Title of Invention	SUBSTRATE PROVIDED WITH A MULTILAYER HAVING THERMAL PROPERTIES
Abstract	The invention relates to a substrate (10), especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer (40) having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy containing silver, and two coatings (20, 60), said coatings being composed of a plurality of dielectric layers (24, 26; 64), so that the functional layer (40) is placed between the two coatings (20, 60), the functional layer (40) being deposited on a wetting layer (30) itself deposited directly onto a subjacent coating (20), characterized in that the subjacent coating (20) comprises at least one dielectric layer (24) based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer (26) made from a mixed oxide, said smoothing layer (26) being in contact with said superjacent wetting layer (30).

Title of Invention

SUBSTRATE PROVIDED WITH A MULTILAYER HAVING THERMAL PROPERTIES

Abstract

The invention relates to a substrate (10), especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer (40) having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy containing silver, and two coatings (20, 60), said coatings being composed of a plurality of dielectric layers (24, 26; 64), so that the functional layer (40) is placed between the two coatings (20, 60), the functional layer (40) being deposited on a wetting layer (30) itself deposited directly onto a subjacent coating (20), characterized in that the subjacent coating (20) comprises at least one dielectric layer (24) based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer (26) made from a mixed oxide, said smoothing layer (26) being in contact with said superjacent wetting layer (30).

Full Text	SUBSTRATE PROVIDED WITH A MULTILAYER HAVING THERMAL PROPERTIES The invention relates to transparent substrates, especially those made of rigid mineral material such as glass, said substrates being coated with a thin-film multilayer comprising a functional layer of metallic type which can act on solar radiation and/or infrared radiation of long wavelength. The invention relates more particularly to the use of such substrates for manufacturing thermal insulation and/or solar protection glazing. This glazing may be intended for equipping both buildings and vehicles, especially with a view to reducing air-conditioning load and/or preventing excessive overheating (glazing called "solar control" glazing) and/or reducing the amount of energy dissipated to the outside (glazing called "low-e" or "low-emissivity" glazing) brought about by the ever growing use of glazed surfaces in buildings and vehicle passenger compartments. This glazing may furthermore be integrated into glazing units having particular functionalities, such as, for example, heated windows or electrochromic glazing. One type of multilayer known for giving substrates such properties is composed of a metallic functional layer having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy containing silver. This metallic functional layer is deposited in a crystalline form on a wetting layer that is also crystalline and that promotes the suitable crystalline orientation of the metallic layer deposited on it. This functional layer is placed between two coatings made of dielectric material of the metal oxide or nitride type. The multilayer is generally obtained by a succession of deposition operation; carried out using a vacuum technique, such as sputtering, optionally magnetically enhanced or magnetron sputtering. One, or even two, very thin film(s), known as "blocking coatings", may also be provided, this or these being placed directly under, over or on each side of each silver-based metallic functional layer - the subjacent coating as a tie, nucleation and/or protection coating, for protection during a possible heat treatment subsequent to the deposition, and the superjacent coating as a "sacrificial" or protection coating so as to prevent the silver from being impaired if a layer that surmounts is deposited by sputtering in the presence of oxygen or nitrogen and/or if the multilayer undergoes a heat treatment subsequent to the deposition. Thus, the use of an amorphous layer based on a mixed zinc and tin oxide, which is directly in contact with the substrate, under a wetting layer based on zinc oxide is known from European patent application No. EP 803 481. It turns out that when such an amorphous layer is not deposited directly onto the substrate but is inserted between at least one subjacent dielectric layer and a wetting layer, it makes it possible to modify the interface between the dielectric layer and the wetting layer located above and thus to significantly improve the crystallization of the wetting layer and also the crystallization of the metallic functional layer. It has been found, surprisingly, that the integration of such an amorphous layer in the coating that is subjacent to the functional layer and provided with at least one nitride-based dielectric layer under this amorphous layer makes it possible to achieve a desired improvement in the crystallization of the functional layers and thus a desired improvement in the resistivity of the entire multilayer. The object of the invention is therefore tc remedy the drawbacks of the prior art, by developing a novel type of multilayer having layers of the type of those described above, which multilayer has an improved resistivity, lower than in a similar multilayer having equivalent unctional layer thickness and coatings. Said multilayer may or may not undergo one (or more) high-temperature heat treatment(s) of the bending, toughening or annealing type, but if it does undergo one (or more) such treatment(s), its optical quality and mechanical integrity will be preserved. Thus, the subject of the invention, in its broadest acceptance, is a substrate, especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy containing silver, and two coatings, said coatings being composed of a plurality of dielectric layers, so that the functional layer is placed between two coatings, the functional layer being deposited on a wetting layer itself deposited directly onto a subjacent coating, characterized in that the subjacent coating comprises at least one dielectric layer based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer made from a mixed oxide, said smoothing layer being in contact with said superjacent wetting layer. Thus, the invention consists in providing a noncrystalline smoothing layer under the wetting layer which is crystalline in order to allow suitable growth of the functional layer located on top of this wetting layer, which smoothing layer is in contact with the wetting layer directly or via an underblocking coating. It has appeared that in the case where the subjacent coating comprises at least one dielectric layer based on nitride, especially on silicon nitride and/or aluminum nitride, choosing a noncrystalline smoothing layer made from a mixed oxide made it possible to obtain good resistivity of the multilayer and optical properties suitable for the expectations whether or not the substrate undergoes a heat treatment after deposition. The invention thus applies to substrates known as "toughened or untoughened" substrates insofar as it is possible, on the same building facade for example, to place near each other glazing that integrate toughened substrates and untoughened substrates, without it being possible to distinguish them from one another by simple visual observation of the color in reflection and of the light reflection. Within the meaning of the present invention, when it is stated that a deposition of a layer or a coating (comprising one or more layers) is carried out directly under or directly on another deposit, it means that no other layer can be interposed between these two deposits. The smoothing layer is said to be "noncrystalline" in the sense that it can be completely amorphous or partially an orphous, and thus partially crystalline, but that it cannot be completely crystalline over its entire thickness. It may be of metallic nature as it is based on a mixed oxide (a mixed oxide is an oxide of at least two elements). The crystallographic appearance of the smoothing layer is inevitably different from that of the wetting layer since the smoothing layer is noncrystalline whereas the wetting layer is, for the most part, crystalline; they can therefore not be confused from this point of view. The advantage of such a smoothing layer is to make it possible to obtain an interface with the directly superjacent wetting layer that is not very rough. This low roughness can furthermore be seen with a transmission electron microscope. Furthermore, the wetting layer has a better texture and, in addition, has a preferential crystallographic orientation that is more pronounced. Each smoothing layer is thus made of a different material, differing both from a crystallographic and stoichiometric point of view, from that of the wetting layer under which it is directly placed. The nitride-based layer of the subjacent coating, which in addition comprises the smoothing layer, is in contact with the substrate, directly or indirectly via a contact layer, for example based on titanium oxide (TiOz). The index of this nitride-based layer is, preferably, less than 2.2. Preferably, the smoothing layer is a mixed oxide layer based on an oxide of one or more of the following metals: Sn, Si, Ti, Zr, Hf, Zn, Ga, In and more precisely a layer of a mixed oxide based on zinc and tin or a layer of a mixed indium tin oxide (ITO) deposited at low temperature. The index of the smoothing layer is, preferably, less than 2.2. Preferably, in addition, the smoothing layer is a mixed oxide layer having a nonstoichiometric amount of oxygen and even more particularly a substoichiometric mixed oxide layer based on zinc and tin, doped with antimony (SnZnOx:Sb, x being a number). Furthermore, the smoothing layer preferably has a geometric thickness between 0.1 and 30 nm and more preferably between 0.2 and 10 nm. In a preferred variant, at least one blocking coating is based on Ni or on Ti or is based on an Ni-based alloy, and especially is based on an NiCr alloy. In addition, the wetting layer subjacent to the functional layer is, preferably, based on zinc oxide; this wetting layer may be, in particular, based on aluminum-doped zinc oxide. The geometric thickness of the wetting layer is preferably between 2 and 30 nm and more preferably between 3 and 20 nm. The glazing according to the invention incorporates at least the substrate carrying the multilayer according to the invention, optionally combined with at least one other substrate. Each substrate may be clear or tinted. At least one of the substrates may especially be made of bulk-tinted glass. The choice of coloration type will depend on the level of light transmission and/or on the colorimetric appearance that is desired for the glazing once its manufacture has been completed. Thus, for glazing intended to equip vehicles, some standards dictate that windshields should have a light transmission TL of about 75%, while other standards impose a light transmission TL of about 65%; such a level of transmission is not required for the side windows or the sunroof for example. The tinted glass that can be used is for example that which, for a thickness of 4 mm, has a TL of 65% to 95%, an energy transmission TE of 40% to 80%, a dominant wavelength in transmission of 470 nm tc 525 nm, associated with a transmission purity of 0.4% to 6% under illuminant D65, which may "result" in the (L, a, b) colorimetry system, in a* and b* values in transmission of between -9 and 0 and between -8 and +2 respectively. For glazing intended to equip buildings, the glazing preferably has a light transmission TL of at least 75% or higher in the case of "low-emissivity" applications, and a light transmission TL of at least 40% or higher for "solar control" applications. The glazing according to the invention may have a laminated structure, especially one combining at least two rigid substrate of the glass type with at least one sheet of thermoplastic polymer, so as to have a structure of the type: glass/thin-film multilayer/sheet(s)/glass. The polymer may especially be based on polyvinyl butyral (PVB), ethylene/vinyl acetate (EVA), polyethylene terephthalate (PET) or polyvinyl chloride (PVC). The glazing may also have what is called an asymmetric laminated glazing structure, which combines a rigid substrate of the glass type with at least one sheet of polymer of the polyurethane :ype having energy-absorbing properties, optionally combined with another layer of polymers having "self-healing" properties. For further details about this type of glazing, the reader may refer especially to patents EP-0 132 198, EP-0 131 523, EP-0 389 354. The glazing may therefore have a structure of the type: glass/thin-film multilayer/polymer sheet(s). The glazing according to the invention is capable of undergoing a heat treatment without damaging the thin-film multilayer. The glazing is therefore possibly curved and/or toughened. The glazing may be curved and/or toughened when consisting of a single substrate, that provided with the multilayer. It is then referred to as "monolithic" glazing. When the glazing is curved, especially for the purpose of making windows for vehicles, the thin-film multilayer is preferably on an at least partly nonplanar face. The glazing may also be a multiple glazing unit, especially a double-glazing unit, at least the substrate carrying the multilayer being curved and/or toughened. It is preferable in a multiple glazing configuration for the multilayer to be placed so as to face the intermediate gas-filled space. In a laminated structure, the substrate carrying the multilayer is preferably in contact with the sheet of polymer. When the glazing is monolithic or is in the form of multiple glazing of the double-glazing or laminated glazing type, at least the substrate carrying the multilayer may be made of curved or toughened glass, it being possible for this substrate to be curved or toughened before or after the multilayer has been deposited. The invention also relates to a process for manufacturing substrates according to the invention, which consists in depositing the thin-film multilayer on its substrate by a vacuum technique of the sputtering, optionally magnetically enhanced sputtering, type and then in carrying out a heat treatment of the bending, toughening or annealing type on the coated substrate without degrading its optical and/or mechanical quality. However, it is not excluded for the first layer or first layers of the multilayer to be able to be deposited by another technique, for example by a thermal decomposition technique of the pyrolysis type. The details and advantageous features of the invention will become apparent from the following nonlimiting examples, illustrated by means of the attached figures: - Figure 1 illustrates the change, before heat treatment, in the sheet resistance of a multilayer having a single functional layer provided with a coating having a single overblocking layer, with and without a smoothing layer, as a function of the thickness of the dielectric layer placed underneath; - Figure 2 illustrates the change, after heat treatment, in the sheet resistance of the same multilayer having a single functional layer as in Figure 1, with and without a smoothing layer, as a function of the thickness of the dielectric layer placed underneath; - Figure 3 illustrates the change, before heat treatment, in the sheet resistance of a multilayer having a single functional layer provided with a coating having a single overblocking layer as a function of the thickness of the smoothing layer; - Figure 4 illustrates the change, after heat treatment, in the sheet resistance of the same multilayer having a single functional layer as in Figure 3, as a function of the thickness of the smoothing layer; - Figure 5 illustrates a multilayer having a single functional layer according to the invention, the functional layer being provided with an overblocking coating but not an underblocking coating; - Figure 6 illustrates a multilayer having a single functional layer according to the invention, the functional layer being provided with an underblocking coating but not with an overblocking coating; and - Figure 7 illustrates a multilayer having a single functional layer according to the invention, the functional layer being provided with an underblocking coating and with an overblocking coating. In the figures illustrating the multilayers, the thicknesses of the various materials have not been drawn strictly to scale in order to make them easier to understand. Furthermore, in all the examples below the thin-film multilayer is deposited on a substrate 10 made of soda-lime glass having a thickness of 2 mm. In each case where a heat treatment was applied to the substrate, this was an annealing treatment for around 5 minutes at a temperature of around 660' C followed by cooling in ambient air (around 20 oC). The objective of Figures 1 to 4 is to illustrate the importance of the presence of a smoothing layer in a multilayer of the type of that illustrated in Figure 5, which shows a multilayer according to the invention. An example, numbered 1, of a multilayer laving a single functional layer according to the invention is of the type: Substrate / Si3N4 / SnZnOx:Sb / ZnO / Ag / Ti / ZnO / Si3N4 Variable / Variable / 8 nm / 10 nm / 2 nm / 8 nm / 20 nm In Figures 1 and 2, the curves C1 and C11 illustrate the change in the sheet resistance (in ohms) of the multilayer as a function of the thickness of the dielectric layer based on silicon nitride (e Si3N4) in contact with the substrate, before (BHT) and after (AHT) heat treatment respectively, when the multilayer is not provided with a smoothing layer. The curves C2 and C12 illustrate the change in the sheet resistance (in ohms) of the multilayer as a function of the thickness of the dielectric layer based on silicon nitride (e Si3N4) in contact with the substrate, before and after heat treatment respectively, when the multilayer is provided with a smoothing layer made from SnZnOx:Sb having a thickness of 6 nm (x denotes a non-zero number). The curves C3 and C13 illustrate the change in the sheet resistance (in ohms) of the multilayer as a function of the thickness of the dielectric layer based on silicon nitride (e Si3N4) in contact with the substrate, before and after heat treatment respectively, when the multilayer is provided with a smoothing layer based on SnZnOx:Sb having a thickness of 20 nm. As can be seen in these Figures 1 and 2, for the same thickness of dielectric layer in contact with the substrate (for example 20 nm), the sheet resistance of the multilayer is always lower - therefore better - for curves C2, C3, C12 and C13 when the multilayer comprises a smoothing layer based on SnZnOx:Sb between the dielectric layer based on silcon nitride in contact with the substrate and the wetting layer based on zinc oxide ZnO subjacent to the functional layer based on silver Ag and the sheet resistance of the multilayer is always lower for a smoothing layer thickness of 20 nm (curves C3 and C13). It was verified that the smoothing layer made from a mixed oxide is amorphous throughout its thickness, whereas the wetting layer and the metallic functional layer are both crystalline, throughout their thickness. Consequently, the presence of the smoothing layer significantly improves the sheet resistance of the multilayer for comparable thickness of the subjacent dielectric layer, and this improvement is even greater when the thickness of the smoothing layer is large. In Figures 3 and 4, the curves illustrate the change in the sheet resistance (in ohms) of the multilayer as a function of the thickness of the smoothing layer based on zinc and tin oxide doped with antimony (e SnZnOx:Sb), before (BHT) and after (AHT) heat treatment respectively, when the multilayer is provided with a 20 nm layer based on silicon nitride Si3N4 between the substrate and the layer based on 5nZnOx:Sb. It was also verified that the smoothing layer made from a mixed oxide is amorphous throughout its thickness, whereas the wetting layer and the metallic functional layer are both crystalline, throughout their thickness. As can be seen in these Figures 3 and 4 also, the presence of the smoothing layer significantly improves the sheet resistance of the multilayer for a smoothing layer with a thickness between > 0 and 4 nm, and this improvement is even greater when the thickness of the smoothing layer is large. Similar observations may be made with a multilayer having a single functional layer provided with an underblocking coating and without an overblocking coating or provided with an underblocking coating and with an overblocking coating. Another series of tests was carried out. Three examples, numbered 2, 3 and 4, were produced based on the multilayer structure having a single functional layer illustrated in Figure 5, in which the functional layer 40 is provided with an overblocking coating 45. Table 1 below illustrates the thicknesses in nanometers of each of the layers: The resistivity, optical and energy characteristics of these examples are given in Table 2 below: Thus, the resistivity of the multilayer both before and after heat treatment of example 4 according to the invention is still lower than the counterexamples 3 and 2 respectively. Furthermore, the light reflection RL, the light transmission TL measured under illuminant D65 and the colors in reflection a* and b* in the LAB system measured under illuminant D65 on the side of the layers do not vary very significantly between the example according to the invention and the counterexamples 3 and 2. By comparing the optical and energy characteristics before heat treatment with these same characteristics after heat treatment, no major degradation was observed. Other tests were carried out based on the multilayer structure having a single functional layer illustrated in Figure 6, in which the functional layer 40 is provided with an overblocking coating 45 but not with an underblocking coating 35. Other tests were carried out based on the multilayer structure having a single functional layer illustrated in Figure 7, in which the functional layer 40 is provided with an underblocking coating 35 ana with an overblocking coating 45. All these tests led to similar observations. In addition, tests were conducted in order to measure the roughness of the layers. Table 3 below illustrates the roughness measured by X-ray reflectometry and expressed in nm (the roughness of the substrate being around 0.4): As can be seen in this table, the roughness of the layer based on silicon nitride Si3N4 deposited alone on the glass is hign, but the final roughness of a multilayer comprising a layer based on indium tin oxide SnlnOx (ITO) or a layer based on a mixed zinc tin oxide SnZnOx:Sb deposited on the layer based on silicon nitride is lower. The wetting layer based on a mixed oxide thus makes it possible to improve the roughness of the interface in contact with the wetting layer, by reducing this roughness. The present invention has been described above by way of example. It will be understood that a person skilled in the art is capable of producing various alternative forms of the invention without thereby departing from the scope of the patent as defined by the claims. CLAIMS 1. A substrate (10), especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer (40) having reflection properties in the infrared and/or in solar radiation, especially a metallic 5 functional layer based on silver or on a metal alloy containing silver, and two coatings (20, 60), said coatings being composed of a plurality of dielectric layers (24, 26; 64), so that the functional layer (40) is placed between the two coatings (20, 60), the functional layer (40) being deposited on a wetting layer (30) itself deposited respectively directly orto a subjacent coating (20), 10 characterized in that the subjacent coating (20) comprises at least one dielectric layer (24) based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer (26) made from a mixed oxide, said smoothing layer (26) being in contact with said superjacent wetting layer (30). 15 2. The substrate (10) as claimed in claim 1, characterized in that the smoothing layer (26) is a mixed oxide layer based on an oxide of one or more of the following metals: Sn, Si, Ti, Zr, Hf, Zn, Ga, In. 3. The substrate (10) as claimed in the preceding claim, characterized in that the smoothing layer (26) is a layer of a mixed oxide based on zinc and 20 tin, possibly doped, or a layer of a mixed indium tin oxide (ITO) deposited at low temperature. 4. The substrate (10) as claimed in any one of the preceding claims, characterized in that the smoothing layer (26) is an oxide layer having a nonstoichiometric amount of oxygen. 25 5. The substrate (10) as claimed in any one of the preceding claims, characterized in that the smoothing layer (26) has a geometric thickness between 0.1 and 30 nm and preferably between 0.2 and 10 nm. 6. The substrate (10) as claimed in any one of the preceding claims, characterized in that the functional layer (40) is placed directly onto at least one subjacent blocking coating (35) and/or directly under at least one superjacent blocking coating (45). 7. The substrate (10) as claimed in the preceding claim, characterized in that at least one blocking coating (35, 45) is based on Ni or on Ti or is based 5 on an Ni-based alloy, and especially is based on an NiCr alloy. 8. The substrate (10) as claimed in any one of the preceding claims, characterized in that the wetting layer (30) subjacent to the functional layer (40) is based on zinc oxide. 9. A glazing unit incorporating at least one substrate (10) as claimed 10 in any one of the preceding claims, optionally combined with at least one other substrate. 10. The glazing unit as claimed in the preceding claim, mounted in monolithic form or as multiple glazing of the double-glazing or laminated glazing type, characterized in that at least the substrate carrying the 15 multilayer is curved or toughened. 11. A process for manufacturing the substrate (10) as claimed in any one of claims 1 to 8, characterized in that the thin-film multilayer is deposited on the substrate by a vacuum technique of the sputtering, optionally magnetron sputtering, type and then in that a heat treatment of 20 the bending, toughening or annealing type is carried out on said substrate without degrading its optical and/or mechanical quality. The invention relates to a substrate (10), especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer (40) having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy containing silver, and two coatings (20, 60), said coatings being composed of a plurality of dielectric layers (24, 26; 64), so that the functional layer (40) is placed between the two coatings (20, 60), the functional layer (40) being deposited on a wetting layer (30) itself deposited directly onto a subjacent coating (20), characterized in that the subjacent coating (20) comprises at least one dielectric layer (24) based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer (26) made from a mixed oxide, said smoothing layer (26) being in contact with said superjacent wetting layer (30).

Full Text

SUBSTRATE PROVIDED WITH A MULTILAYER HAVING THERMAL PROPERTIES
The invention relates to transparent substrates, especially those made of
rigid mineral material such as glass, said substrates being coated with a
thin-film multilayer comprising a functional layer of metallic type which can
act on solar radiation and/or infrared radiation of long wavelength.
The invention relates more particularly to the use of such substrates for
manufacturing thermal insulation and/or solar protection glazing. This glazing
may be intended for equipping both buildings and vehicles, especially with a
view to reducing air-conditioning load and/or preventing excessive
overheating (glazing called "solar control" glazing) and/or reducing the
amount of energy dissipated to the outside (glazing called "low-e" or
"low-emissivity" glazing) brought about by the ever growing use of glazed
surfaces in buildings and vehicle passenger compartments.
This glazing may furthermore be integrated into glazing units having
particular functionalities, such as, for example, heated windows or
electrochromic glazing.
One type of multilayer known for giving substrates such properties is
composed of a metallic functional layer having reflection properties in the
infrared and/or in solar radiation, especially a metallic functional layer based
on silver or on a metal alloy containing silver.
This metallic functional layer is deposited in a crystalline form on a
wetting layer that is also crystalline and that promotes the suitable crystalline
orientation of the metallic layer deposited on it.
This functional layer is placed between two coatings made of dielectric
material of the metal oxide or nitride type. The multilayer is generally
obtained by a succession of deposition operation; carried out using a vacuum
technique, such as sputtering, optionally magnetically enhanced or magnetron
sputtering. One, or even two, very thin film(s), known as "blocking coatings",

may also be provided, this or these being placed directly under, over or on
each side of each silver-based metallic functional layer - the subjacent
coating as a tie, nucleation and/or protection coating, for protection during a
possible heat treatment subsequent to the deposition, and the superjacent
coating as a "sacrificial" or protection coating so as to prevent the silver from
being impaired if a layer that surmounts is deposited by sputtering in the
presence of oxygen or nitrogen and/or if the multilayer undergoes a heat
treatment subsequent to the deposition.
Thus, the use of an amorphous layer based on a mixed zinc and tin oxide,
which is directly in contact with the substrate, under a wetting layer based on
zinc oxide is known from European patent application No. EP 803 481.
It turns out that when such an amorphous layer is not deposited directly
onto the substrate but is inserted between at least one subjacent dielectric
layer and a wetting layer, it makes it possible to modify the interface
between the dielectric layer and the wetting layer located above and thus to
significantly improve the crystallization of the wetting layer and also the
crystallization of the metallic functional layer.
It has been found, surprisingly, that the integration of such an
amorphous layer in the coating that is subjacent to the functional layer and
provided with at least one nitride-based dielectric layer under this amorphous
layer makes it possible to achieve a desired improvement in the crystallization
of the functional layers and thus a desired improvement in the resistivity of
the entire multilayer.
The object of the invention is therefore tc remedy the drawbacks of the
prior art, by developing a novel type of multilayer having layers of the type of
those described above, which multilayer has an improved resistivity, lower
than in a similar multilayer having equivalent unctional layer thickness and
coatings. Said multilayer may or may not undergo one (or more)
high-temperature heat treatment(s) of the bending, toughening or annealing

type, but if it does undergo one (or more) such treatment(s), its optical
quality and mechanical integrity will be preserved.
Thus, the subject of the invention, in its broadest acceptance, is a
substrate, especially a transparent glass substrate, provided with a thin-film
multilayer comprising a functional layer having reflection properties in the
infrared and/or in solar radiation, especially a metallic functional layer based
on silver or on a metal alloy containing silver, and two coatings, said coatings
being composed of a plurality of dielectric layers, so that the functional layer
is placed between two coatings, the functional layer being deposited on a
wetting layer itself deposited directly onto a subjacent coating, characterized
in that the subjacent coating comprises at least one dielectric layer based on
nitride, especially on silicon nitride and/or aluminum nitride, and at least one
noncrystalline smoothing layer made from a mixed oxide, said smoothing layer
being in contact with said superjacent wetting layer.
Thus, the invention consists in providing a noncrystalline smoothing layer
under the wetting layer which is crystalline in order to allow suitable growth
of the functional layer located on top of this wetting layer, which smoothing
layer is in contact with the wetting layer directly or via an underblocking
coating.
It has appeared that in the case where the subjacent coating comprises
at least one dielectric layer based on nitride, especially on silicon nitride
and/or aluminum nitride, choosing a noncrystalline smoothing layer made
from a mixed oxide made it possible to obtain good resistivity of the
multilayer and optical properties suitable for the expectations whether or not
the substrate undergoes a heat treatment after deposition.
The invention thus applies to substrates known as "toughened or
untoughened" substrates insofar as it is possible, on the same building facade
for example, to place near each other glazing that integrate toughened
substrates and untoughened substrates, without it being possible to

distinguish them from one another by simple visual observation of the color in
reflection and of the light reflection.
Within the meaning of the present invention, when it is stated that a
deposition of a layer or a coating (comprising one or more layers) is carried
out directly under or directly on another deposit, it means that no other layer
can be interposed between these two deposits.
The smoothing layer is said to be "noncrystalline" in the sense that it can
be completely amorphous or partially an orphous, and thus partially
crystalline, but that it cannot be completely crystalline over its entire
thickness. It may be of metallic nature as it is based on a mixed oxide (a
mixed oxide is an oxide of at least two elements).
The crystallographic appearance of the smoothing layer is inevitably
different from that of the wetting layer since the smoothing layer is
noncrystalline whereas the wetting layer is, for the most part, crystalline;
they can therefore not be confused from this point of view.
The advantage of such a smoothing layer is to make it possible to obtain
an interface with the directly superjacent wetting layer that is not very
rough. This low roughness can furthermore be seen with a transmission
electron microscope.
Furthermore, the wetting layer has a better texture and, in addition, has
a preferential crystallographic orientation that is more pronounced.
Each smoothing layer is thus made of a different material, differing both
from a crystallographic and stoichiometric point of view, from that of the
wetting layer under which it is directly placed.
The nitride-based layer of the subjacent coating, which in addition
comprises the smoothing layer, is in contact with the substrate, directly or
indirectly via a contact layer, for example based on titanium oxide (TiOz).
The index of this nitride-based layer is, preferably, less than 2.2.
Preferably, the smoothing layer is a mixed oxide layer based on an oxide
of one or more of the following metals: Sn, Si, Ti, Zr, Hf, Zn, Ga, In and more

precisely a layer of a mixed oxide based on zinc and tin or a layer of a mixed
indium tin oxide (ITO) deposited at low temperature.
The index of the smoothing layer is, preferably, less than 2.2.
Preferably, in addition, the smoothing layer is a mixed oxide layer having
a nonstoichiometric amount of oxygen and even more particularly a
substoichiometric mixed oxide layer based on zinc and tin, doped with
antimony (SnZnOx:Sb, x being a number).
Furthermore, the smoothing layer preferably has a geometric thickness
between 0.1 and 30 nm and more preferably between 0.2 and 10 nm.
In a preferred variant, at least one blocking coating is based on Ni or on
Ti or is based on an Ni-based alloy, and especially is based on an NiCr alloy.
In addition, the wetting layer subjacent to the functional layer is,
preferably, based on zinc oxide; this wetting layer may be, in particular,
based on aluminum-doped zinc oxide.
The geometric thickness of the wetting layer is preferably between 2 and
30 nm and more preferably between 3 and 20 nm.
The glazing according to the invention incorporates at least the substrate
carrying the multilayer according to the invention, optionally combined with
at least one other substrate. Each substrate may be clear or tinted. At least
one of the substrates may especially be made of bulk-tinted glass. The choice
of coloration type will depend on the level of light transmission and/or on the
colorimetric appearance that is desired for the glazing once its manufacture
has been completed.
Thus, for glazing intended to equip vehicles, some standards dictate that
windshields should have a light transmission TL of about 75%, while other
standards impose a light transmission TL of about 65%; such a level of
transmission is not required for the side windows or the sunroof for example.
The tinted glass that can be used is for example that which, for a thickness of
4 mm, has a TL of 65% to 95%, an energy transmission TE of 40% to 80%, a
dominant wavelength in transmission of 470 nm tc 525 nm, associated with a

transmission purity of 0.4% to 6% under illuminant D65, which may "result" in
the (L, a*, b*) colorimetry system, in a* and b* values in transmission of
between -9 and 0 and between -8 and +2 respectively.
For glazing intended to equip buildings, the glazing preferably has a light
transmission TL of at least 75% or higher in the case of "low-emissivity"
applications, and a light transmission TL of at least 40% or higher for "solar
control" applications.
The glazing according to the invention may have a laminated structure,
especially one combining at least two rigid substrate of the glass type with at
least one sheet of thermoplastic polymer, so as to have a structure of the
type: glass/thin-film multilayer/sheet(s)/glass. The polymer may especially
be based on polyvinyl butyral (PVB), ethylene/vinyl acetate (EVA),
polyethylene terephthalate (PET) or polyvinyl chloride (PVC).
The glazing may also have what is called an asymmetric laminated
glazing structure, which combines a rigid substrate of the glass type with at
least one sheet of polymer of the polyurethane :ype having energy-absorbing
properties, optionally combined with another layer of polymers having
"self-healing" properties. For further details about this type of glazing, the
reader may refer especially to patents EP-0 132 198, EP-0 131 523, EP-0 389
354.
The glazing may therefore have a structure of the type: glass/thin-film
multilayer/polymer sheet(s).
The glazing according to the invention is capable of undergoing a heat
treatment without damaging the thin-film multilayer. The glazing is therefore
possibly curved and/or toughened.
The glazing may be curved and/or toughened when consisting of a single
substrate, that provided with the multilayer. It is then referred to as
"monolithic" glazing. When the glazing is curved, especially for the purpose of
making windows for vehicles, the thin-film multilayer is preferably on an at
least partly nonplanar face.

The glazing may also be a multiple glazing unit, especially a
double-glazing unit, at least the substrate carrying the multilayer being
curved and/or toughened. It is preferable in a multiple glazing configuration
for the multilayer to be placed so as to face the intermediate gas-filled space.
In a laminated structure, the substrate carrying the multilayer is preferably in
contact with the sheet of polymer.
When the glazing is monolithic or is in the form of multiple glazing of the
double-glazing or laminated glazing type, at least the substrate carrying the
multilayer may be made of curved or toughened glass, it being possible for
this substrate to be curved or toughened before or after the multilayer has
been deposited.
The invention also relates to a process for manufacturing substrates
according to the invention, which consists in depositing the thin-film
multilayer on its substrate by a vacuum technique of the sputtering,
optionally magnetically enhanced sputtering, type and then in carrying out a
heat treatment of the bending, toughening or annealing type on the coated
substrate without degrading its optical and/or mechanical quality.
However, it is not excluded for the first layer or first layers of the
multilayer to be able to be deposited by another technique, for example by a
thermal decomposition technique of the pyrolysis type.
The details and advantageous features of the invention will become
apparent from the following nonlimiting examples, illustrated by means of the
attached figures:
- Figure 1 illustrates the change, before heat treatment, in the sheet
resistance of a multilayer having a single functional layer provided
with a coating having a single overblocking layer, with and without a
smoothing layer, as a function of the thickness of the dielectric layer
placed underneath;
- Figure 2 illustrates the change, after heat treatment, in the sheet
resistance of the same multilayer having a single functional layer as

in Figure 1, with and without a smoothing layer, as a function of the
thickness of the dielectric layer placed underneath;
- Figure 3 illustrates the change, before heat treatment, in the sheet
resistance of a multilayer having a single functional layer provided
with a coating having a single overblocking layer as a function of the
thickness of the smoothing layer;
- Figure 4 illustrates the change, after heat treatment, in the sheet
resistance of the same multilayer having a single functional layer as
in Figure 3, as a function of the thickness of the smoothing layer;
- Figure 5 illustrates a multilayer having a single functional layer
according to the invention, the functional layer being provided with
an overblocking coating but not an underblocking coating;
- Figure 6 illustrates a multilayer having a single functional layer
according to the invention, the functional layer being provided with
an underblocking coating but not with an overblocking coating; and
- Figure 7 illustrates a multilayer having a single functional layer
according to the invention, the functional layer being provided with
an underblocking coating and with an overblocking coating.
In the figures illustrating the multilayers, the thicknesses of the various
materials have not been drawn strictly to scale in order to make them easier
to understand.
Furthermore, in all the examples below the thin-film multilayer is
deposited on a substrate 10 made of soda-lime glass having a thickness of
2 mm.
In each case where a heat treatment was applied to the substrate, this
was an annealing treatment for around 5 minutes at a temperature of around
660' C followed by cooling in ambient air (around 20 oC).

The objective of Figures 1 to 4 is to illustrate the importance of the
presence of a smoothing layer in a multilayer of the type of that illustrated in
Figure 5, which shows a multilayer according to the invention.
An example, numbered 1, of a multilayer laving a single functional layer
according to the invention is of the type:
Substrate / Si3N4 / SnZnOx:Sb / ZnO / Ag / Ti / ZnO / Si3N4
Variable / Variable / 8 nm / 10 nm / 2 nm / 8 nm / 20 nm
In Figures 1 and 2, the curves C1 and C11 illustrate the change in the
sheet resistance (in ohms) of the multilayer as a function of the thickness of
the dielectric layer based on silicon nitride (e Si3N4) in contact with the
substrate, before (BHT) and after (AHT) heat treatment respectively, when
the multilayer is not provided with a smoothing layer.
The curves C2 and C12 illustrate the change in the sheet resistance (in
ohms) of the multilayer as a function of the thickness of the dielectric layer
based on silicon nitride (e Si3N4) in contact with the substrate, before and
after heat treatment respectively, when the multilayer is provided with a
smoothing layer made from SnZnOx:Sb having a thickness of 6 nm (x denotes a
non-zero number).
The curves C3 and C13 illustrate the change in the sheet resistance (in
ohms) of the multilayer as a function of the thickness of the dielectric layer
based on silicon nitride (e Si3N4) in contact with the substrate, before and
after heat treatment respectively, when the multilayer is provided with a
smoothing layer based on SnZnOx:Sb having a thickness of 20 nm.
As can be seen in these Figures 1 and 2, for the same thickness of
dielectric layer in contact with the substrate (for example 20 nm), the sheet
resistance of the multilayer is always lower - therefore better - for curves C2,
C3, C12 and C13 when the multilayer comprises a smoothing layer based on
SnZnOx:Sb between the dielectric layer based on silcon nitride in contact with
the substrate and the wetting layer based on zinc oxide ZnO subjacent to the

functional layer based on silver Ag and the sheet resistance of the multilayer
is always lower for a smoothing layer thickness of 20 nm (curves C3 and C13).
It was verified that the smoothing layer made from a mixed oxide is
amorphous throughout its thickness, whereas the wetting layer and the
metallic functional layer are both crystalline, throughout their thickness.
Consequently, the presence of the smoothing layer significantly improves
the sheet resistance of the multilayer for comparable thickness of the
subjacent dielectric layer, and this improvement is even greater when the
thickness of the smoothing layer is large.
In Figures 3 and 4, the curves illustrate the change in the sheet
resistance (in ohms) of the multilayer as a function of the thickness of the
smoothing layer based on zinc and tin oxide doped with antimony (e
SnZnOx:Sb), before (BHT) and after (AHT) heat treatment respectively, when
the multilayer is provided with a 20 nm layer based on silicon nitride Si3N4
between the substrate and the layer based on 5nZnOx:Sb.
It was also verified that the smoothing layer made from a mixed oxide is
amorphous throughout its thickness, whereas the wetting layer and the
metallic functional layer are both crystalline, throughout their thickness.
As can be seen in these Figures 3 and 4 also, the presence of the
smoothing layer significantly improves the sheet resistance of the multilayer
for a smoothing layer with a thickness between > 0 and 4 nm, and this
improvement is even greater when the thickness of the smoothing layer is
large.
Similar observations may be made with a multilayer having a single
functional layer provided with an underblocking coating and without an
overblocking coating or provided with an underblocking coating and with an
overblocking coating.
Another series of tests was carried out.

Three examples, numbered 2, 3 and 4, were produced based on the
multilayer structure having a single functional layer illustrated in Figure 5, in
which the functional layer 40 is provided with an overblocking coating 45.
Table 1 below illustrates the thicknesses in nanometers of each of the
layers:

The resistivity, optical and energy characteristics of these examples are
given in Table 2 below:

Thus, the resistivity of the multilayer both before and after heat
treatment of example 4 according to the invention is still lower than the
counterexamples 3 and 2 respectively.

Furthermore, the light reflection RL, the light transmission TL measured
under illuminant D65 and the colors in reflection a* and b* in the LAB system
measured under illuminant D65 on the side of the layers do not vary very
significantly between the example according to the invention and the
counterexamples 3 and 2.
By comparing the optical and energy characteristics before heat
treatment with these same characteristics after heat treatment, no major
degradation was observed.
Other tests were carried out based on the multilayer structure having a
single functional layer illustrated in Figure 6, in which the functional layer 40
is provided with an overblocking coating 45 but not with an underblocking
coating 35.
Other tests were carried out based on the multilayer structure having a
single functional layer illustrated in Figure 7, in which the functional layer 40
is provided with an underblocking coating 35 ana with an overblocking coating
45.
All these tests led to similar observations.
In addition, tests were conducted in order to measure the roughness of
the layers.
Table 3 below illustrates the roughness measured by X-ray reflectometry
and expressed in nm (the roughness of the substrate being around 0.4):

As can be seen in this table, the roughness of the layer based on silicon
nitride Si3N4 deposited alone on the glass is hign, but the final roughness of a
multilayer comprising a layer based on indium tin oxide SnlnOx (ITO) or a layer
based on a mixed zinc tin oxide SnZnOx:Sb deposited on the layer based on
silicon nitride is lower. The wetting layer based on a mixed oxide thus makes
it possible to improve the roughness of the interface in contact with the
wetting layer, by reducing this roughness.
The present invention has been described above by way of example. It
will be understood that a person skilled in the art is capable of producing
various alternative forms of the invention without thereby departing from the
scope of the patent as defined by the claims.

CLAIMS
1. A substrate (10), especially a transparent glass substrate, provided
with a thin-film multilayer comprising a functional layer (40) having reflection
properties in the infrared and/or in solar radiation, especially a metallic
5 functional layer based on silver or on a metal alloy containing silver, and two
coatings (20, 60), said coatings being composed of a plurality of dielectric
layers (24, 26; 64), so that the functional layer (40) is placed between the two
coatings (20, 60), the functional layer (40) being deposited on a wetting layer
(30) itself deposited respectively directly orto a subjacent coating (20),
10 characterized in that the subjacent coating (20) comprises at least one
dielectric layer (24) based on nitride, especially on silicon nitride and/or
aluminum nitride, and at least one noncrystalline smoothing layer (26) made
from a mixed oxide, said smoothing layer (26) being in contact with said
superjacent wetting layer (30).
15 2. The substrate (10) as claimed in claim 1, characterized in that the
smoothing layer (26) is a mixed oxide layer based on an oxide of one or more
of the following metals: Sn, Si, Ti, Zr, Hf, Zn, Ga, In.
3. The substrate (10) as claimed in the preceding claim, characterized
in that the smoothing layer (26) is a layer of a mixed oxide based on zinc and
20 tin, possibly doped, or a layer of a mixed indium tin oxide (ITO) deposited at
low temperature.
4. The substrate (10) as claimed in any one of the preceding claims,
characterized in that the smoothing layer (26) is an oxide layer having a
nonstoichiometric amount of oxygen.
25 5. The substrate (10) as claimed in any one of the preceding claims,
characterized in that the smoothing layer (26) has a geometric thickness
between 0.1 and 30 nm and preferably between 0.2 and 10 nm.
6. The substrate (10) as claimed in any one of the preceding claims,
characterized in that the functional layer (40) is placed directly onto at least

one subjacent blocking coating (35) and/or directly under at least one
superjacent blocking coating (45).
7. The substrate (10) as claimed in the preceding claim, characterized
in that at least one blocking coating (35, 45) is based on Ni or on Ti or is based
5 on an Ni-based alloy, and especially is based on an NiCr alloy.
8. The substrate (10) as claimed in any one of the preceding claims,
characterized in that the wetting layer (30) subjacent to the functional layer
(40) is based on zinc oxide.
9. A glazing unit incorporating at least one substrate (10) as claimed
10 in any one of the preceding claims, optionally combined with at least one
other substrate.
10. The glazing unit as claimed in the preceding claim, mounted in
monolithic form or as multiple glazing of the double-glazing or laminated
glazing type, characterized in that at least the substrate carrying the
15 multilayer is curved or toughened.
11. A process for manufacturing the substrate (10) as claimed in any
one of claims 1 to 8, characterized in that the thin-film multilayer is
deposited on the substrate by a vacuum technique of the sputtering,
optionally magnetron sputtering, type and then in that a heat treatment of
20 the bending, toughening or annealing type is carried out on said substrate
without degrading its optical and/or mechanical quality.

The invention relates to a substrate (10), especially a transparent glass substrate, provided with a thin-film multilayer comprising a functional layer (40) having reflection properties in the infrared and/or in solar radiation, especially a metallic functional layer based on silver or on a metal alloy
containing silver, and two coatings (20, 60), said coatings being composed of a plurality of dielectric layers (24, 26; 64), so that the functional layer (40) is placed between the two coatings (20, 60), the functional layer (40) being deposited on a wetting layer (30) itself deposited directly onto a subjacent coating (20), characterized in that the subjacent coating (20) comprises at least one dielectric layer (24) based on nitride, especially on silicon nitride and/or aluminum nitride, and at least one noncrystalline smoothing layer (26)
made from a mixed oxide, said smoothing layer (26) being in contact with said superjacent wetting layer (30).

Documents:

3548-KOLNP-2008-(03-01-2013)-CORRESPONDENCE.pdf

3548-KOLNP-2008-(07-02-2014)-ABSTRACT.pdf

3548-KOLNP-2008-(07-02-2014)-CLAIMS.pdf

3548-KOLNP-2008-(07-02-2014)-CORRESPONDENCE.pdf

3548-KOLNP-2008-(07-02-2014)-DESCRIPTION (COMPLETE).pdf

3548-KOLNP-2008-(07-02-2014)-DRAWINGS.pdf

3548-KOLNP-2008-(07-02-2014)-OTHERS.pdf

3548-kolnp-2008-abstract.pdf

3548-kolnp-2008-claims.pdf

3548-kolnp-2008-CORRESPONDENCE 1.1.pdf

3548-kolnp-2008-correspondence.pdf

3548-kolnp-2008-description (complete).pdf

3548-kolnp-2008-drawings.pdf

3548-kolnp-2008-form 1.pdf

3548-kolnp-2008-form 2.pdf

3548-kolnp-2008-form 3.pdf

3548-kolnp-2008-form 5.pdf

3548-kolnp-2008-gpa.pdf

3548-kolnp-2008-international preliminary examination report.pdf

3548-kolnp-2008-international publication.pdf

3548-kolnp-2008-international search report.pdf

3548-kolnp-2008-others pct form.pdf

3548-kolnp-2008-OTHERS.pdf

3548-kolnp-2008-pct request form.pdf

3548-kolnp-2008-specification.pdf

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Patent Number

263878

Indian Patent Application Number

3548/KOLNP/2008

PG Journal Number

48/2014

Publication Date

28-Nov-2014

Grant Date

26-Nov-2014

Date of Filing

01-Sep-2008

Name of Patentee

SAINT-GOBAIN GLASS FRANCE

Applicant Address

18 AVENUE D'ALSACE F-92400 COURBEVOIE

Inventors:

#	Inventor's Name	Inventor's Address
1	REUTLER, PASCAL	22 RUE PERDONNET, 75010 PARIS
2	MATTMANN, ERIC	20 RUE OUDRY, 75013 PARIS
3	GILLET, PIERRE-ALAIN	AVENUE DE 1'ETE, 33, 1410 WATERLOO
4	PETITJEAN, ERIC	4 RUE DE ROMAINVILLE, 93260 LES LILAS

PCT International Classification Number

C03C 17/36

PCT International Application Number

PCT/FR2007/050882

PCT International Filing date

2007-03-06

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	0650771	2006-03-06	France