Polishing slurries for copper and associated materials

Information

  • Patent Grant
  • 6409781
  • Patent Number
    6,409,781
  • Date Filed
    Monday, May 1, 2000
    24 years ago
  • Date Issued
    Tuesday, June 25, 2002
    22 years ago
Abstract
A chemical mechanical polishing slurry and method for using the slurry for polishing copper, barrier material and dielectric material that comprises a first and second slurry. The first slurry has a high removal rate on copper and a low removal rate on barrier material. The second slurry has a high removal rate on barrier material and a low removal rate on copper and dielectric material. The first and second slurries at least comprise silica particles, an oxidizing agent, a corrosion inhibitor, and a cleaning agent.
Description




BACKGROUND OF THE INVENTION




The present invention relates to a chemical mechanical polishing slurry for surfaces of a semiconductor wafer, and more particularly, to a chemical mechanical polishing slurry and a method for using the slurry to remove and polish copper, barrier materials and dielectric materials layered on semiconductor wafer surfaces.




Semiconductor wafers are used to form integrated circuits. The semiconductor wafer typically includes a substrate, such as silicon, upon which dielectric materials, barrier materials, and metal conductors and interconnects are layered. These different materials have insulating, conductive or semi-conductive properties. Integrated circuits are formed by patterning regions into the substrate and depositing thereon multiple layers of dielectric material, barrier material, and metals.




In order to obtain the correct patterning, excess material used to form the layers on the substrate must be removed. Further, to obtain efficient circuits, it is important to have a flat or planar semiconductor wafer surface. Thus, it is necessary to polish certain surfaces of a semiconductor wafer.




Chemical Mechanical Polishing or Planarization (“CMP”) is a process in which material is removed from a surface of a semiconductor wafer, and the surface is polished (planarized) by coupling a physical process such as abrasion with a chemical process such as oxidation or chelation. In its most rudimentary form, CMP involves applying slurry, a solution of ah abrasive and an active chemistry, to a polishing pad that buffs the surface of a semiconductor wafer to achieve the removal, planarization, and polishing process. It is not desirable for the removal or polishing process to be comprised of purely physical or purely chemical action, but rather the synergistic combination of both in order to achieve fast uniform removal. In the fabrication of integrated circuits, the CMP slurry should also be able to preferentially remove films that comprise complex layers of metals and other materials so that highly planar surfaces can be produced for subsequent photolithography, or patterning, etching and thin-film processing.




Recently, copper has been used as the metal interconnect for semiconductor wafers. Typically fore copper technology, the layers that are removed and polished consist of a copper layer (about 1-1.5 μm thick) on top of a thin copper seed layer (about 0.05-0.15 μm thick). These copper layers are separated from the dielectric material surface by a layer of barrier material (about 50-300 Å thick). The key to obtaining good uniformity across the wafer surface after polishing is by using a slurry that has the correct removal selectivities for each material. If appropriate material removal selectivity is not maintained, unwanted dishing of copper and/or erosion of the dielectric material may occur.




Dishing occurs when too much copper is removed such that the copper surface is recessed relative to the dielectric surface of the semiconductor wafer. Dishing primarily occurs when the copper and barrier material removal rates are disparate. Oxide erosion occurs when too much dielectric material is removed and channels are formed in the dielectric material on the surface of the semiconductor wafer relative to the surrounding regions. Oxide erosion occurs when the dielectric material removal rate is locally much higher than the copper removal rate. Dishing and oxide erosion are area dependent being wafer pattern and pitch dependent as well.




Typical commercial CMP slurries used to remove overfill material and polish semiconductor wafer surfaces have a barrier material removal rate below 500 Å/min. Further, these slurries have a copper to barrier material removal rate selectivity of greater than 4:1. This disparity, in removal rates during the removal and polishing of the barrier material results in significant dishing of copper on the surface of the semiconductor wafer and/or poor removal of the barrier material.




Another problem with conventional CMP slurries is that the removal chemistry of the slurry is compositionally unstable. Further, many of the colloidal abrasives agglomerate after relatively short time frames following addition to the supporting chemistry. Both of these problems lead to significant operational obstacles.




A further problem in commercial CMP slurries is that the abrasive materials in the slurries produce defects in the form of micro scratches. These slurries also have poor planarization efficiency, which is the ability of the slurry to polish high points preferentially over low points on the surface of the wafer. Micro scratches and poor planarization efficiency result in integrated circuits with increased defects and a lower yield.




Still another problem of commercial CMP slurries is that the chemicals that make up the slurries produce a copper surface that has a high corrosion tendency post polish.




An object of this invention, therefore, is a CMP slurry that employs a two-step slurry approach. The slurry used in the first step has a high copper removal rate and a comparatively low barrier material removal rate. The slurry used in the second step has a relatively high barrier material removal rate, comparable removal rate for copper and low removal rate on the dielectric material. By using this two-step slurry approach, the first and second slurries can provide the appropriate selectivity ranges to minimize copper dishing and oxide erosion, thereby providing a viable CMP approach to advanced device manufacturing.




Another object of the invention is for the first and second slurries to have stable removal chemistry.




Yet another object is to use abrasives in the first slurry that achieve high copper removal rates, but minimal barrier material removal rates, and to use abrasives in the second slurry that provide superior removal rates on barrier material and low removal rates for copper, which also minimize micro scratch defects and provide very good planarization efficiency.




It is a further object of this invention to employ active copper cleaning chemistry and corrosion inhibitors in the slurry to minimize copper corrosion post polish, and to eliminate post-polish cleaning steps.




These and other objects and advantages of the invention will be apparent to those skilled in the art upon reading the following detailed description and upon reference to the drawings.




SUMMARY OF THE INVENTION




The present invention is directed to a chemical mechanical polishing slurry comprising a first slurry, which has a high removal rate on copper and a low removal rate on barrier material and a second slurry, which has a high removal rate on barrier material and a low removal rate on copper and the associated dielectric material. The first and second slurries comprise silica particles, an oxidizing agent, a corrosion inhibitor, and a cleaning agent. Also disclosed as the present invention is a method for chemical mechanical polishing copper, barrier material and dielectric material with the polishing slurry of the present invention. As will become apparent from the discussion that follows, the stable slurry and method of using the slurry provide for removal of material and polishing of semiconductor wafer surfaces with significantly no dishing or oxide erosion, with significantly no surface defects and good planarization efficiency, and produce a copper surface with minimal corrosion tendency post-polish.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a cross-sectional view of a semiconductor wafer prior to chemical mechanical polishing.





FIG. 2

is a cross sectional view of the semiconductor wafer of

FIG. 1

following chemical mechanical polishing with the first slurry, according to the present invention.





FIG. 3

is a cross sectional view of the semiconductor wafer of

FIG. 2

following chemical mechanical polishing with the second slurry, according to the present invention.





FIG. 4

is a cross sectional view of a semiconductor wafer illustrating copper dishing.





FIG. 5

is a cross sectional view of a semiconductor wafer illustrating oxide erosion.





FIG. 6

is a transmission electron micrograph (TEM) showing 13 nm silica particles of the present invention.





FIG. 7

is the size distribution of 13 nm silica particles of the present invention determined with Coulter N4 Plus particle analyzer.











DETAILED DESCRIPTION OF THE INVENTION





FIG. 1

illustrates a semiconductor wafer


10


prior to CMP. As shown, substrate


11


may be made of any conventional semiconductor materials, including silicon or germanium or silicon-germanium. Layered on top of the substrate


11


is dielectric material


12


, which is preferentially silicon oxide, low k dielectrics comprised substantially of silicon oxide or a carbon containing silicon oxide. The instant invention is not limited to such dielectric materials and is also useful for removal of dielectrics such as fluoride doped silicon glass (FSG). Layered on the dielectric material


12


, is barrier material


13


. The barrier material layer


13


is typically about 50 to 300 Å thick. The barrier material


13


maX be any material conventionally used, but is typically chosen from the group of tungsten nitride, tantalum, tantalum nitride, titanium nitride, silicon doped tantalum nitride or silion doped titanium nitride. Finally, a layer of copper


14


covers the barrier material layer


13


, and extends into trenches


14




a,




14




b,


and


14




c.


The copper layer


14


is usually about 0. 1-0.15 μm thick and the copper layer


14


in

FIG. 1

includes a thin copper seed layer, which is usually about 0.05-0.15 μm thick.




The invention is a CMP slurry designed to polish copper


14


and associated barrier materials


13


such as tungsten nitride, tantalum, tantalum nitride, silicon doped tantalum nitride, titanium nitride and silicon doped titanium nitride. The chemical mechanical polishing slurry of the present invention is comprised of two parts. The first slurry is a copper selective slurry used to remove the bulk copper down to the barrier layer (FIG.


2


). The first slurry has a high removal rate of copper and a low removal rate of barrier material. The second slurry is selective to the barrier layer and removes the barrier material down to the dielectric material. The barrier and copper rate are comparable for this step (FIG.


3


). The various removal rates of the first and second slurries on various materials are shown in Table 1. In this way, two slurries together comprise a combined package to polish copper metallization schemes for integrated circuit manufacturing.












TABLE 1











Removal Rates of the First and Second Slurries on Different Materials*

















Selectivity







First Slurry




Second Slurry




Material:Cu
















Removal Rates




Removal Rates




First




Second






LAYER




(Å/min)




(Å/min)




Slurry




Slurry


















Copper




>5000




<1000








Tantalum




<500




>1000




1:10




1:1






Tantalum




<500




>1000




1:10




1:1






Nitride






Thermal Oxide




<150




<150




1:50




1:6











*(Down Force = 5 psi, Flow Rate = 200 mL/min, Table Speed = 90 rpm, Quill Speed = 50 rpm, Pad Type = IC 1000)













Referring to

FIG. 1

, the present invention includes a method for chemical mechanical polishing copper


14


, barrier material


13


and dielectric material


12


, comprises the following steps: (1) providing a first chemical mechanical polishing slurry that has a high removal rate on copper


14


and a low removal rate on barrier material


13


; (2) chemical mechanical polishing a semiconductor wafer surface


10


with the first slurry; (3) providing a second chemical mechanical polishing slurry that has a high removal rate on barrier material


13


a comparable removal rate on copper


14


and a low removal rate on the dielectric material


12


; and (4) chemical mechanical polishing the semiconductor wafer surface


10


with the second slurry.




Generally, the; slurry is applied to a pad contained on a polishing instrument. Polishing instrument parameters such as down force (DF), flow rate (FR), table speed (TS), quill speed (QS), and pad type can be adjusted to effect the results of the CMP slurry. These parameters are important in obtaining efficient planarization results and limiting dishing and erosion. Although these parameters may be altered, when used with the CMP slurry of the present invention, the standard conditions used are DF of 5 psi, FR of 200 mL/min, TS of 90 rpm, QS of 50 rpm, and the IC 1000 pad type.





FIG. 2

illustrates the semiconductor wafer


10


of

FIG. 1

, after steps (1) and (2) of the present method for CMP have been carried out, and the semiconductor wafer surface has been polished with the first slurry. When

FIG. 2

is compared to

FIG. 1

, the top copper layer


14


in

FIG. 1

has been preferentially removed, and only the copper in the trenches (

FIG. 2

)


18




a,




18




b,


and


18




c


is left. As shown in

FIG. 2

the barrier material layer


17


is substantially in tact, and the dielectric material


16


based on substrate


15


is still unexposed.




Similarly,

FIG. 3

illustrates the semiconductor wafer


10


of

FIGS. 1 and 2

, after steps (3) and (4) of the present method for CMP have been carried out, and the semiconductor wafer surface has been polished with the second slurry. As shown in

FIG. 3

, the barrier material layer


21


has been removed down to the dielectric material


20


. The second slurry also removed just enough of the copper in trenches


22




a,




22




b,


and


22




c


so that the surface of the semiconductor wafer


10


is flat and planar. The second slurry also serves to polish the newly exposed surface, including the dielectric material


20


, the barrier material


21




a,




21




b,




21




c,


and the copper


22




a,




22




b,




22




c.


All of these materials are based on substrate


19


.




By using the first and second slurries of the claimed invention, with the selectivities described in Table 1, and following the described method, copper dishing (

FIG. 4

) and oxide erosion (

FIG. 5

) can be minimized.

FIG. 4

shows a semiconductor wafer to which a CMP slurry has been applied, which had a higher selectivity for copper


26




a,




26




b,




26




c


than for the barrier material


25




a,




25




b,




25




c


or dielectric material


24


. As a result, disparate amounts of copper are removed from the surface of the semiconductor wafer. This is known as copper dishing and is shown by the dish-like troughs


27




a,




27




b,


and


27




c


in the trenches of copper


26




a,




26




b,




26




c.


The CMP slurry of the present invention and method of using this slurry greatly reduces copper dishing.




Similarly,

FIG. 5

shows a semiconductor wafer to which a CMP slurry has been applied, which has a higher selectivity for the dielectric material


29


than for the barrier material


30




a,




30




b,




30




c,


or copper


31




a,




31




b,




31




c.


As a result, disparate amounts of dielectric material are removed from the surface of the semiconductor wafer. This is known as oxide erosion and is shown by the indentions and/or reduction of the dielectric material


29




a,




29




b.


The CMP slurry of the present invention and method of using this slurry greatly reduces oxide erosion.




Turning now to the composition of the CMP slurry, generally the first and second slurries comprise silica particles, an oxidizing agent, a corrosion inhibitor, and a cleaning agent. The chemistry of the first and second slurries should be stable and have a pH in the range of about 2 to 5. The first and second slurries may contain potassium or ammonium hydroxide in such amounts to adjust the pH to a range of about 2 to 5.




The preferred oxidizing agent for the first and second slurries is potassium iodate formed by reaction of HIO


3


with KOH. The corrosion inhibitor and cleaning agent for the first and second slurries should be a carboxylic acid. More specifically, the carboxylic acid may be chosen from the group of glycine, oxalic acid, malonic acid, succinic acid and nitrilotriacetic acid. Alternatively, the carboxylic acid may be a dicarboxylic acid that preferentially has a nitrogen containing functional group. In the most preferred form, the corrosion inhibitor and cleaning agent for the first and second slurries is iminodiacetic acid. Inorganic acids such as phosphoric, nitric and hydrochloric were added to adjust pH and accelerate copper removal rates.




The use of potassium iodate as the oxidizing agent and carboxylic acids as the corrosion inhibitors and cleaning agents and inorganic acids as accelerating agents creates a stable removal chemistry in the pH region of about 2 to 5, for the first and second slurries. Further, the use of copper corrosion inhibitors and cleaning agents minimizes copper corrosion, as indicated by low static etch rates of roughly less than 50 Å/min on copper.




The silica particles of the first and second slurries can be precipitated. The precipitated particles usually range from about 3 to 100 nm in size and can be spherical. An alternative to precipitated silica particles in the first slurry is fumed silica. Generally, the fumed silica has a mean particle size of less than 700 nm.




Alternatively, and more preferred is to use colloidal silica particles of the type described. The colloidal silica particles can range from about 3 to 100 nm in size, and can be spherical. Preferentially, when the first and second slurries employ spherical colloidal particles, the particles should have a narrow size distribution. More specifically, about 99.9% of the spherical colloidal particles should be within about 3 sigma of a mean particle size with negligible particles larger than about 500 nm.




The first slurry, thus, can employ either precipitated spherical silica particles in the size range of 3 to 100 nm, or fumed silica with mean particle size less than about 700 nm. These particles coupled with the iodate chemistry allows the first slurry to achieve high copper removal rate but minimal barrier material removal rate. Colloidal silica, with a narrow size distribution, minimizes micro scratch defects and provides superior removal rates on barrier materials, greater than about 1000 Å/min, and low removal rates for copper for the second slurry. Further, spherical silica abrasives with a mean size of less than about 100 nm provide very good planarization efficiency.




The pH, oxidizing agents, modifying agents, abrasive particle composition and size distribution, and weight percent were evaluated to establish a baseline for removal rates and selectivity.




EXAMPLE I




Precipitated silica mean particle sizes of 8 nm, 20 nm, and 70 nm were tested. The fumed silica particle size tested was less than 700 nm. The optimum CMP slurry, including the first and second slurry, had a precipitated silica mean size of less than about 100 nm. The optimum fumed silica abrasive mean size for the first slurry is less than about 700 nm. The optimum CMP slurry formulations contain 1-10% precipitated silica, or fumed silica for the first slurry.




Further, different types of abrasive particles were studied to maximize the removal and selectivity characteristic of the slurry. Precipitated silica abrasives, with mean size distributions of 4 nm, 8 nm, 13 nm, 20 nm and 70 nm were tested.

FIG. 6

shows a TEM picture of 13 nm slurry. The size distribution of these particles is presented in FIG.


7


. Fumed silica, with a mean particle size of less than about 700 nm, was also evaluated. All of these mean size distributions can be used to achieve effective polishing rates and selectivities for the first and second slurries.




EXAMPLE 2




Different pH ranges were tested for the first and second slurries (See Table 2 and 3). The precipitated silica abrasives had a starting pH range of 9-11 and the fumed silica had a starting pH range of 2-7. The optimum CMP slurry was found to be acidic. Thus, the pH ranges were altered to the 2 to 5 range by adding potassium, sodium or ammonium hydroxide in appropriate amounts to solutions of iodic acid, cleaning agent and corrosion inhibitor.




EXAMPLE 3




Several formulations of the first slurries were prepared. The characteristics of these formulations are described in Table 2. The first slurry is optimally comprised of formula 5, for colloidal silica particles, and formula 19 for fumed silica particles. Thus, the first slurry is preferentially comprised of 1-10% colloidal silica with particle size 3 to 100 nm, or 1-5% fumed silica with mean particle size of less than about 700 nm. Further, the active chemistry for the optimum first slurry is about 1-12% potassium iodate (KIO


3


, formed by reaction of HIO


3


with KOH), which is used as the oxidizing agent for the copper, about 0-5% concentrated inorganic acid as a copper activating agent, and 0-2% iminodiacetic acid (IDA) as the copper corrosion inhibitor and cleaning agent.












TABLE 2











Formulations for the First Slurry






















Oxidizer,




Copper




Copper




Neutralizer,




Abrasive,





Thermal




Copper




Tantalum




Tantalum






Formula




%




Inhibitor, %




Activator, %




%




%




pH




Oxide RR*




RR*




RR




Nitride RR









 1




HIO


3


,




IDA,




H


3


PO


4






KOH




Colloidal




2.4









3176

















8.22




1.5




 1.764




 4.523;




(13 nm),










NH4OH,




1










 3.7768






 2




HIO


3+


,




IDA,




H


3


PO


4






KOH,




Colloidal




2.7




113




4713

















12.33 




1.5




0.5




5.022




(13 nm)k











1






 3




HIO


3


,




IDA,









NH4OH,




Colloidal




3.0




126




4800

















10   




1.5





2.685




(13 nm),











1






 4




HIO


3


,




IDA,









KOH,




Colloidal




2.8




126




5165

















10   




1.5





4.084




(13 nm),











1






  5!




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




2.9




151




6530




453




590







10   




1.5




0.5




4.523




(13 nm),











1






 6




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.1




115




6877




422




528







12.33 




1.5




0.5




5.486




(13 nm),











1






 7




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.1




115




6877




422




528







12.33 




1.5




0.5




5.486




(13 nm),











1






 8




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.1




112




4797




494




730







8.22




1.5




0.5




3.978




(13 nm),











1






 9




HIO


3


,









HCl,




KOH,




Colloidal




6.0




117




423




878




1031







8.22





0.15 g




4.284




(13 nm),











1






10




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.4




134




2138




550




618







4.11




1.5




0.5




2.92 




(13 nm),











1






11




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.6




105




2134




512




882







4.11




1.5




0.5




2.92 




(13 nm),











1






12




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




6.0




106




1448




890




1047







6.17




1.5




0.5




4.087




(13 nm),






13




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.5




140




3900




720




1066







4.11




1.5




0.5




2.918




(13 nm),











1






14




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.6




 45




4157




527




623







4.11




1.5




0.5




3.012




 (8 nm),











1






15




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.7




172




6852




649




842







4.11




1.5




0.5




3.067




(20 nm),











1






16




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.6




171




2720




451




625







4.11




1.5




0.5




3.13 




(70 nm),











1






17




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




Colloidal




3.6




118




3973




832




1028







4.11




1.5




0.5




2.918




(13 nm),











1






18




HIO


3


,




IDA,









KOH,




Colloidal




3.5




167




5630




728




946







4.11




1.5





2.474




(13 nm),











1






 19!




HIO


3


,




IDA,




H


3


PO


4


,




KOH,




fumed, 1




3.6




 15




4823




2.4




−10







4.11




1.5




0.5




2.918











*“RR” means removal rates in Å/min.













Stock Solutions: HIO


3


(50% by weight); H


3


PO


4


(85.87% by weight); KOH (45-46% by weight) NH


4


OH(28-30% by weight); HNO


3


(68-70% by weight); HCI (36-38% by weight)




As can be seen from Table 2, all of the first slurry formulations of the present invention were effective in achieving acceptable copper removal rates, and semiconductor wafer surfaces of high quality. Thus, the first slurry is preferentially comprised of 1-10% colloidal silica with particle size of less than about 100 nm.




EXAMPLE 4




Several formulations of the second slurry were prepared. The characteristics of these formulations are described in Table 3. The second step slurry is dependent on the copper removal rate requirement and therefore is optimally comprised of either formula 6 or 9. The active chemistry for the optimum second slurry is 0.14 1% potassium iodate (KIO


3


, formed by reaction of HIO


3


with KOH) as the oxidizing agent for the copper, 0-5% concentrated inorganic acid and 0-2% iminodiacetic acid as the copper corrosion inhibitor and cleaning agent.












TABLE 3











Formulations for the Second Slurry






















Oxidizer,




Copper




Copper




Neutralizer,




Abrasive,





Thermal




Copper




Tantalum




Tantalum






Formula




%




Inhibitor, %




Activator, %




%




%




pH




Oxide RR*




RR*




RR




Nitride RR
























1




HIO


3


,




IDA,









KOH




Colloidal




3.4




101




430




462




2128







0.1




1.5





1.005




(13 nm),











1






2




HIO


3


,




IDA,




HNO


3


,




KOH




Colloidal




3.0




100




572




146




1749







0.1




1.5




10




13.66 




(13 nm),











1






3




HIO


3


,




IDA,




HNO


3


, 5;




KOH




Colloidal




3.0




 53




358




50.21




751







0.1




0.1




HCl, 5




13.14 




(13 nm),











1






4




HIO


3


,




IDA,




H


3


PO


4


,




KOH




Colloidal




2.7




116




574




772




1471







0.1




1.5




1.5




2.079




(13 nm),











1






5




HIO


3


,




IDA,




HNO


3


,




KOH




Colloidal




3.1




149




511




670




2087







0.1




1.5




2




3.674




(13 nm),











1






 6!




HIO


3


,




IDA,




HNO


3


,




NH4OH,




Colloidal




3.1




130




239




623




2146







0.1




1.5




2.31




2.507




(13 nm),











1






7




HIO


3


,




IDA,









KOH,




Colloidal




3.4




126




1053




657




1200







0.1




1.5





1.312




(13 nm),











1






8




HIO


3


,




IDA,









KOH,




Colloidal




3.5




200




0




>3000




217







0  




2  





1.305




(13nm),











1






9




HIO


3


,




IDA,









KOH,




Colloidal




3.5




120




1120




731




907







0.5




1.5





1.086




(13 nm),











1






10 




HIO


3


,




IDA,









KOH,




Colloidal




3.5




131




1208




901




856







1.5




1.5





1.443




(13 nm),











1











*“RR” means removal rates in Å/min.













Stock Solutions: HIO


3


(50% by weight); H


3


PO


4


(85-87% by weight); KOH (45-46% by weight); NH


4


OH(28-30% by weight); HNO


3


(68-70% by weight); HCI (36-38% by weight).




As can be seen from Table 3, all of the second slurry formulations of the present invention were effective in achieving acceptable barrier dielectric and copper removal rates, and semiconductor wafer surfaces of high quality.




The first and second slurries described herein, may also be used in a method of chemical mechanical polishing as described above. Also, while this invention has been disclosed and discussed primarily in terms of specific embodiments thereof, it is not intended to be limited thererto. Other modifications and embodiments will be apparent to the worker in the art.



Claims
  • 1. A chemical mechanical polishing slurry comprising:a first slurry, wherein said first slurry has a removal rate on copper of greater than 5000 Å/min and a removal rate on barrier material of less than 500 Å/min; and a second slurry having a pH in a range of from about 2-5, wherein said second slurry has a removal rate on said barrier material of greater than 1000 Å/min and a removal rate on copper of less than 1000 Å/min and a dielectric material removal <500 Å/min.
  • 2. The chemical mechanical polishing slurry of claim 1, wherein said first slurry comprises: from about:weight %1-12potassium iodate;0-2iminodiacetic acid; andsilica particles selected from the group consisting of:1-10colloidal silica; and1-10fumed silica;and said second slurry comprises about:weight %  1-10colloidal silica particles0.1-1.0potassium iodate  0-2iminodiacetic acid
  • 3. The chemical mechanical polishing slurry of claim 1, wherein said dielectric material is silicon oxide.
  • 4. The chemical mechanical polishing slurry of claim 1, wherein said barrier material is selected from the group consisting of: tungsten nitride, tantalum, tantalum nitride, silicon doped tantalum nitride, titanium nitride and silicon doped titanium nitride.
  • 5. The chemical mechanical polishing slurry of claim 1, wherein said barrier material is tantalum.
  • 6. The chemical mechanical polishing slurry of claim 1, wherein said barrier material is tantalum nitride or silicon doped tantalum nitride.
  • 7. The chemical mechanical polishing slurry of claim 2, wherein said first slurry is stable and has a pH in a range of about 2 to 5.
  • 8. The chemical mechanical polishing slurry of claim 2, wherein said first and second slurries further comprise an iodate oxidizer.
  • 9. The chemical mechanical polishing slurry of claim 2, wherein said first and second slurries further comprise a carboxylic acid corrosion inhibitor.
  • 10. The chemical mechanical polishing slurry of claim 9, wherein said carboxylic acid is selected from the group consisting of: glycine, oxalic acid, malonic acid, succinic acid and nitrilotriacetic acid.
  • 11. The chemical mechanical polishing slurry of claim 2, wherein said first and second slurries further comprise a dicarboxylic acid corrosion inhibitor.
  • 12. The chemical mechanical polishing slurry of claim 11, wherein said dicarboxylic acid has a nitrogen containing functional group.
  • 13. The chemical mechanical polishing slurry of claim 11 wherein said dicarboxylic acid is iminodiacetic acid.
  • 14. The chemical mechanical polishing slurry of claim 2, wherein said first and second slurries further comprise a carboxylic acid cleaning agent.
  • 15. The chemical mechanical polishing slurry of claim 14 wherein said carboxylic acid is selected from the group consisting of: glycine, oxalic acid, malonic acid, succinic acid or nitrilotriacetic acid.
  • 16. The chemical mechanical polishing slurry of claim 2 wherein said first and second slurries further comprise a dicarboxylic acid cleaning agent.
  • 17. The chemical mechanical polishing slurry of claim 16 wherein said dicarboxylic acid has a nitrogen containing functional group.
  • 18. The chemical mechanical polishing slurry of claim 16 wherein said dicarboxylic acid is iminodiacetic acid.
  • 19. The chemical mechanical polishing slurry of claim 1, wherein said first and second slurries contain precipitated silica particles.
  • 20. The chemical mechanical polishing slurry of claim 19, wherein said precipitated silica particles are about 3 to 100 nm in size.
  • 21. The chemical mechanical polishing slurry of claim 19 wherein said precipitated silica particles are spherical.
  • 22. The chemical mechanical polishing slurry of claim 20 wherein said precipitated silica particles are spherical.
  • 23. The chemical mechanical polishing slurry of claim 2 wherein said silica particles for said first slurry are fumed silica.
  • 24. The chemical mechanical polishing slurry of claim 23, wherein said fumed silica particles have a mean particle size of less than 700 mm.
  • 25. The chemical mechanical polishing slurry of claim 2 wherein said silica particles for the first slurry are colloidal silica particles.
  • 26. The chemical mechanical polishing slurry of claim 25 wherein said colloidal silica particles are about 3 to 100 nm in size.
  • 27. The chemical mechanical polishing slurry of claim 25 wherein said colloidal silica particles are spherical.
  • 28. The chemical mechanical polishing slurry of claim 26 wherein said colloidal silica particles are spherical.
  • 29. The chemical mechanical polishing slurry of claim 27 wherein id particles have a size distribution in a range of from about 3 nm to 100 nm.
  • 30. The chemical mechanical polishing slurry of claim 27 wherein about 99.9% of said particles are within about 3 sigma of a mean particle size with particles larger than 500 nm≦0.1%.
  • 31. The chemical mechanical polishing slurry of claim 1 wherein said first slurry comprises about 1-10% colloidal silica, about 1-12% potassium iodate, about 0-5% concentrated inorganic acid, and about 0-2% iminodiacetic acid.
  • 32. The chemical mechanical polishing slurry of claim 1 wherein said first slurry comprises about 1-5% fumed silica, about 1-12% potassium iodate, about 0-5% concentrated inorganic acid, and about 0-2% iminodiacetic acid.
  • 33. The chemical mechanical polishing slurry of claim 31 wherein said colloidal silica has a particle size of about 3 to 100 nm.
  • 34. The chemical mechanical polishing slurry of claim 32 wherein said fumed silica has a mean particle size of less than 700 nm.
  • 35. The chemical mechanical polishing slurry of claim 31 wherein said first slurry further comprises a pH modifier selected from the group consisting of potassium hydroxide and ammonium hydroxide in such amounts to modify the pH to a region of about 2 to 5.
  • 36. The chemical mechanical polishing slurry of claim 32 wherein said first slurry further comprises a pH modifier selected from the group consisting of potassium hydroxide and ammonium hydroxide in such amounts to modify the pH to a region of about 2 to 5.
  • 37. The chemical mechanical polishing slurry of claim 1 wherein said second slurry comprises about 1-10% colloidal silica, about 0.1-1% potassium iodate, and about 0-2% iminodiacetic acid and 0-5% concentrated inorganic acid.
  • 38. The chemical mechanical polishing slurry of claim 37 wherein said colloidal silica has a particle size of less than 100 nm.
  • 39. The chemical mechanical polishing slurry of claim 37 wherein said second slurry further comprises a pH modifier selected from the group consisting of potassium hydroxide and ammonium hydroxide in such amounts to modify the pH to a region of about 2 to 5.
  • 40. The chemical mechanical polishing slurry of claim 31 wherein said second slurry comprises about 1-10% colloidal silica, about 0.1-1% potassium iodate, and about 0-2% iminodiacetic acid and 0-5% concentrated inorganic acid.
  • 41. The chemical mechanical polishing slurry of claim 32 wherein said second slurry comprises about 1-10% colloidal silica, about 0.1-1% potassium iodate, and about 0-2% iminodiacetic acid and 0-5% concentrated inorganic acid.
  • 42. A chemical mechanical polishing slurry comprising:a first slurry, wherein said first slurry has a removal rate on copper that is between 2134 and 6877 Å/min and a removal rate on a tantalum barrier material that is between 2.4 and 832 Å/min; and a second slurry having a pH in a range of from about 2-5, wherein said second slurry has a removal rate on said tantalum barrier material that is between 50.21 and 3000 Å/min and a removal rate on copper that is between 0 and 1208 Å/min.
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Foreign Referenced Citations (1)
Number Date Country
8-223072 Feb 1998 JP