JP2007165592A - Conductive laminate, electromagnetic wave shielding film for plasma display, and protection board for plasma display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a conductive laminate whose transmission/reflection band is large and which is superior in conductivity (electromagnetic wave shielding property), visible light transmission property, and near-infrared shielding property; and to provide an electromagnetic shielding film for plasma display and a protection board. <P>SOLUTION: The conductive laminate 10 has a substrate 11 and a conductive film 12. In the conductive film 12, oxide layers 12a and metal layers 12b are alternately laminated from a substrate 11-side by (2n+1) layers in total. The oxide layer 12a is mainly composed of zinc oxide, niobium oxide and gallium oxide. A rate of niobium is 1 to 7 atom% and a rate of gallium is 0.01 to 0.5 atom% in the layer. The metal layer 12b is mainly composed of silver or silver alloy. The protection board for plasma display is provided with a support substrate, the conductive substrate 10 arranged on the support substrate, and an electrode which is electrically brought into contact with the conductive film 12 of the conductive laminate 10. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention is a plasma having an electromagnetic wave shielding ability which is installed on the observer side of a PDP to protect a conductive laminate and a plasma display panel (hereinafter referred to as PDP) body and shields electromagnetic noise generated from the PDP. The present invention relates to an electromagnetic wave shielding film for display and a protective plate for plasma display.

  The conductive laminate having transparency is used as a transparent electrode such as a liquid crystal display element, an automobile windshield, a heat mirror, an electromagnetic wave shielding window glass, and the like. For example, Patent Document 1 discloses a conductive laminate in which a total of (2n + 1) layers (n ≧ 2) are coated by alternately laminating transparent oxide layers and silver layers made of ZnO on a transparent substrate. Has been. The conductive laminate is said to have sufficient conductivity (electromagnetic wave shielding property) and visible light transmittance. However, in order to further improve the conductivity (electromagnetic wave shielding property) of the conductive laminate, when the number n of layers is increased and the number of silver layers is increased, there is a problem that the visible light transmittance is lowered.

In addition, the conductive laminate is also used as an electromagnetic wave shielding film for plasma display. Since electromagnetic waves are emitted from the front surface of the PDP, an electromagnetic wave shielding film in which a conductive film is formed on a substrate such as a plastic film is disposed on the observer side of the PDP for the purpose of shielding the electromagnetic waves. ing.
For example, Patent Document 2 describes a protective plate for a plasma display having a laminate in which oxide layers and metal layers are alternately laminated as a conductive film.

An electromagnetic wave shielding film is required to have a high transmittance and a low reflectance over the entire visible light region, that is, a wide transmission / reflection band, and a high shielding property in the near infrared region. In order to widen the transmission / reflection band, the number of stacked oxide layers and metal layers may be increased. However, when the number of laminated layers is increased, (i) the internal stress in the electromagnetic wave shielding film increases, the film curls, the conductive film breaks and the resistance value increases, and (ii) visible light transmittance. This causes a problem such as a decrease in the number of layers, and thus there is a limit to the number of stacked oxide layers and metal layers in the conductive film. Therefore, an electromagnetic wave shielding film that can widen the transmission / reflection band and is excellent in conductivity (electromagnetic wave shielding property) and visible light transmittance has not been known.
Japanese Patent Publication No. 8-32436 International Publication No. 98/13850 Pamphlet

  The present invention relates to a conductive laminate having a wide transmission / reflection band and excellent conductivity (electromagnetic wave shielding property), visible light transmission property, and near-infrared shielding property, an electromagnetic wave shielding film for plasma display, and a protective plate for plasma display The purpose is to provide.

The conductive laminate of the present invention is a conductive laminate having a substrate and a conductive film formed on the substrate, and the conductive film is alternately measured from the substrate side by an oxide layer and a metal layer. (2n + 1) layers [where n is an integer of 1 or more. ] A laminated multilayer structure in which the oxide layer is mainly composed of zinc oxide, niobium oxide and gallium oxide, and the ratio of niobium is 1 to 7 of the total (100 atomic%) of zinc, niobium and gallium. It is a layer in which the proportion of gallium is 0.01 to 0.5 atomic percent of the total of zinc, niobium and gallium (100 atomic percent), and the metal layer is mainly composed of silver or a silver alloy. It is characterized by being a layer.
The conductive film preferably has 2 to 8 metal layers.
The metal layer is preferably a layer made of pure silver or a layer made of a silver alloy containing at least one selected from gold, palladium and bismuth.

The electromagnetic wave shielding film for plasma display of the present invention is characterized by comprising the conductive laminate of the present invention.
The protective plate for plasma display of the present invention is in electrical contact with the support substrate, the electromagnetic wave shielding film for plasma display of the present invention provided on the support substrate, and the conductive film of the electromagnetic wave shielding film for plasma display. And an electrode.
The protective plate for plasma display of the present invention may further have a conductive mesh film.

The conductive laminate of the present invention has a wide transmission / reflection band, and is excellent in conductivity (electromagnetic wave shielding property), visible light transmittance, and near-infrared shielding property.
The electromagnetic wave shielding film for plasma display of the present invention has a wide transmission / reflection band, and is excellent in conductivity (electromagnetic wave shielding property), visible light transmittance, and near infrared shielding property.
The protective plate for plasma display of the present invention is excellent in electromagnetic wave shielding ability, has a wide transmission / reflection band, has high visible light transmittance, and has excellent near-infrared shielding properties.

<Conductive laminate>
FIG. 1 is a schematic cross-sectional view showing an example of the conductive laminate of the present invention. The conductive laminate 10 includes a base 11 and a conductive film 12 provided on the base.

(Substrate)
The substrate 11 is preferably a transparent substrate. “Transparent” in the present invention means that light having a wavelength in the visible light region is transmitted.
The material of the substrate 11 includes a glass plate (including tempered glass such as air-cooled tempered glass and chemically tempered glass); polyethylene terephthalate (PET), triacetyl cellulose (TAC), polycarbonate (PC), polymethyl methacrylate (PMMA). ) And the like.

(Conductive film)
In the conductive film 12, the oxide layer 12a and the metal layer 12b are alternately (2n + 1) layers [n is an integer of 1 or more] from the substrate 11 side. It is a laminated multilayer structure.
The conductive film 12 preferably has 2 to 8 metal layers 12b, more preferably 2 to 6 layers. If there are two or more metal layers 12b, the resistance value can be made sufficiently low. If the metal layer 12b is 8 layers or less, the increase in internal stress of the conductive laminate 10 can be further suppressed.
The resistance value of the conductive film 12 is preferably 3.5Ω or less, more preferably 2.5Ω or less, and particularly preferably 1.5Ω or less in order to sufficiently secure the electromagnetic wave shielding ability.

The oxide layer 12a is a layer mainly composed of zinc oxide, niobium oxide, and gallium oxide. The oxide layer 12a preferably contains 90% by mass or more in total of ZnO, Nb ₂ O ₅ and Ga ₂ O _{3 in} terms of oxide, more preferably 95% by mass or more, and 99% by mass. It is particularly preferable to contain the above.
In the oxide layer 12a, zinc (Zn), niobium (Nb), and gallium (Ga) are used as zinc oxide (ZnO), niobium oxide (Nb ₂ O ₅ ), and gallium oxide (Ga ₂ O ₃ ), or these It is considered that the composite oxide exists in a mixed form.

  The ratio of niobium is preferably 1 to 7 atomic% in the total of zinc, niobium and gallium (100 atomic%). Moreover, the ratio of gallium is preferably 0.01 to 0.5 atomic% in the total of zinc, niobium and gallium (100 atomic%). By setting it within this range, it is possible to maintain a wide transmission / reflection band and to obtain a conductive film with good moisture resistance.

  The oxide layer 12a may contain a metal other than zinc, niobium, and gallium as an oxide as long as the physical properties are not impaired. For example, an oxide such as indium, aluminum, magnesium, or tin may be included for the purpose of imparting conductivity.

  The physical film thickness (hereinafter simply referred to as the film thickness) of the oxide layer 12a closest to the substrate 11 and the oxide layer 12a farthest from the substrate 11 is preferably 20 to 60 nm, and particularly preferably 30 to 50 nm. The thickness of the other oxide layer 12a is preferably 40 to 120 nm, particularly preferably 40 to 100 nm. The “film thickness” in the present invention is a film thickness measured by a stylus type surface roughness measuring machine.

  The metal layer 12b is a layer mainly composed of silver or a silver alloy. The metal layer 12b preferably contains 95% by mass or more of silver in the metal layer 12b (100% by mass). Since the metal layer 12b is formed of silver or a silver alloy, the resistance value of the conductive film 12 can be lowered.

The metal layer 12b is preferably a layer made of pure silver from the viewpoint of reducing the resistance value of the conductive film 12. “Pure silver” in the present invention means that 99.9% by mass or more of silver is contained in the metal layer 12b (100% by mass).
The metal layer 12b is preferably a layer made of a silver alloy containing at least one other metal selected from gold, palladium, and bismuth from the viewpoint of suppressing the diffusion of silver and consequently increasing the moisture resistance. The total of other metals is preferably 0.2 to 1.5% by mass in the metal layer 12b (100% by mass) so that the specific resistance is 5.0 μΩcm or less.

  The total film thickness obtained by adding the film thicknesses of all the metal layers 12b is preferably 25 to 60 nm and preferably 25 to 50 nm, for example, when the target of the surface resistance of the obtained conductive laminate 10 is 1.5Ω / □. More preferably, when the target of the surface resistance is 0.9Ω / □, 35 to 80 nm is preferable and 35 to 70 nm is more preferable. As for the film thickness of each metal layer 12b, the total film thickness is appropriately distributed according to the number of metal layers 12b. As the number of metal layers 12b increases, the specific resistance of each metal layer 12b increases, so the total film thickness tends to increase to reduce the surface resistance.

  Examples of the method for forming the conductive film 12 (oxide layer 12a, metal layer 12b) on the substrate 11 include sputtering, vacuum deposition, ion plating, chemical vapor deposition, and the like. The sputtering method is preferable because the stability of characteristics is good. Examples of the sputtering method include a pulse sputtering method and an AC sputtering method.

The formation of the conductive film 12 by the sputtering method can be performed, for example, as follows.
(I) While introducing argon gas mixed with oxygen gas, pulse sputtering is performed using a target made of zinc oxide, niobium oxide and gallium oxide (hereinafter referred to as a mixed target), and an oxide layer is formed on the surface of the substrate 11. 12a is formed.
(Ii) While introducing argon gas, pulse sputtering is performed using a silver target or a silver alloy target to form the metal layer 12b on the surface of the oxide layer 12a.
The operations (i) and (ii) are repeated, and finally the oxide layer 12a is formed by the same method as in (i), thereby forming the conductive film 12 having a multilayer structure.

The mixed target can be produced by mixing high-purity (usually 99.9%) powders of each metal oxide and sintering by hot pressing, HIP (hot isostatic pressing), or normal pressure firing. . Since a target containing gallium oxide can be manufactured by a normal pressure firing method, the cost is lower than a target made only of zinc oxide and niobium oxide that must be manufactured by a hot press method.
The mixed target is preferably one having a porosity of 5.0% or less and a specific resistance of less than 1 Ωcm.

  In the conductive film 12, a protective film 12 d may be provided on the surface of the oxide layer 12 a farthest from the substrate 11. The protective film 12d is a layer that protects the oxide layer 12a and the metal layer 12b from moisture. Further, the oxide layer 12a farthest from the substrate 11 is coated with any resin film (moisture-proof film, anti-scattering film, anti-reflection film, protective film for shielding near infrared rays, functional film such as near infrared absorbing film). It is a layer that protects from an adhesive (particularly an alkaline adhesive) when adhering.

Examples of the protective film 12d include oxide films and nitride films of metals such as tin, indium, titanium, and silicon, and an indium-tin oxide (ITO) film is preferable.
2-30 nm is preferable and, as for the film thickness of 12 d of protective films, 3-20 nm is more preferable.

  In the conductive film 12, as shown in FIG. 2, a barrier layer 12c may be provided on the metal layer 12b. By providing the barrier layer 12c on the metal layer 12b, oxidation of the metal layer 12b can be prevented when the oxide layer 12a is formed in an oxygen atmosphere. Examples of the barrier layer 12c include those that can be formed in the absence of oxygen. Examples of the material include aluminum-doped zinc oxide (AZO) and tin-doped indium oxide (ITO).

  The conductive laminate of the present invention preferably has a luminous transmittance of 55% or more, more preferably 60% or more. The conductive laminate of the present invention preferably has a transmittance of 5% or less at a wavelength of 850 nm, particularly preferably 2% or less.

(Use)
The conductive laminate of the present invention is excellent in conductivity (electromagnetic wave shielding), visible light transmittance and near infrared shielding property, and when laminated on a support substrate such as glass, the transmission / reflection band becomes wide. It is useful as an electromagnetic wave shielding film for plasma display.
Moreover, the electroconductive laminated body of this invention can be used as transparent electrodes, such as a liquid crystal display element. The transparent electrode has good responsiveness because of low surface resistance, and good visibility because the reflectance is suppressed to the same level as glass.

Moreover, the electroconductive laminated body of this invention can be used as a motor vehicle windshield. The automotive windshield can exhibit antifogging or melting ice functions by energizing the conductive film, and since it has low resistance, the voltage required for energization can be reduced, and the reflectance can be suppressed to the same level as glass. The driver's visibility is not impaired.
Moreover, since the electroconductive laminated body of this invention has the very high reflectance in an infrared region, it can be used as a heat mirror provided in the window etc. of a building.
In addition, since the conductive laminate of the present invention has a high electromagnetic shielding effect, the electromagnetic waves radiated from the electric / electronic device are prevented from leaking outside, and the electromagnetic waves that affect the electric / electronic device enter the room from the outside. It can be used for an electromagnetic wave shielding window glass that prevents intrusion.

<Protective plate for plasma display>
Hereinafter, the example which used the electroconductive laminated body of this invention as an electromagnetic wave shielding film of the protection board for plasma displays (henceforth a protection board) is demonstrated.

(First embodiment)
FIG. 3 shows the protective plate of the first embodiment. The protective plate 1 includes a support base 20, a conductive laminate 10 provided on the support base 20, a colored ceramic layer 30 provided on a peripheral portion of the surface of the support base 20 on the conductive laminate 10 side, The scattering prevention film 40 bonded to the surface of the support base 20 opposite to the conductive laminate 10 side, the electrode 50 in electrical contact with the peripheral edge of the conductive film 12 of the conductive laminate 10, and conductive And a protective film 60 provided on the conductive laminate 10. An adhesive layer 70 is provided between the conductive laminate 10 and the support base 20, between the conductive laminate 10 and the protective film 60, and between the support base 20 and the scattering prevention film 40. The protection plate 1 is an example in which the conductive laminate 10 is provided on the PDP side of the support base 20.

The support base 20 is a transparent base having higher rigidity than the base 11 of the conductive laminate 10. By providing the support base 20, even if the material of the base 11 of the conductive laminate 10 is a plastic such as PET, no warp is generated due to a temperature difference between the PDP side and the observer side.
Examples of the material for the support base 20 include the same materials as those for the base 11 described above.

  The colored ceramic layer 30 is a layer for concealing the electrode 50 so as not to be directly visible from the viewer side. The colored ceramic layer 30 can be formed, for example, by printing on the support base 20 or pasting a colored tape.

The anti-scattering film 40 is a film for preventing the fragments of the supporting base 20 from scattering when the supporting base 20 is damaged. As the scattering prevention film 40, a known film can be used.
The anti-scattering film 40 may have an antireflection function. As a film having an anti-scattering function and an anti-reflection function, ARCTOP (trade name) manufactured by Asahi Glass Co., Ltd. may be mentioned. ARCTOP (trade name) is an anti-reflective treatment by forming a low-refractive index anti-reflective layer made of an amorphous fluoropolymer on one side of a polyurethane-based soft resin film having self-healing properties and anti-scattering properties. Is given. Moreover, the film etc. which formed the anti-reflective layer of a low refractive index on the film which consists of plastics, such as PET, by the wet type or the dry type are mentioned.

The electrode 50 is provided so as to be in electrical contact with the conductive film 12 so that the electromagnetic wave shielding effect of the conductive film 12 of the conductive laminate 10 is exhibited. The electrode 50 is preferably provided on the entire periphery of the conductive film 12 in order to ensure the electromagnetic shielding effect of the conductive film 12.
The material of the electrode 50 is superior in terms of electromagnetic wave shielding ability when the resistance is lower. The electrode 50 is formed, for example, by applying and baking a silver paste containing silver and glass frit, or a copper paste containing copper and glass frit.

  The protective film 60 is a film that protects the conductive film 12 of the conductive laminate 10. In the case where the conductive film 12 is protected from moisture, a moisture-proof film is provided. Examples of the moisture-proof film include plastic films such as PET and polyvinylidene chloride. Moreover, you may use the scattering prevention film mentioned above as the protective film 60. FIG.

  Examples of the pressure-sensitive adhesive for the pressure-sensitive adhesive layer 70 include commercially available pressure-sensitive adhesives, such as acrylic ester copolymer, polyvinyl chloride, epoxy resin, polyurethane, vinyl acetate copolymer, and styrene-acrylic copolymer. , Polyesters, polyamides, polyolefins, styrene-butadiene copolymer rubbers, butyl rubbers, silicone resins and the like, and an acrylic pressure-sensitive adhesive is particularly preferable because good moisture resistance can be obtained. The pressure-sensitive adhesive layer 70 may contain additives having various functions such as an ultraviolet absorber.

(Second Embodiment)
FIG. 4 shows a protective plate according to the second embodiment. The protective plate 2 includes a support base 20, a conductive laminate 10 provided on one side of the support base 20, an anti-scattering film 40 provided on the conductive laminate 10, and a conductive film of the conductive laminate 10. 12 is provided with an electrode 50 that is in electrical contact with the peripheral edge portion 12 and a colored ceramic layer 30 provided on the peripheral edge portion of the surface of the support base 20 opposite to the conductive laminate 10 side. Further, the scattering prevention film 40 is provided inside the electrode 50. The protection plate 2 is an example in which the conductive laminate 10 is provided on the observer side of the support base 20.
In the present embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as those in FIG.

(Third embodiment)
FIG. 5 shows a protective plate according to the third embodiment. The protective plate 3 includes the support base 20, the conductive laminate 10 bonded to the surface of the support base 20 via the pressure-sensitive adhesive layer 70, and the scattering bonded to the surface of the conductive laminate 10 via the pressure-sensitive adhesive layer 70. The prevention film 40 and the colored ceramic layer 30 provided on the peripheral edge of the surface of the support base 20 opposite to the conductive laminate 10, and the peripheral edge of the conductive mesh film 80 overlap the colored ceramic layer 30. The conductive mesh film 80 bonded to the surface of the support base 20 via the adhesive layer 70, the conductive film 12 of the conductive laminate 10, and the conductive mesh layer (not shown) of the conductive mesh film 80 are electrically connected. And an electrode 90 provided on the peripheral side portion of the protective plate 3 so as to be connected to. The protection plate 3 is an example in which the conductive laminate 10 is provided on the observer side of the support base 20 and the conductive mesh film 80 is provided on the PDP side of the support base 20.
Note that in the third embodiment, the same components as those in the first embodiment are denoted by the same reference numerals as in FIG. 3 and description thereof is omitted.

The conductive mesh film 80 is obtained by forming a conductive mesh layer made of copper on a transparent film. Usually, after manufacturing a copper foil on a transparent film, it manufactures by processing in a mesh form.
The copper foil may be either rolled copper or electrolytic copper, and a known one may be used as appropriate. The copper foil may be subjected to various surface treatments. Examples of the surface treatment include chromate treatment, roughening treatment, pickling, zinc / chromate treatment, and the like. 3-30 micrometers is preferable, as for the thickness of copper foil, 5-20 micrometers is more preferable, and 7-10 micrometers is especially preferable. By setting the thickness of the copper foil to 30 μm or less, the etching time can be shortened, and by setting the thickness to 3 μm or more, the electromagnetic wave shielding property is enhanced.

The opening ratio of the conductive mesh layer is preferably 60 to 95%, more preferably 65 to 90%, and particularly preferably 70 to 85%.
The shape of the opening of the conductive mesh layer is a regular triangle, a regular square, a regular hexagon, a circle, a rectangle, a rhombus, or the like. It is preferable that the openings have the same shape and are aligned in the plane.
The size of the opening is preferably 5 to 200 μm on a side or diameter, and more preferably 10 to 150 μm. By setting one side or diameter of the opening to 200 μm or less, the electromagnetic wave shielding property is improved, and by setting it to 5 μm or more, there is little influence on the image of the PDP.
The width of the metal part other than the opening is preferably 5 to 50 μm. That is, the arrangement pitch of the openings is preferably 10 to 250 μm. By making the width of the metal part 5 μm or more, processing becomes easy, and by making the width 50 μm or less, the influence on the image of the PDP is small.

  If the surface resistance of the conductive mesh layer is lowered more than necessary, the film becomes thick and adversely affects the optical performance and the like of the protective plate 3 such that the openings cannot be sufficiently secured. On the other hand, if the surface resistance of the conductive mesh layer is increased more than necessary, sufficient electromagnetic shielding properties cannot be obtained. Therefore, the sheet resistance of the conductive mesh layer is preferably 0.01 to 10Ω / □, more preferably 0.01 to 2Ω / □, and particularly preferably 0.05 to 1Ω / □.

The sheet resistance of the conductive mesh layer may be measured by a four-terminal method using an electrode that is 5 times or more larger than one side or diameter of the opening and an electrode interval of 5 times or more than the arrangement pitch of the openings. For example, if the openings are squares with a side of 100 μm and are regularly arranged via a metal part with a width of 20 μm, electrodes having a diameter of 1 mm may be arranged at intervals of 1 mm. Alternatively, the conductive mesh film is processed into a strip shape, electrodes are provided at both ends in the longitudinal direction, the resistance R is measured, and the length a in the longitudinal direction and the length b in the lateral direction are obtained from the following formula: May be.
Surface resistance = R × b / a

  When laminating a copper foil on a transparent film, a transparent adhesive is used. Examples of the adhesive include acrylic adhesives, epoxy adhesives, urethane adhesives, silicone adhesives, and polyester adhesives. The adhesive type is preferably a two-component type or a thermosetting type. Moreover, as an adhesive agent, what was excellent in chemical-resistance is preferable.

  As a method of processing the copper foil into a mesh shape, a photoresist method can be mentioned. In the printing method, the opening pattern is formed by screen printing. In the photoresist method, a photoresist material is formed on a copper foil by a roll coating method, a spin coating method, a full surface printing method, a transfer method, and the like, and an opening pattern is formed by exposure, development, and etching. As another method of forming the conductive mesh layer, a method of forming a pattern of openings by a printing method such as screen printing can be given.

  The electrode 90 electrically connects the conductive film 12 of the conductive laminate 10 and the conductive mesh layer of the conductive mesh film 80. Examples of the electrode 90 include a conductive tape. By electrically connecting the conductive film 12 of the conductive laminate 10 and the conductive mesh layer of the conductive mesh film 80, the overall sheet resistance value can be further reduced, thereby further improving the electromagnetic wave shielding effect. be able to.

  Since the protective plates 1 to 3 are arranged on the front surface of the PDP, the luminous transmittance is preferably 40% or more so as not to make it difficult to see the image of the PDP. Further, the luminous reflectance is preferably less than 6%, particularly preferably less than 3%. Further, the transmittance at a wavelength of 850 nm is preferably 5% or less, and particularly preferably 2% or less.

Note that the protective plate of the present invention is not limited to the first to third embodiments. For example, heat bonding may be performed without providing the pressure-sensitive adhesive layer 70.
In addition, the protective plate of the present invention may have an antireflection layer that is an antireflection film or a low refractive index thin film, if necessary. A known film can be used as the antireflection film, and a fluororesin film is preferred from the viewpoint of antireflection properties. As the antireflection layer, the reflectance of the protective plate is lowered, and a preferable reflected color is obtained. Therefore, the wavelength at which the reflectance is lowest in the visible light region is preferably 500 to 600 nm, and preferably 530 to 590 nm. Those are particularly preferred.

  Further, the protective plate may have a near infrared shielding function. As a method for providing a near-infrared shielding function, a method using a near-infrared shielding film, a method using a near-infrared absorbing substrate, a method using a pressure-sensitive adhesive added with a near-infrared absorbing agent during film lamination, an antireflection resin film, etc. Examples thereof include a method of adding an infrared absorber to have a near infrared absorption function, a method of using a conductive film having a near infrared reflection function, and the like.

In the conductive laminate 10 described above, the oxide layer 12a is mainly composed of zinc oxide, niobium oxide and gallium oxide, and the ratio of niobium is the total of zinc, niobium and gallium (100 atomic%). 1 to 7 atomic%, and the ratio of gallium is 0.01 to 0.5 atomic% of the total of zinc, niobium, and gallium (100 atomic%). Without this, the transmission / reflection bands of the protective plates 1 to 3 using the same can be widened. In addition, since the metal layer 12b is formed on the surface of the oxide layer 12a, the resistance of the metal layer 12b is reduced. As a result, even when the number of stacked conductive films 12 is reduced, conductivity (electromagnetic wave shielding) is achieved. Excellent. Further, since the transmission / reflection band can be widened and the conductivity is excellent without increasing the number of stacked conductive films 12, the number of stacked conductive films 12 can be reduced, and as a result, the visible light transmittance is also excellent.
Further, in the protective plates 1 to 3 described above, since the conductive laminate 10 having a wide transmission / reflection band and excellent in conductivity, visible light transmittance and near-infrared shielding properties is used, Excellent electromagnetic shielding properties, wide transmission and reflection bands, high visible light transmittance, and excellent near infrared shielding properties.

Example 1
The conductive laminated body shown in FIG. 2 was produced as follows.
First, dry cleaning with an ion beam was performed as follows for the purpose of cleaning the surface of a PET film having a thickness of 100 μm as the substrate 11.
About 30% by volume of oxygen gas was mixed with argon gas, 100 W electric power was applied, and the surface of the substrate 11 was irradiated with argon ions and oxygen ions ionized by an ion beam source.

(I) Using a mixed target [zinc oxide: niobium oxide: gallium oxide = 95: 4.9: 0.1 (mass ratio)] while introducing argon gas mixed with 15% by volume of oxygen gas, pressure 0 Pulse sputtering was performed under the conditions of .73 Pa, frequency 50 kHz, power density 3.7 W / cm ² , and inversion pulse width 2 μs, and an oxide layer 12 a (1) having a thickness of 35 nm was formed on the surface of the substrate 11.

(Ii) Using a silver alloy target doped with 1.0% by mass of gold while introducing argon gas, under the conditions of pressure 0.73 Pa, frequency 50 kHz, power density 2.5 W / cm ² , and inversion pulse width 10 μsec. Pulse sputtering was performed to form a metal layer 12b (1) having a thickness of 10 nm on the surface of the oxide layer 12a (1).

(Iii) While introducing argon gas, using an AZO target [zinc oxide: alumina = 95: 5 (mass ratio)], pressure 0.45 Pa, frequency 50 kHz, power density 2.5 W / cm ² , inversion pulse width 2 μm Pulse sputtering was performed under conditions of seconds to form a barrier layer 12c (1) having a thickness of 5 nm on the surface of the metal layer 12b (1).

In the same manner as (i), an oxide layer 12a (2) having a thickness of 65 nm was formed on the surface of the barrier layer 12c (1).
Similarly to (ii), a metal layer 12b (2) having a thickness of 14 nm was formed on the surface of the oxide layer 12a (2).
In the same manner as (iii), a barrier layer 12c (2) having a thickness of 5 nm was formed on the surface of the metal layer 12b (2).

In the same manner as (i), an oxide layer 12a (3) having a thickness of 65 nm was formed on the surface of the barrier layer 12c (2).
In the same manner as (ii), a metal layer 12b (3) having a thickness of 14 nm was formed on the surface of the oxide layer 12a (3).
In the same manner as (iii), a barrier layer 12c (3) having a thickness of 5 nm was formed on the surface of the metal layer 12b (3).

In the same manner as (i), an oxide layer 12a (4) having a thickness of 65 nm was formed on the surface of the barrier layer 12c (3).
In the same manner as (ii), a metal layer 12b (4) having a thickness of 10 nm was formed on the surface of the oxide layer 12a (4).
In the same manner as (iii), a barrier layer 12c (4) having a thickness of 5 nm was formed on the surface of the metal layer 12b (4).

An oxidation of 30 nm thick on the surface of the barrier layer 12c (4) was performed in the same manner as (i) except that argon gas mixed with 10% by volume of oxygen gas was used and the power density was changed to 4.5 W / cm ^2. The physical layer 12a (5) was formed.
While introducing an argon gas mixed with 5% by volume of oxygen gas, using an ITO target [indium oxide: tin oxide = 90: 10 (mass ratio)], pressure 0.35 Pa, frequency 100 kHz, power density 1.3 W / Pulse sputtering was performed under the conditions of cm ² and an inversion pulse width of 1 μs, and an ITO film having a thickness of 5 nm as a protective film 12d was formed on the surface of the oxide layer 12a (5).

In this manner, the oxide layers 12a made of zinc oxide, niobium oxide and gallium oxide and the metal layers 12b made of a silver alloy containing gold are alternately laminated on the base 11, and the barriers are formed on the metal layer 12b. A conductive laminate 10 provided with a layer 12c, having five oxide layers 12a and four metal layers 12b was obtained.
The oxide layer 12a contains 100% by mass of ZnO, Nb ₂ O ₅ and Ga ₂ O ₃ in total in terms of oxides and measured by ULVAC-PHI, ESCA 5500. In the oxide layer 12a, zinc and In the total of niobium and gallium (100 atomic%), zinc was 98.19 atomic%, niobium was 1.76 atomic%, and gallium was 0.05 atomic%.

About the electroconductive laminated body 10 of Example 1, the luminous transmittance (stimulus value Y prescribed | regulated in JISZ8701) measured by Tokyo Denshoku color analyzer TC1800 was 67.0%. Further, the transmittance at a wavelength of 850 nm was 0.97%. In addition, the wavelength band (bandwidth) of the transmittance of 40% or more was 282 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current resistance measuring device SRM12 manufactured by Nagy was 1.179 Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Example 2)
A conductive laminate 10 was obtained in the same manner as in Example 1 except that the mixed target [zinc oxide: niobium oxide: gallium oxide = 95: 4.5: 0.5 (mass ratio)] was used.
The oxide layer 12a contains 100% by mass of ZnO, Nb ₂ O ₅ and Ga ₂ O ₃ in total in terms of oxides and measured by ULVAC-PHI, ESCA 5500. In the oxide layer 12a, zinc and In the total of niobium and gallium (100 atomic%), zinc was 98.16 atomic%, niobium was 1.62 atomic%, and gallium was 0.22 atomic%.

With respect to the conductive laminate 10 of Example 2, the luminous transmittance (stimulus value Y defined in JIS Z 8701) measured by a color analyzer TC1800 manufactured by Tokyo Denshoku was 67.8%. Further, the transmittance at a wavelength of 850 nm was 0.68%. Further, the wavelength band (bandwidth) of the transmittance of 40% or more was 273 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 0.997Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Comparative Example 1)
A conductive laminate was obtained in the same manner as in Example 1 except that the mixed target [zinc oxide: niobium oxide = 95: 5 (mass ratio)] was used.
When measured by ESCA5500 manufactured by ULVAC-PHI, zinc was 98.20 atomic% and niobium was 1.80 atomic% in the total of zinc and niobium (100 atomic%) in the oxide layer.

About the electroconductive laminated body of the comparative example 1, the luminous transmittance (stimulus value Y prescribed | regulated in JISZ8701) measured by Tokyo Denshoku color analyzer TC1800 was 65.2%. Further, the transmittance at a wavelength of 850 nm was 0.32%. The wavelength band (bandwidth) of the transmittance of 40% or more was 255 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 0.982Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Comparative Example 2)
A conductive laminate was obtained in the same manner as in Example 1 except that the mixed target [zinc oxide: niobium oxide = 80: 20 (mass ratio)] was used.
When measured with ESCA 5500 manufactured by ULVAC-PHI, zinc was 92.00 atomic% and niobium was 8.00 atomic% in the total of zinc and niobium (100 atomic%) in the oxide layer.

About the electroconductive laminated body of the comparative example 2, the luminous transmittance (stimulus value Y prescribed | regulated in JISZ8701) measured by Tokyo Denshoku color analyzer TC1800 was 63.1%. Further, the transmittance at a wavelength of 850 nm was 0.31%. Further, the wavelength band (bandwidth) of the transmittance of 40% or more was 246 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 1.049Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Comparative Example 3)
A conductive laminate was obtained in the same manner as in Example 1 except that the mixed target [zinc oxide: niobium oxide: gallium oxide = 80: 19.9: 0.1 (mass ratio)] was used.
When measured by ESCA 5500 manufactured by ULVAC-PHI, in the oxide layer, zinc was 91.99 atomic%, niobium was 7.96 atomic%, and gallium was 0.8% in the total of zinc, niobium and gallium (100 atomic%). It was 05 atomic%.

About the electroconductive laminated body of the comparative example 3, the luminous transmittance (stimulus value Y prescribed | regulated in JISZ8701) measured by Tokyo Denshoku color analyzer TC1800 was 61.0%. Further, the transmittance at a wavelength of 850 nm was 0.20%. Further, the wavelength band (bandwidth) of the transmittance of 40% or more was 237 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 1.027Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Comparative Example 4)
A conductive laminate was obtained in the same manner as in Example 1 except that the mixed target was changed to an AZO target [zinc oxide: alumina = 95: 5 (mass ratio)].
With respect to the conductive laminate 10 of Comparative Example 4, the luminous transmittance (stimulus value Y defined in JIS Z 8701) measured with a color analyzer TC1800 manufactured by Tokyo Denshoku was 64.4%. Further, the transmittance at a wavelength of 850 nm was 0.34%. The wavelength band (bandwidth) of the transmittance of 40% or more was 250 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 0.996Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

(Comparative Example 5)
A conductive laminate was obtained in the same manner as in Example 1 except that the mixed target was changed to an ITO target [indium oxide: tin oxide = 90: 10 (mass ratio)].
With respect to the conductive laminate 10 of Comparative Example 5, the luminous transmittance (stimulus value Y specified in JIS Z 8701) measured by a color analyzer TC1800 manufactured by Tokyo Denshoku was 66.8%. Further, the transmittance at a wavelength of 850 nm was 0.71%. The wavelength band (bandwidth) of the transmittance of 40% or more was 270 nm.
Further, the sheet resistance (surface resistance) measured by an eddy current type resistance measuring device SRM12 manufactured by Nagy was 0.977Ω / □.
The transmission spectrum is shown in FIG. 6, and the evaluation results are shown in Table 1.

  The conductive laminate of the present invention is useful as an electromagnetic wave shielding film for plasma displays and a protective plate because of its excellent conductivity (electromagnetic wave shielding property), visible light permeability and near infrared ray shielding property, and a wide transmission / reflection band. is there. Moreover, the electroconductive laminated body of this invention can be used as transparent electrodes, such as a liquid crystal display element, a motor vehicle windshield glass, a heat mirror, and an electromagnetic wave shielding window glass.

It is a schematic sectional drawing which shows an example of the electroconductive laminated body of this invention. It is a schematic sectional drawing which shows the other example of the electroconductive laminated body of this invention. It is a schematic sectional drawing which shows 1st Embodiment of the protective plate for plasma displays of this invention. It is a schematic sectional drawing which shows 2nd Embodiment of the protection plate for plasma displays of this invention. It is a schematic sectional drawing which shows 3rd Embodiment of the protection plate for plasma displays of this invention. It is a graph which shows the transmission spectrum of the electroconductive laminated body of an Example.

Explanation of symbols

1 Protection plate (Plasma display protection plate)
2 Protection plate (Protection plate for plasma display)
3 Protection plate (Protection plate for plasma display)
DESCRIPTION OF SYMBOLS 10 Conductive laminated body 11 Base body 12 Conductive film 12a Oxide layer 12b Metal layer 20 Support base body 50 Electrode 80 Conductive mesh film

Claims (6)

A conductive laminate having a base and a conductive film formed on the base,
The conductive film has a total of (2n + 1) layers of oxide layers and metal layers alternately from the substrate side [where n is an integer of 1 or more. ] Is a laminated multilayer structure,
The oxide layer is mainly composed of zinc oxide, niobium oxide and gallium oxide, the ratio of niobium is 1 to 7 atomic% of the total of zinc, niobium and gallium (100 atomic%), and the ratio of gallium is zinc. And a layer that is 0.01 to 0.5 atomic percent of the total (100 atomic percent) of niobium and gallium,
The electroconductive laminated body whose metal layer is a layer which has silver or a silver alloy as a main component.   The conductive laminate according to claim 1, wherein the conductive film has 2 to 8 metal layers.   The conductive laminate according to claim 1 or 2, wherein the metal layer is a layer made of pure silver or a layer made of a silver alloy containing at least one selected from gold, palladium, and bismuth.   The electromagnetic wave shielding film for plasma displays which consists of an electroconductive laminated body in any one of Claims 1-3. A support substrate;
The electromagnetic wave shielding film for plasma display according to claim 4 provided on the support substrate,
A protective plate for plasma display, comprising: an electrode in electrical contact with the conductive film of the electromagnetic wave shielding film for plasma display. The protective plate for a plasma display according to claim 5, further comprising a conductive mesh film.

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