of the residual metal layer after the stressed polishing step satisfies the following formula: Y =? / 6 * H2? Lt; RTI ID = 0.0 > planarization < / RTI > process.

Description

Optimization of metal planarization process

FIELD OF THE INVENTION The present invention relates generally to semiconductor manufacturing, and more particularly to a method for optimizing a metal planarization process.

In the interconnection structure manufacturing process, with the shrinking of the line width and the application of copper and low k dielectric materials, interconnection structure planarization techniques have more stringent requirements than in the past. Currently, at least two types of techniques used to planarize metals on interconnect structures include polishing processes where stresses are applied, such as CMP, and polishing processes where stress is not applied, such as electrochemical polishing. CMP uses a slurry and a down force to remove the metal. CMP is still the most commonly used planarization technology, but with advances in semiconductor technology, bottlenecks and problems in the CMP process are gradually evolving. CMP has a number of adverse effects on the underlying structures of the interconnected structures because relatively strong mechanical forces are involved. In particular, if the k value of the dielectric material decreases gradually, mechanical forces can cause permanent damage to the dielectric material.

Electrochemical polishing removes the metal on the interconnect structure using a charged electrolyte. Because only the charged electrolyte is in contact with the metal surface, the electrochemical polishing process will not have mechanical forces, and mechanical forces will not cause damage to the low k dielectric material. The charged electrolyte is released to the metal surface and reacts with the metal. Metal ions are delivered to the cathode. In the electrochemical polishing process, the metal surface can be considered as the anode. Thus, as a by-product, large bubbles are produced on the metal surface, which makes the roughness of the metal surface worse. As is known, the smaller the amount of bubbles on the metal surface after electrochemical polishing, the better the metal surface roughness. Therefore, in order to improve the metal surface roughness, the amount of bubbles on the metal surface must be controlled. The amount of bubbles is proportional to the electrochemical polishing time. The shorter the electrochemical polishing time, the smaller the amount of bubbles. In addition, the electrochemical polishing time is proportional to the electrochemical polishing removal thickness. The smaller the electrochemical polishing thickness, the shorter the electrochemical polishing time. Based on the above relationship, the smaller the electrochemical polishing removal thickness after the electrochemical polishing, the better the surface roughness of the metal can be obtained.

To improve planarization efficiency and reduce electrochemical removal thickness, CMP and electrochemical polishing are combined to planarize the metal on the interconnect structure. First, the bulk metal on the upper surface of the interconnect structure is removed by CMP, and a continuous metal layer covering the upper surface of the interconnect structure remains. The continuous metal layer can withstand the mechanical forces of the CMP for protection of the low k dielectric material from damage. Subsequently, the continuous metal layer on the upper surface of the interconnect structure is removed by electrochemical polishing, and the underlying structure of the interconnect structure such as the barrier layer is exposed. The method of finding the optimum thickness after CMP, as well as the removal thickness of the electrochemical polishing, is very important for controlling the final metal surface roughness and dishing. If the thickness of the residual metal layer after CMP is too thin, it is difficult to ensure that the metal layer can completely cover the top surface of the interconnect structure and there is a possibility that the low k dielectric material will be damaged during the process. If the thickness of the residual metal layer after CMP is too thick, this means that the electrochemical polishing removal thickness is thick, which may lead to poor surface quality of the metal surface after electrochemical polishing.

The present invention provides a method of optimizing a metal planarization process comprising the steps of:

Removing the bulk metal layer on the upper surface of the interconnect structure by a stressed polishing process until the thickness of the remaining metal layer reaches the predetermined value Y, wherein the residual metal layer is a continuous layer covering the upper surface of the interconnect structure, The residual metal layer having a first average surface roughness Ra1 induced by a stressed polishing process;

The upper surface of the metal layer in the recessed region of the interconnect structure is interconnected by a dicing value H2 after the unstressed polishing process to remove the residual metal layer on the upper surface of the interconnect structure by an unstressed polishing process, Wherein the metal layer in the recessed region has a second average surface roughness Ra2 induced by the unstressed polishing process and the removed thickness of the unstressed polishing process is Ra2 ≪ / RTI > to obtain a ratio alpha;

When the dicing value H2 for obtaining the minimum metal surface roughness after the polishing step not subjected to the stress is set, the thickness Y of the residual metal layer after the stressed polishing step satisfies the following formula: Y =? / 6 * H2? Lt; RTI ID = 0.0 > planarization < / RTI > process.

As described above, in order to avoid the damage of the internal structure of the interconnecting structure against the mechanical force of the stressed polishing process and to improve the surface roughness of the metal after the unstressed polishing process, a stressed polishing process The thickness of the remaining metal layer after the step needs to satisfy the following requirements: the thickness of the remaining metal layer is as thin as possible; The remaining metal layer is a continuous layer covering the upper surface of the interconnect structure; When the target dishing value is set, the thickness of the residual metal layer satisfies the following formula: Y =? / 6 * H2 -? Ra1.

The present invention will become apparent to those skilled in the art from the following description of the embodiments with reference to the accompanying drawings, in which:
1 is a cross-sectional view of an interconnect structure in which a metal layer is not removed.
2 is a cross-sectional view showing that the bulk metal layer on the upper surface of the interconnect structure is removed by CMP.
3 is a cross-sectional view showing that the residual metal layer on the upper surface of the interconnect structure is completely removed by electrochemical polishing.
4 is a cross-sectional view showing the critical state of the residual metal layer on the upper surface of the interconnect structure removed by electrochemical polishing, with some residual metal on the space areas of the interconnect structure.
5 is a cross-sectional view showing that the residual metal on the free space of the interconnect structure is completely removed by electrochemical polishing.
6 is a graph showing the relationship between the electrochemical removal thickness and the average roughness after the CMP and electrochemical polishing process.
7 is a graph showing the relationship between the electrochemical abrasion removal thickness and the average roughness induced by the electrochemical polishing process.
FIG. 8 shows the relationship between the electrochemical abrasion removal thickness and the average roughness Ra1, CMP induced by the CMP process and the average roughness Ra after the electrochemical polishing process, the average roughness Ra2 derived by the electrochemical polishing process, And a value? Divided by an average roughness Ra2 derived by a chemical polishing process.
9 is a cross-sectional view showing that the bulk metal layer on the upper surface of the interconnect structure having different line widths and line densities is removed by CMP.

The present invention relates to a method of optimizing a metal planarization process by adjusting the thickness of a residual metal layer on the upper surface of an interconnect structure after a CMP process to improve the surface roughness of the metal after the remnant metal layer is removed by an electrochemical polishing process .

Referring to Figure 1, an exemplary interconnect structure is shown. It will be appreciated that the formation of the interconnect structure is not limited to the exemplary interconnect structure shown in FIG. Depending on the different process requirements, the formation of the interconnect structure may be different. As shown in Figure 1, an exemplary interconnect structure comprises a substrate 101, a first dielectric layer 102 formed on the substrate 101, a second dielectric layer 103 formed on the first dielectric layer 102, A hard mask layer 104 formed on the dielectric layer 103, a hard mask layer 104, a second dielectric layer 103 and a recess region 108 formed on the first dielectric layer 102, for example, a trench (not shown) a first barrier layer 105 formed on the hardmask layer 104 such as trenches or vias, bottoms of the sidewalls and recessed regions 108 of the recessed regions 108, a first barrier layer 105 And a metal layer 107 formed on the second barrier layer 106 and filling the recessed region 108. The second barrier layer 106 is formed on the first barrier layer 106 and the second barrier layer 106. [

After the metal layer 107 is formed on the second barrier layer 106 and filling the recessed area 108, the subsequent process is to remove the metal layer 107 on the upper surface of the interconnect structure. First, a stressed polishing process such as CMP is used to remove the bulk metal layer 107 and to leave a metal layer 107 of a specific thickness. The thickness of the residual metal layer 107 after CMP is preferably as thin as possible in order to avoid damage to the underlying structure of the interconnect structure by resisting the mechanical force of the CMP and to improve the surface roughness of the metal after electrochemical polishing, 107 are continuous layers covering the upper surface of the interconnect structure as shown in Fig.

Next, as shown in Fig. 3, the residual metal layer 107 on the upper surface of the interconnect structure is removed using an unstressed polishing process, for example, electrochemical polishing. After the residual metal layer 107 on the upper surface of the interconnect structure is removed, the second barrier layer 106 is exposed. Considering that the first barrier layer 105 and the hard mask layer 104 on the upper surface of the interconnect structure and the second barrier layer 106 are removed in the next process, the metal layer 107 in the recess region 108, May be the same height as the upper surface of the second dielectric layer 103 or may be somewhat lower than the upper surface of the second dielectric layer 103. [

The present invention teaches how to obtain the thickness of the residual metal layer 107 after CMP.

To simplify the calculation, it is assumed that the metal layer has the same thickness over the top surface of the interconnect structure. In other words, the thickness of the metal layer on the upper surface of the interconnect structure before removing the metal layer on the upper surface of the interconnect structure by CMP is the same regardless of whether the line width and line density of the interconnect structure are the same. After the CMP and electrochemical polishing processes are completed, the metal surface maximum roughness satisfies the following equation:

Rt = Rt1 + Rt2

Here, Rt is the maximum surface roughness of the metal surface after CMP and the electrochemical polishing process are completed, Rt1 is the surface roughness of the metal induced by the CMP process, and Rt2 is the surface roughness of the metal induced by the electrochemical polishing process.

Based on the statistical normal distribution, at 3 sigma (3 sigma) condition, Rt = 6 Ra and Ra is the average surface roughness of the metal surface after the CMP and electrochemical polishing process is completed. The relationship can be described as follows:

Rt = Rt1 + Rt2 = 6Ra1 + 6Ra2

Here, Ra1 is the average surface roughness of the metal surface induced by the CMP process, and Ra2 is the average surface roughness of the metal surface induced by the electrochemical polishing process.

Referring to FIG. 5, if the first barrier layer 105 and the hard mask layer 104 on the upper surface of the interconnect structure and the second barrier layer 106 are not removed in the next step, Is equal to the upper surface height of the second barrier layer 106 in the sense region 108 minus the upper surface height of the metal layer 107.

4, the upper surface of the metal layer 107 in the recess region 108 is in contact with the second barrier layer 106 in the critical state in which the residual metal layer on the upper surface of the interconnect structure is removed by electrochemical polishing, And the height of the upper surface of the substrate. There is some residual metal 107 in the clearance of the interconnect structure, and usually the remaining metal height H1 is equal to Rt. It can be seen that the metal surface roughness, especially Rt, after the CMP and electrochemical polishing process is complete determines the minimum dishing. The dishing H2 should not be less than Rt (H2 > Rt). If the condition of H2 > = Rt is satisfied, the residual metal can be completely removed. The relationship between the thickness of the residual metal layer 107 after CMP and the minimum dishing satisfies the following equation:

Y =? / 6 (H2-Rt1) =? / 6 * H2-?

Where Y is the optimal thickness of the residual metal layer after CMP and H2 is the minimum dishing, which is a target value set according to the process requirements, where H2 is a known quantity and? Is equal to the electrochemical abrasion removal thickness divided by Ra2 , and α is an empirical equation obtained through experiments. The ratio α is determined by the electrolyte type, viscosity, temperature, substrate rotation speed, horizontal movement speed, current, voltage, and the like.

As described above, in order to improve the surface roughness of the metal after electrochemical polishing without damaging the substructure of the interconnect structure against the mechanical force of CMP, the thickness of the residual metal layer after CMP must satisfy the following requirements: The thickness of the residual metal layer is as thin as possible; The remaining metal layer is a continuous layer covering the upper surface of the interconnect structure; When setting the target dishing value, the thickness of the residual metal layer satisfies the following equation: Y =? / 6 (H2-Rt1) =? / 6 * H2-?

Considering that the first barrier layer 105 and the hard mask layer 104 on the upper surface of the second barrier layer 106 and the interconnect structure are removed in the next step, the actual thickness of the remaining metal layer after CMP is determined by the following requirements Lt; / RTI >

Y '= YY _b -Y _m

Here, Y 'is the actual thickness of the residual metal layer after CMP, Y _b is the total thickness of the second barrier layer 106 and the first barrier layer 105, and Y _m is the thickness of the hard mask layer 104.

Referring to Fig. 9, in another embodiment of the present invention, the interconnect structure has different linewidths and linear densities. In the plating process, the line width and linear density cause a difference in step height between different line areas, which determines the uniformity of the height of the metal layer. The height of the metal layer covering the free area is 0 angstrom and can be considered as a reference plane. Generally, the height of a metal layer covering a wide line is lower than the reference plane. Conversely, the height of the metal layer covering the narrow line is higher than the reference plane. In order to completely remove the metal layer on the upper surface of the interconnect structure, the metal layer on the narrow line must be completely removed completely. On the other hand, since the electrochemical polishing process is a conformal process, if the metal layer on the narrow line is completely removed, the electrochemical polishing process will lead to dishing of a broad line. The depth of dishing is determined by the step difference and the density of the line after the CMP process. The dishing satisfies the following equation:

Rx = Tmin / Dx - Tx

Here, Rx is the dishing of the line width of the x region, Tmin is the step of the minimum line width with respect to the reference plane, Dx is the density of the line width of the x region, and Tx is the step of the line width of the x region with respect to the reference plane.

For example, if the line width of the smallest line is 28 nm, the minimum narrow line step to the reference plane is 200 angstroms, the line width of the wide line is 10 um, the wide line step to the reference plane is -100 angstroms, If removed, the density of the broad line is 50%, and the dishing of the linewidth in the 10 um area is as follows.

R10 = Tmin / D10-T10 = 200/50% - (-100) = 500 Angstroms

In combination with the formula Y '= Y-Yb-Ym, when the interconnect structure has different line widths and linear densities, the actual thickness of the residual metal layer after CMP satisfies the following equation:

Y '' = α '/ 6 (H2 + Tmin-Rt1) = α' / 6 * (H2 + Tmin)

alpha '= (Y' + Tmin) / Ra2 '

Where Y "is the actual thickness of the residual metal layer after the stressed polishing process and Tmin is the step of the minimum line width relative to the reference surface.

Ra2 'is obtained according to two aspects:

1) thickness Y '+ Tmin removed by electrochemical polishing (unstressed polishing process); And

2) The relationship between the electrochemical polish removal thickness and the average surface roughness of the metal surface induced by the electrochemical polishing process, as shown in Fig.

As described above, the thickness of the residual metal layer after CMP must satisfy the formula requirement to completely remove the metal layer on the upper surface of the interconnect structure and obtain the target dishing and minimum metal surface roughness, the step height of the die should be as low as possible, Especially, the step of narrow line should be optimized and should be zero.

The foregoing description of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teachings. Such modifications and variations that may be apparent to those skilled in the art are intended to be included within the scope of the present invention as defined by the appended claims.

Claims (7)

Removing the bulk metal layer on the upper surface of the interconnect structure by a stressed polishing process until the thickness of the remaining metal layer reaches the predetermined value Y, wherein the residual metal layer is a continuous layer covering the upper surface of the interconnect structure, The residual metal layer having a first average surface roughness Ra1 induced by a stressed polishing process;
The upper surface of the metal layer in the recessed region of the interconnect structure is interconnected by a dicing value H2 after the unstressed polishing process to remove the residual metal layer on the upper surface of the interconnect structure by an unstressed polishing process, Wherein the metal layer in the recessed region has a second average surface roughness Ra2 induced by the unstressed polishing process and the removed thickness of the unstressed polishing process is Ra2 ≪ / RTI > to obtain a ratio alpha;
When the dicing value H2 for obtaining the minimum metal surface roughness after the polishing step not subjected to the stress is set, the thickness Y of the residual metal layer after the stressed polishing step satisfies the following formula: Y =? / 6 * H2? Lt; RTI ID = 0.0 > planarization < / RTI > process.

The method according to claim 1,
Wherein the metal layer has the same thickness as the upper surface of the interconnect structure before the metal layer on the upper surface of the interconnect structure is removed by a stressed polishing process.
The method according to claim 1,
Wherein the maximum polishing of the metal surface satisfies the following equation after the stressed polishing step and the unstressed polishing step are completed.
Rt = Rt1 + Rt2
Where Rt is the maximum roughness of the metal surface after the stressed polishing process and the unfinished polishing process are completed, Rt1 is the roughness of the metal surface induced by the stressed polishing process, and Rt2 is the roughness Is the roughness of the metal surface induced by the unsupported polishing process.
The method of claim 3,
Wherein, based on the statistical normal distribution, in the three sigma condition, the Rt satisfies the following equation.
Rt = Rt1 + Rt2 = 6Ra1 + 6Ra2
The method of claim 3,
Lt; RTI ID = 0.0 > Rt. ≪ / RTI >
The method according to claim 1,
The interconnection structure comprising at least one barrier layer and a hard mask layer in consideration of removal of the barrier layer and the hard mask layer on the upper surface of the interconnect structure, wherein the actual thickness of the residual metal layer after the stressed polishing process ≪ / RTI > satisfies the following equation.
Y'YY _b -Y _m
Where Y 'is the actual thickness of the residual metal layer after the stressed polishing process, Y _b is the thickness of the barrier layer, and Y _m is the thickness of the hard mask layer.
The method according to claim 6,
Wherein the interconnect structure has a different linewidth and wherein the height of the metal layer covering the free space is used as a reference plane and the actual thickness of the residual metal layer after the stressed polishing process satisfies the following equation:
Y '' = α '/ 6 * (H2 + Tmin) -α'Ra1
alpha '= (Y' + Tmin) / Ra2 '
Here, Y "is the actual thickness of the residual metal layer after the stressed polishing process, Tmin is the step of the minimum line width with respect to the reference plane, and Ra2 'is obtained as follows.
Thickness Y ' + Tmin removed by a non-stressed polishing process; And
The relationship between the thickness removed by the unstressed polishing process and the average roughness of the metal surface induced by the unstressed polishing process.

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