CN1397661A

CN1397661A - Sputtering target for high resistance transparent conductive membrane and mfg. method of high resistance transparent conductive membrane

Info

Publication number: CN1397661A
Application number: CN02124433A
Authority: CN
Inventors: 高桥诚一郎; 池田真; 渡边弘
Original assignee: Mitsui Mining and Smelting Co Ltd
Current assignee: Mitsui Mining and Smelting Co Ltd
Priority date: 2001-06-26
Filing date: 2002-06-26
Publication date: 2003-02-19
Anticipated expiration: 2022-06-26
Also published as: CN1320155C; KR100744017B1; KR20030076917A; JP2010031382A; TW570909B

Abstract

The present invention provided a sputtering target for a highly resistant transparent conductive film which can be basically used by a DC magnetron sputtering apparatus, and deposit a transparent and highly resistant film, and to provide a manufacturing method of the highly resistant transparent conductive film using the target. The indium oxide sputtering gate for the highly resistant transparent conductive film to deposit the highly resistant transparent conductive film with the resistivity of about 0.8-10 times 10<-3> Omega cm contains indium oxide and tin oxide as necessary, and also contains an insulating oxide.

Description

The high resistance nesa coating is with the manufacture method of sputtering target and high resistance nesa coating

Technical field

The present invention relates to be about 0.8～10 * 10 in making resistivity ^-3Employed high resistance nesa coating is with sputtering target (Sputtering targot) and use its to make the manufacture method of the high resistance nesa coating of high resistance nesa coating during the high resistance conductive film of Ω cm.

Background technology

Because Indium sesquioxide-stannic oxide (In ₂O ₃-SnO ₂Composite oxides, hereinafter referred to as ' ITO ') the visible light permeability height of film, and electroconductibility height is so prevent that as what nesa coating was widely used in liquid crystal indicator, glass frosting is with heating film and infrared reflection film etc.

For example, with regard to employed nesa coating in the flat pannel display (FPD), (resistivity is about 2 * 10 to select low resistance ^-4Ω cm) nesa coating.

On the other hand, on principle, be installed in that such FPD etc. goes up and the resistance-type button control panel nesa coating that uses, as requiring characteristic, the high-resistance nesa coating of needs.Yet there are the following problems at present: if use the ITO that is used to FPD, must be extremely thin film, can not guarantee the intensity of button control panel like this.

In addition,, just can not use, have the bigger problem of facility investment than the low-cost DC magnetic controlled tube sputtering apparatus of high frequency magnetron if the resistance of sputtering target self is become high resistance.

Summary of the invention

In view of such situation, the object of the present invention is to provide the manufacture method of a kind of high resistance nesa coating with sputtering target and high resistance nesa coating, can use the DC magnetic controlled tube sputtering apparatus basically, can be made into transparent and high-resistance film.

In order to achieve the above object, the 1st mode of the present invention is high resistance nesa coating sputtering target, is to be used to form resistivity to be about 0.8～10 * 10 ^-3The high resistance nesa coating Indium sesquioxide base sputtering target of the high resistance conductive film of Ω cm is characterized in that, contains Indium sesquioxide and stannic oxide as required, and contains the insulativity oxide compound.

In the 1st mode,, can not make the resistivity of target self produce big variation, and improve the resistivity of formed nesa coating by in the Indium sesquioxide base sputtering target, adding the insulativity oxide compound.

The 2nd mode of the present invention is high resistance nesa coating sputtering target, it is characterized in that, in the 1st mode, described insulativity oxide compound is be selected from silicon oxide, aluminum oxide, tantalum oxide, hafnia, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide, beryllium oxide, magnesium oxide, calcium oxide, strontium oxide, barium oxide, Scium trioxide, titanium oxide, zirconium white, vanadium oxide, boron oxide, gallium oxide, zinc oxide, chromic oxide, manganese oxide, ferric oxide, molybdenum oxide, phosphorus oxide and oxidation lanthanide at least a.

In the 2nd mode,, can not make the resistivity of target self produce big variation, and improve the resistivity of formed nesa coating by adding silicon oxide, aluminum oxide, tantalum oxide, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide etc.

The 3rd mode of the present invention is high resistance nesa coating sputtering target, it is characterized in that, in the 2nd mode, described insulativity oxide compound is a silicon oxide.

In the 3rd mode,, can not make the resistivity of target self produce big variation, and improve the resistivity of formed nesa coating by adding silicon oxide.

The 4th mode of the present invention is high resistance nesa coating sputtering target, it is characterized in that, in arbitrary mode of the 1st～3, with respect to 1 mole of indium, the element that constitutes described insulativity oxide compound is 0.00001～0.26 mole.

In the 4th mode,, can not make the resistivity of target self produce big variation, and improve the resistivity of formed nesa coating by adding the insulativity oxide compound of specified rate.

The 5th mode of the present invention is high resistance nesa coating sputtering target, it is characterized in that, in arbitrary mode of the 1st～4, with respect to 1 mole of indium, contains 0～0.3 mole of tin (Sn).

In the 5th mode, become the sputtering target that contains stannic oxide based on Indium sesquioxide, as required.

The 6th mode of the present invention is high resistance nesa coating sputtering target, it is characterized in that, in arbitrary mode of the 1st～5, can form resistivity by the DC magnetron sputtering is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

In the 6th mode, can be made into high-resistance nesa coating by the DC magnetron sputtering.

The 7th mode of the present invention is the manufacture method of high resistance nesa coating, it is characterized in that, use contains the Indium sesquioxide base sputtering target that Indium sesquioxide reaches stannic oxide as required and contains the insulativity oxide compound, and forming resistivity by the DC magnetron sputtering is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

In the 7th mode, by using the Indium sesquioxide base sputtering target that has been added with the insulativity oxide compound, can not make the resistivity of target self produce big variation, be 0.8～10 * 10 and form resistivity by the DC magnetron sputtering ^-3The nesa coating of Ω cm.

The 8th mode of the present invention is the manufacture method of high resistance nesa coating, it is characterized in that, in the 7th mode, described insulativity oxide compound is be selected from silicon oxide, aluminum oxide, tantalum oxide, hafnia, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide, beryllium oxide, magnesium oxide, calcium oxide, strontium oxide, barium oxide, Scium trioxide, titanium oxide, zirconium white, vanadium oxide, boron oxide, gallium oxide, zinc oxide, chromic oxide, manganese oxide, ferric oxide, molybdenum oxide, phosphorus oxide and oxidation lanthanide at least a.

In the 8th mode, by using the Indium sesquioxide base sputtering target that has been added with silicon oxide, aluminum oxide, tantalum oxide, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide etc., can not make the resistivity of target self produce big variation, be 0.8～10 * 10 and form resistivity by the DC magnetron sputtering ^-3The nesa coating of Ω cm.

The 9th mode of the present invention is the manufacture method of high resistance nesa coating, it is characterized in that, in the 8th mode, described insulativity oxide compound is a silicon oxide.

In the 9th mode, by using the Indium sesquioxide base sputtering target that has been added with silicon oxide, can not make the resistivity of target self produce big variation, be 0.8～10 * 10 and form resistivity by the DC magnetron sputtering ^-3The nesa coating of Ω cm.

The 10th mode of the present invention is the manufacture method of high resistance nesa coating, it is characterized in that, in arbitrary mode of the 7th～9, with respect to 1 mole of indium, the element that constitutes described insulativity oxide compound is 0.00001～0.26 mole.

In the 10th mode, by using the Indium sesquioxide base sputtering target of the insulativity oxide compound that has added specified rate, can not make the resistivity of target self produce big variation, be 0.8～10 * 10 and form resistivity by the DC magnetron sputtering ^-3The nesa coating of Ω cm.

The 11st mode of the present invention is the manufacture method of high resistance nesa coating, it is characterized in that, in arbitrary mode of the 7th～10, with respect to 1 mole of indium, contains 0～0.3 mole of tin (Sn).

In the 11st mode, can use with Indium sesquioxide as main body, contain the sputtering target of stannic oxide as required, forming resistivity by the DC magnetron sputtering is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

High resistance nesa coating sputtering target of the present invention is based on Indium sesquioxide, contains stannic oxide and contain the oxidate sintered body of insulativity oxide compound as required, each oxide compound can exist with the original form of oxide compound or composite oxides form or sosoloid form, is not particularly limited.

At this, with regard to the insulativity oxide compound, can list silicon oxide, aluminum oxide, tantalum oxide, hafnia, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide, beryllium oxide, magnesium oxide, calcium oxide, strontium oxide, barium oxide, Scium trioxide, titanium oxide, zirconium white, vanadium oxide, boron oxide, gallium oxide, zinc oxide, chromic oxide, manganese oxide, ferric oxide, molybdenum oxide, phosphorus oxide and oxidation lanthanide etc.

With regard to the insulativity oxide compound, preferably generate the energy insulativity oxide compound lower than Indium sesquioxide 0～1600 ℃ of scope internal standard.This is that chemical is more stable because compare with Indium sesquioxide, is difficult to decompose.

The amount of preferred insulativity oxide compound is in the following scope: with respect to 1 mole of indium, the element that constitutes this insulativity oxide compound is 0.00001～0.26 mole.Reason is, if lack than this scope, then the effect of Tian Jiaing is not remarkable, and, as if more than this scope, the too high in resistance of formed nesa coating then.

And tin (Sn) is 0～0.3 mole with respect to 1 mole of indium.Containing under the situation of tin, with respect to 1 mole of indium, the content of tin is 0.001～0.3 mole scope, is preferably 0.01～0.15 mole scope, more preferably 0.05～0.1 mole scope.If be in this scope, just can suitably control the density and the degree of excursion of the carrier electrons of sputtering target, guarantee that electroconductibility is in the good scope.And, add if exceed this scope, the degree of excursion of the carrier electrons of sputtering target is reduced, and electroconductibility is developed to the direction of deterioration, so inadvisable.

High resistance nesa coating of the present invention has the resistance value that can be carried out the degree of sputter by the DC magnetron sputtering with sputtering target, and can form resistivity is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

Certainly, using the high frequency magnetic controlled tube sputtering apparatus also can form resistivity is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

Below, the manufacture method of sputtering target of the present invention is described, this only is an example, manufacture method is not limited to this.

At first, constituting the initial feed of sputtering target of the present invention, generally is In ₂O ₃, SnO ₂, SiO ₂Powder.And, can be raw material also with these simple substance, compound, composite oxides etc.When using simple substance, compound, need in advance through becoming the operation of oxide compound.

For with desired fit rate with these raw material powder mix, the method for moulding do not do special qualification, can use existing known various damp process or drying process.

With regard to drying process, can list (Cold Press) method of colding pressing or hot pressing (Hot Press) method etc.In cold press process, powder mix is filled in the pressing mold, be made into formed body, fire under the atmospheric atmosphere gas or under the oxygen atmosphere gas, sintering.In pressure sintering, powder mix directly placed carry out sintering in the pressing mold.

With regard to damp process, for example, preferably use filtering shaping method (opening flat 11-286002 communique) with reference to the spy.This filtering type method of forming is, use is reduced pressure from the ceramic raw material slurry and is discharged moisture and obtain the filtering type pressing mold that is made of non-water soluble material of formed body, and the slurry formed by powder mix, ion exchanged water and organic additive of modulation, this slurry is injected the filtering type pressing mold, only discharge the moisture the slurry and make formed body from this side decompression of strainer, behind resulting ceramic molding drying defatted, fire.Above-mentioned filtering type pressing mold, be by have more than 1 the moulding that removes the water hole with counterdie, be disposed at this moulding and constitute with the strainer on the counterdie and the forming mould plate of seizing on both sides by the arms from above by the sealing member that is used to seal this strainer with water flowing, can assemble above-mentioned moulding counterdie, forming mould plate, sealing member and strainer respectively, only the moisture from this side decompression discharge slurry of this strainer with dismantling.

In the whole bag of tricks, firing temperature is preferably 1300～1600 ℃, more preferably 1300～1450 ℃.Then, implement to be used to process, be shaped to the mechanical workout of intended size, make target.

Description of drawings

Fig. 1 is the figure that concerns between the transmitance at the resistivity of oxygen partial pressure and wavelength 550nm of expression embodiment 1.

Fig. 2 is the figure that concerns between the transmitance at the resistivity of oxygen partial pressure and wavelength 550nm of expression comparative example 1.

Fig. 3 is the figure that concerns between the transmitance at the resistivity of oxygen partial pressure and wavelength 550nm of expression embodiment 2.

Embodiment

Below, by embodiment the present invention is described, but is not limited to this.

(embodiment 1)

Prepare the In of purity＞99.99% ₂O ₃Powder and SnO ₂The SiO of powder and purity＞99.9% ₂Powder.According to SnO ₂Be 10wt%, SiO ₂Be 5wt%, In ₂O ₃For ratio and the full dose of 85wt% is that 1.5Kg prepares this powder (for 1 mole of In, Si is equivalent to about 0.13 mole), adopt the filtering shaping method to obtain formed body.Then, under oxygen atmosphere gas, 1550 ℃ of conditions, this fired body is carried out 8 hours fire, sintering.Process this sintered compact, obtain relative density with respect to theoretical density and be 100% target.The body resistivity of this target is 2.4 * 10 ^-4Ω cm.

Use this target, under the following conditions, come film forming, obtain the film that thickness is 1200 by the DC magnetron sputtering.

Target size: φ=6in. τ=6mm

Sputter mode: DC magnetron sputtering

Gas barrier: rotor pump+cryopump

Arrive vacuum tightness: 4.0 * 10 ^-5[Torr]

Ar pressure: 3.0 * 10 ^-3[Torr]

Oxygen pressure: 1～10 * 10 ^-5[Torr]

Substrate temperature: 200 ℃

Sputtering power: 300W (power density 1.6W/cm ²)

Use substrate: Denpax (liquid-crystal display glass) t=1.8mm

By resistivity and the transmitance of analyzing this film, obtain Fig. 1 such at the relation between the transmitance of the resistivity of oxygen partial pressure and wavelength 550nm.

(comparative example 1)

Prepare the In of purity＞99.99% ₂O ₃Powder and SnO ₂Powder.According to SnO ₂Be 10wt%, In ₂O ₃For ratio and the full dose of 90wt% is that 1.5Kg prepares this powder, adopt the filtering shaping method to obtain formed body.Then, under oxygen atmosphere gas, 1550 ℃ of conditions, this fired body is carried out 8 hours fire, sintering.Process this sintered compact, obtain relative density with respect to theoretical density and be 99.6% target.The body resistivity of this target is 1.7 * 10 ^-4Ω cm.

Use this target, under the condition identical, come film forming, obtain the film that thickness is 2000 by the DC magnetron sputtering with embodiment 1.By resistivity and the transmitance of analyzing this film, obtain Fig. 2 such at the relation between the transmitance of the resistivity of oxygen partial pressure and wavelength 550nm.

(embodiment 2)

Prepare the In of purity＞99.99% ₂O ₃Powder and SnO ₂The SiO of powder and purity＞99.9% ₂Powder.According to SnO ₂Be 10wt%, SiO ₂Be 10wt%, In ₂O ₃For ratio and the full dose of 80wt% is that 1.5Kg prepares this powder (for 1 mole of In, Si is equivalent to about 0.26 mole), adopt the filtering shaping method to obtain formed body.Then, under oxygen atmosphere gas, 1550 ℃ of conditions, this fired body is carried out 8 hours fire, sintering.Process this sintered compact, obtain relative density with respect to theoretical density and be 100% target.The body resistivity of this target is 4.0 * 10 ^-4Ω cm.

Use this target, under the condition identical, come film forming, obtain the film that thickness is 1200 by the DC magnetron sputtering with embodiment 1.By resistivity and the transmitance of analyzing this film, obtain Fig. 3 such at the relation between the transmitance of the resistivity of oxygen partial pressure and wavelength 550nm.

(embodiment 3)

Prepare the In of purity＞99.99% ₂O ₃Powder and SnO ₂The SiO of powder and purity＞99.9% ₂Powder.According to SnO ₂Be 10wt%, SiO ₂Be 5wt%, In ₂O ₃For ratio and the full dose of 85wt% is that 1.5Kg prepares this powder (for 1 mole of In, Si is equivalent to about 0.13 mole), adopt the filtering shaping method to obtain formed body.Then, under oxygen atmosphere gas, 1450 ℃ of conditions, this fired body is carried out 8 hours fire, sintering.Process this sintered compact, obtain relative density with respect to theoretical density and be 100% target.The body resistivity of this target is 3.0 * 10 ^-4Ω cm.

Use this target, under the condition identical, come film forming, obtain the film that thickness is 1200 by the DC magnetron sputtering with embodiment 1.Analyze the resistivity and the transmitance of this film, demonstrate with Fig. 1 and be close to equal oxygen partial pressure characteristic.

By above result as can be seen, the body resistivity of embodiment 1～3 is 10 ^-4The Ω cm order of magnitude demonstrates with the existing ITO target shown in the comparative example 1 and is close to equal value, and the DC magnetron sputtering is fine.

And as can be known, compare with the oxygen partial pressure dependency of the existing ITO film shown in the comparative example 1, also having shown in the embodiment 1～3 is close to equal characteristic, can use the film of existing ITO film.

Compare with the resistivity in the preferred oxygen partial pressure of the existing ITO film shown in the comparative example 1, the resistivity of embodiment 1 becomes 10 times size, and, with regard to embodiment 2, become 100 times size.

In fact, be about 150 if the thickness will be applicable to commodity the time is set, in embodiment 1, sheet resistance is about 700 Ω.On the other hand, in embodiment 2, sheet resistance is about 7000 Ω.In addition, if thickness is set at 1500 , in embodiment 1, sheet resistance is about 70 Ω.On the other hand, in embodiment 2, sheet resistance is about 700 Ω.

In addition, we know, by increasing SnO ₂Addition, can generate current carrier, have the tendency that reduces resistance.Hence one can see that, not only SiO ₂, and by adjusting SnO ₂Addition also can the controlling resistance rate.

As known from the above, by control SnO ₂, SiO ₂Amount, can obtain best resistivity.

As described above, the present invention can provide a kind of resistivity that is used to form to be about 0.8～10 * 10 ^-3The high resistance nesa coating Indium sesquioxide base sputtering target of the nesa coating of Ω cm, promptly, contain Indium sesquioxide and stannic oxide as required and contain the high resistance nesa coating sputtering target of insulativity oxide compound, thus, can adopt basic DC magnetic controlled tube sputtering apparatus to make the high resistance nesa coating that can form transparent and high-resistance film.

Claims

1. a high resistance nesa coating sputtering target is to be used to form resistivity to be about 0.8～10 * 10 ^-3The high resistance nesa coating Indium sesquioxide base sputtering target of the high resistance conductive film of Ω cm is characterized in that:

Contain Indium sesquioxide and stannic oxide as required, and contain the insulativity oxide compound.

2. high resistance nesa coating sputtering target as claimed in claim 1 is characterized in that:

Described insulativity oxide compound is be selected from silicon oxide, aluminum oxide, tantalum oxide, hafnia, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide, beryllium oxide, magnesium oxide, calcium oxide, strontium oxide, barium oxide, Scium trioxide, titanium oxide, zirconium white, vanadium oxide, boron oxide, gallium oxide, zinc oxide, chromic oxide, manganese oxide, ferric oxide, molybdenum oxide, phosphorus oxide and oxidation lanthanide at least a.

3. high resistance nesa coating sputtering target as claimed in claim 2 is characterized in that: described insulativity oxide compound is a silicon oxide.

4. as any described high resistance nesa coating sputtering target in the claim 1～3, it is characterized in that: with respect to 1 mole of indium, the element that constitutes described insulativity oxide compound is 0.00001～0.26 mole.

5. as any described high resistance nesa coating sputtering target in the claim 1～4, it is characterized in that:, contain 0～0.3 mole of tin (Sn) with respect to 1 mole of indium.

6. as any described high resistance nesa coating sputtering target in the claim 1～5, it is characterized in that: forming resistivity by the DC magnetron sputtering is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

7. the manufacture method of a high resistance nesa coating is characterized in that: use the Indium sesquioxide base sputtering target that contains Indium sesquioxide and stannic oxide as required and contain the insulativity oxide compound, forming resistivity by the DC magnetron sputtering is 0.8～10 * 10 ^-3The nesa coating of Ω cm.

8. the manufacture method of high resistance nesa coating as claimed in claim 7 is characterized in that: described insulativity oxide compound is be selected from silicon oxide, aluminum oxide, tantalum oxide, hafnia, niobium oxides, yttrium oxide, cerium oxide, Praseodymium trioxide, beryllium oxide, magnesium oxide, calcium oxide, strontium oxide, barium oxide, Scium trioxide, titanium oxide, zirconium white, vanadium oxide, boron oxide, gallium oxide, zinc oxide, chromic oxide, manganese oxide, ferric oxide, molybdenum oxide, phosphorus oxide and oxidation lanthanide at least a.

9. the manufacture method of high resistance nesa coating as claimed in claim 8 is characterized in that: described insulativity oxide compound is a silicon oxide.

10. as the manufacture method of any described high resistance nesa coating in the claim 7～9, it is characterized in that: with respect to 1 mole of indium, the element that constitutes described insulativity oxide compound is 0.00001～0.26 mole.

11. the manufacture method as any described high resistance nesa coating in the claim 7～10 is characterized in that:, contain 0～0.3 mole of tin (Sn) with respect to 1 mole of indium.