COATED LENS TO REDUCE VISUAL PERCEPTION OF STAINS
The present invention relates to optical articles bearing a coating which reduces the visual perception of stains.
The optical articles according to the present invention are preferably employed in the preparation of articles such as optical lenses, including spectacle lenses, including sunglass lenses, visors, shields, glass sheets, protective screens, and the like.
Sunglasses generally serve to attenuate transmitted light, but aside from the level of light transmittance, there are other features that distinguish different sunglass lenses, such as material, transmitted colour, scratch resistance, reduction of side glare, ultra-violet transmittance, cosmetic appearance etc. Coatings, e.g thin films, may be applied to enhance the performance of sunglass lenses. Such coatings include scratch resistant coatings, hydrophobic coatings for easier cleaning, anti-reflection coatings for reducing side glare or "mirror" (or "interference") coatings for producing fashionable lens colours. Mirror coatings may also have other benefits such as contrast enhancement or the reduction of transmitted ultra-violet or infra-red light.
Anti-reflection coatings known in the prior art enhance vision by reducing parasitic reflections that can disturb the wearer. They are generally deposited on both sides of transparent ophthalmic lenses and on the back (eye-side) surface of higher-quality sunglass lenses. For ophthalmic lenses, such coatings also increase the transmission of light through to the wearer and improve the visibility of his eyes to others.
Both mirror and anti-reflection coatings known in the art are multilayer structures that achieve their optical properties by means of thin film interference effects. When stained, e.g. by facial oils or fingerprints, the stain on the surface of the lens is highly visible, as it contrasts greatly with adjacent clean areas of the lens. Because of this high visibility, the lens is perceived to be difficult to clean and to keep clean.
The most common approach established in the prior art to make such lenses easier to clean is to coat the mirror or anti-reflection coating with an additional hydrophobic layer, which has a low surface energy and reduces the tendency for oily contaminants to attach to the coating. While this an improvement, oils nevertheless still can soil the coating, and when they do, they are highly visible. The hydrophobic layer also has little effect on staining by greasy or fatty contaminants.
Since it would not appear possible to completely eliminate soiling of the coating by oily or greasy contaminants, another approach might be to try to reduce the visibility of stains when they do occur. Such a proposal is made in United States Patent 4,070,097 (Gelber). Gelber describes an anti-reflection coating for ophthalmic lenses that is designed to reduce the visibility of stains such as fingerprints and facial oils. The patent is restricted to a two-layer, metal-dielectric anti-reflection coating so is of limited application.
Similarly, United States Patent 5,847,876 (Ferrante and Ott) describes an anti-reflection coating that is "fingerprint-resistant". The patent is restricted to two dielectric layers on glass substrates, so is again of limited application.
It would accordingly be a significant advance in the art if ophthalmic lenses could be provided with a coating or coatings of general applicability which could reduce the visibility of stains such as fingerprints and facial oils.
Accordingly, it is an object of the present invention to overcome, or at least alleviate, one or more of the difficulties or deficiencies related to the prior art.
Accordingly, in a first aspect of the present invention there is provided a coated optical lens including a lens element; and a stain masking coating on a surface of the lens element which coating
does not substantially vary in colour when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; is a multi-layer coating, the thickness and/or number of whose layers are selected to reduce the visibility of stains; and functions as an anti-reflective or reflective (mirror) coating.
In accordance with the present invention, one or more surfaces of an optical lens may be coated with the stain masking coating.
The lens element may be either optically clear or tinted (light absorbing), such as a sunglass lens, ophthalmic lens element, visor or the like. A sunglass lens is preferred.
By the term "ophthalmic lens element", as used herein, we mean all forms of individual refractive optical bodies employed in the ophthalmic arts, including, but not limited to, lenses, lens wafers and semi-finished lens blanks requiring further finishing to a particular patient's prescription.
Where the lens element is an ophthalmic lens element, the ophthalmic lenses may be formed from a variety of different lens materials, including glass and particularly from a number of different polymeric plastic resins. A common ophthalmic lens material is diethylene glycol bis (allyl carbonate) or CR39 (PPG Industries). Other examples of lens materials that may be suitable for use with the invention include other acrylics, other allylics, styrenics, polycarbonates, vinylics, polyesters and the like.
The stain masking coating is a multi-layer or interference coating. By "stain masking," we mean that the appearance of the coating is substantially similar either when it is clean or when it is stained by oily or greasy contaminants.
The visual appearance of the coated optical lens in reflected light can be quantified by measuring its reflectance spectrum in a spectrophotometer. This spectral information may be reduced to three colour coordinates - a "lightness"
corresponding primarily to the luminous intensity of the reflected light, and two chromatic attributes, the "hue" and "chroma" corresponding to the general colour (eg. red, blue, green etc.) and its vividness. ("The Measurement of Appearance", 2nd ed., R.S. Hunter and R.W. Harold, Wiley, New York, 1987). The term "colour" as used here refers to all three colour coordinates. Perceived variations in appearance may be quantified by calculating "CMC colour differences," as developed by the Colour Measurement Committee of the Society of Dyers and Colourists. A CMC colour variation of
is the limit of acceptability for textiles. Applicants have found that this is too stringent a tolerance for changes in appearance when anti-reflection or mirror coated lenses in the ophthalmic industry are stained. Applicants have observed that colour changes of up to 11 occurring when a mirror coated sunglass lens is stained are quite acceptable. Preferably the reflected colour shift (Δ E), when stained, is 8 or less, more preferably 6 or less.
It will be understood that optical interference coatings are designed to function in air, that is in a medium of refractive index equal to one. Accordingly, when stained, e.g. by body oils, and the like, the refractive index of which is approximately 1.3-1.6, there is normally a highly visible change in perceived colour. By calculating and minimising the colour difference ΔE between the clean and stained reflectance of a hypothetical coating, it is possible to specifically design the stain masking coating of this invention. Accordingly, the stain masking coating may be designed by selecting the number and/or thickness and/or materials of the layers in a multilayer coating utilising suitable computer software.
In a preferred form, the stain masking coating may function as a mirror coating for a sunglass lens. Such a coating may preferably be applied to the convex surface of the lens. In another form, the stain masking coating may function as an anti-reflective coating, applied to the concave surface of a sunglass lens or on both surfaces of an ordinary lens.
Accordingly, in one embodiment, wherein the stain masking coating functions as a reflective (mirror) coating; and includes
a plurality of layers of differing refractive index, wherein the thickness and/or number of the respective layers are selected to provide a desired reflectance; the reflectance not varying substantially in colour when stained.
The lower and higher refractive index layers may be formed from any suitable material. The lower and higher refractive index layers may be formed of a dielectric material. Preferably the dielectric layers may be formed from metal oxides, fluorides or nitrides and diamond-like carbon. Preferably the dielectric material is selected from one or more of Al203, BaTi03, Bi203, B203, Ce02, Cr203ι Ga203, Ge02, Fe203, Hf02, ln203, Indium-tin oxide, La203, MgO, Nd203, Nb205, Pr203, Sb203, Sc203, SiO, Si02, Sn02, Ta205, TiO, Ti02, Ti03, W03, Y203, Yb203, ZnO, Zr02, AIF3, BaF2, CaF2, CdF2, CeF3, HfF4, LaF3, LiF, MgF2, NaF, Na3AIF6, Na5AI3FI1 , NdF3, PbF2, PrF3, SrF2, ThF , ZrF4) Si3N4, AIN. Polymeric materials or dielectric materials including dopants of metal compounds or other materials may also be used.
In a particularly preferred form the lower refractive index layers include a silica (Si02) or magnesium fluoride (MgF2) material and the higher refractive index layers are formed from a combination of titanium dioxide (Ti02) and praseodymium oxide (Pr203).
Accordingly, in a preferred aspect there is provided a coated optical lens including a lens element; and a stain masking reflective (mirror) coating on a surface of the lens element which coating exhibits a reflected colour shift (ΔE) of 6 or less when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; and includes at least three layers of differing refractive index whose thickness is selected to provide a desired reflectance; the lower refractive index layers including a silica (Si02) or magnesium fluoride (MgF2) material;
the higher refractive index layers including titanium dioxide (Ti02) or a combination of titanium dioxide (Ti02) and praseodymium oxide (Pr203).
Preferably the stain masking coating includes a first adhesion layer.
More preferably the adhesion layer is a metallic, e.g. Chromium (Cr) layer.
In a preferred form, the stain masking coating may include a total of 4 to 6 alternating higher and lower index layers, preferably 4 to 6 alternating layers.
Alternatively the stain masking coating functions as a reflective (mirror) coating and includes a plurality of dielectric and metallic layers, wherein the thickness and/or number of the respective layers are selected to provide a desired reflectance; the reflectance not varying substantially in colour when stained.
Preferably the dielectric materials may be formed from metal oxides, fluorides or nitrides and diamond-like carbon. Preferably the dielectric material is selected from one or more of Al203, BaTi03, Bi203, B203, Ce02, Cr2θ3, Ga203, Ge02, Fe203, Hf02, ln203, Indium-tin oxide, La203, MgO, Nd203, Nb205, Pr203, Sb203, Sc203, SiO, Si02, Sn02, Ta205, TiO, Ti02, Ti03, W03l Y203, Yb203, ZnO, Zr02, AIF3, BaF2, CaF2. CdF2, CeF3, HfF4, LaF3, LiF, MgF2, NaF, Na3AIF6, Na5AI3FI14, NdF3, PbF2, PrF3, SrF2, ThF4, ZrF4, Si3N4, AIN. Preferably the metallic materials may be selected from the metals, metal oxides or nitrides of one or more of Aluminium (Al), Chromium (Cr), Niobium (Nb), Nickel (Ni), Palladium (Pd), Tin (Sn), Tantalum (Ta), Titanium (Ti), Tungsten (W) or Zirconium (Zr).
A silica (Si02) or magnesium fluoride (MgF2) material is preferred for the dielectric layers.
Chromium (Cr) or Niobium (Nb) is preferred for the light absorbing metallic layers.
Accordingly, in a particularly preferred embodiment there is provided a coated optical lens including a lens element; and a stain masking reflective (mirror) coating on a surface of the lens element which coating exhibits a reflected colour shift (ΔE) of 6 or less when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; and includes at least three dielectric and metallic layers; wherein the dielectric layers are formed of a dielectric material and include a silica (Si02) or magnesium fluoride (MgF2) material; and the metallic materials include Chromium (Cr) or Niobium (Nb).
In an alternative aspect of the present invention, the stain masking coating functions as an anti-reflective coating and includes three or more layers of differing refractive index, wherein the thickness and/or number of the respective layers are selected to provide a desired reflectance; the reflectance not varying substantially in colour when stained
Preferably the lower and higher refractive index layers are formed of a dielectric material selected from one or more of Al203, BaTi03, Bi203, B2O3, Ce02, Cr203, Ga203, Ge02, Fe203, Hf02, ln203, Indium-tin oxide, La203, MgO, Nd203, Nb205, Pr203, Sb203, Sc203, SiO, Si02, Sn02, Ta205, TiO, Ti02, Ti203, Ti305, W03, Y203, Yb203, ZnO, Zr02, AIF3, BaF2, CaF2, CdF2, CeF3> HfF4, LaF3, LiF, MgF2, NaF, Na3AIF6, Na5AI3FI14, NdF3, PbF2l PrF3, SrF2, ThF4, ZrF4, Si3N4, AIN, or diamond-like carbon. Polymeric materials or dielectric materials including dopants of metal compounds or other materials may also be used.
More preferably the lower refractive index layers include a silica (Si02) or magnesium fluoride (MgF2) material; and the higher refractive index layers are formed from titanium dioxide (Ti02) or a combination of titanium dioxide (Ti02) and praseodymium oxide (Pr203).
Accordingly, in a particularly preferred embodiment, there is provided a coated optical lens including a lens element; and a stain masking, anti-reflective coating on a surface of the lens element which coating exhibits a reflected colour shift (ΔE) of 6 or less when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; and includes at least three layers of differing refractive index whose thickness is selected to provide a desired reflectance; the lower refractive index layers including a silica (Si02) or magnesium fluoride (MgF2) material; the higher refractive index layers including titanium dioxide (Ti02) or a combination of titanium dioxide (Ti02) and praseodymium oxide (Pr2θ3).
In an alternative embodiment of this aspect of the present invention, the stain masking coating functions as an anti-reflective coating and includes three or more dielectric and metallic layers, wherein the thickness and/or number of the respective layers are selected to provide a desired reflectance; the reflectance not varying substantially in colour when stained.
Preferably, the dielectric layer(s) is formed from a dielectric material selected from one or more of Al203, BaTi03, Bi203, B203, Ce02, Cr203, Ga203, Ge02, Fe203, Hf02| ln203, Indium-tin oxide, La203, MgO, Nd203, Nb205, Pr203, Sb203, Sc203, SiO, Si02, Sn02, Ta205, TiO, Ti0 , Ti03, W03, Y203, Yb203, ZnO, Zr02, AIF3, BaF2, CaF2, CdF2, CeF3, HfF4, LaF3, LiF, MgF2, NaF, Na3AIF6, Na5AI3FI14, NdF3, PbF2, PrF3ι SrF2, ThF , ZrF4, S.3N4, AIN, or diamond-like carbon; and the metallic layer(s) is formed from a metallic material selected from the metals, metal oxides or metal nitrides of one or more of Aluminium (Al), Chromium (Cr), Niobium (Nb), Nickel (Ni), Palladium (Pd), Tin (Sn), Tantalum (Ta), Titanium (Ti), Tungsten (W) or Zirconium (Zr).
More preferably, the dielectric layer(s) include a silica (Si02) or magnesium fluoride (MgF2) material; and the metallic material(s) is Niobium (Nb) or Chromium
(Cr).
Accordingly, in a particularly preferred embodiment, there is provided a coated optical lens including a lens element; and a stain masking, anti-reflective coating on a surface of the lens element which coating exhibits a reflected colour shift (Δ E) of 6 or less when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; and includes at least three layers of differing refractive index whose thickness is selected to provide a desired reflectance; wherein the dielectric layers are formed of a dielectric material and include a silica (Si02) or magnesium fluoride (MgF2) material; and the metallic materials include Chromium (Cr) or Niobium (Nb).
The optical lens may further include one or more additional coatings.
Accordingly in a further aspect of the present invention there is provided a multi-coated optical lens including a lens element; and a coating on surface of the lens element that does not substantially vary in colour when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6; and a secondary coating which provides a desirable optical and/or mechanical property to the optical article.
The secondary coating may underlay the stain masking coating or be applied to a second surface of the lens element.
The secondary coating may be of any suitable type. The secondary coating may be one or more of an anti-reflective, abrasion resistant, or impact-resistant hydrophobic and adhesion coatings. An abrasion-resistant coating is preferred.
The combination of an abrasion resistant coating and an anti-reflective coating is particularly preferred.
In a preferred embodiment of this aspect of the present invention, where the stain masking coating is a reflective coating, the secondary coating is an anti- reflective coating applied to the opposite surface of the lens element.
In a further preferred embodiment, the stain masking coating functions as a reflective (mirror) coating or anti-reflective coating as described above.
In a further preferred aspect, one or both surfaces of the optical article may be subjected to a surface treatment to improve bondability and/or compatibility of the stain masking and/or secondary coating. The surface treatment may be selected from one or more of the group consisting of plasma discharge, corona discharge, glow discharge, ionising radiation, UV radiation, flame treatment and laser, preferably excimer laser treatment. A plasma discharge treatment is preferred.
The surface treatment, alternatively or in addition, may include incorporating another adhesion layer, for example a layer including a metal or metal compound selected from the group consisting of one or more of Chromium, Nickel, Tin, Palladium, Silicon, and/or oxides thereof.
In a further aspect of the present invention, there is provided a method for preparing a coated optical lens, which method includes providing a lens element; a metallic material or a higher refractive index material; and a lower refractive index material; depositing overlapping layers of lower refractive index material and higher refractive index material or metallic material on a surface of the optical lens element, the number and/or thickness of the respective layers being selected to produce a stain masking coating which coating does not substantially vary in colour when stained by contaminants having a refractive index in the range of approximately 1.3 to 1.6;
O 00/31569 .. .. PCT/AU99/01025
is a multi-layer coating, the thickness and/or number of which are selected to reduce the visibility of stains; and functions as an anti-reflective or reflective (mirror) coating.
In a preferred aspect the high and low refractive index materials, preferably Ti02 or Pr2θ3/Ti02 and Si02, are deposited as alternating layers.
Alternatively the metallic material and low refractive index materials are deposited as alternating layers. More preferably, the metallic material is Niobium (Nb) or Chromium (Cr).
The deposition step may be a vacuum deposition step. The deposition step may be conducted in a coating apparatus. A box coater or sputter coater may be used.
Further characteristics and advantages of the present invention will be apparent from the following description of drawings and examples of embodiments of the present invention, given as indicative but not restrictive.
In the figures:
Figure 1 illustrates a known anti-reflective coating on the surface of a lens when contaminated by an oil droplet.
Figure 2 illustrates a similar view to Figure 1 where the oil is able to wet the coating surface.
Figure 3 illustrates the measured reflectance spectra of a hard resin lens coated on both sides with a stain-masking coating according to the present invention.
Figure 4 illustrates the measured reflectance spectra of a hard resin lens coated on both sides with a typical prior art anti-reflection coating.
Figure 5 illustrates the measured reflectance spectra of a hard resin lens
coated on one side with a stain-masking blue mirror coating according to the present invention.
Figure 6 illustrates the measured reflectance spectra of a hard resin lens coated on one side with a typical, prior art blue mirror coating.
EXAMPLE 1
Figure 1 illustrates a typical known anti-reflective coating on the surface of a standard optical lens. For light incident from air onto a clean portion of the lens, the luminous reflectance (i.e. that visible to the human eye) is designed to be as low as possible (typically 0.5%). Only the front surface of the lens is shown - the other surface of the lens would normally be coated identically.
When the coating is stained by a liquid contaminant such as finger oil, the liquid either wets the surface of the lens or "beads up," depending on the contaminant and how it interacts with the surface of the coating. Commercial anti- reflective ophthalmic lenses may be treated with a "hydrophobic" surface layer, which has very low surface energy and is not easily wet by any liquid. It causes oily contaminants to bead on the surface of the lens, and they are easily removed by wiping, due to the low attraction of the liquid to the hydrophobic surface. This is the situation illustrated in Figure 1. However, if the contaminant is not a liquid, the hydrophobic coating is less effective in reducing soiling.
When the contaminant is able to soil the coating, either because the contaminant is a liquid able to spread on the surface or because it is a fatty solid, the situation is illustrated in Figure 2. The soiled area of the coating has two components of reflection - a first reflection from the surface of the contaminant and a second reflection from the coating underneath the contaminant. Typically the layer of contamination on the surface of the coating will be at least of the order of several microns in thickness. Since this thickness is much greater than the wavelengths of visible light, the two reflections do not interfere coherently.
The top reflection then is spectrally white, with an intensity given by
p
Hair/contaminant = (ncontaminant " 1 ) '( ^contaminant ■
Since ncontaminant ~ 1 -3 for oily contaminants, the top reflection is of the order of 2%, as shown in the figure. This reflection is unavoidable and cannot be eliminated by interference effects. The second reflection Rcontaminant/coating, from the coating underneath the oily or greasy contaminant, has an intensity determined by the way the coating behaves when light is incident from a medium of refractive index ncontaminant ~ 1 -3. The reflection is determined by the way sub-reflections from the multiple layers of the coating interfere. According to the present invention, the intensity of the second reflection may be minimised and made close to zero. Therefore, the minimal reflectance from the soiled coating is 2 + 0 = 2%, which is still less than that from the uncoated substrate (4% if nSUbstrate = 1.5).
Furthermore, the coating may be designed according to the present invention so that there is no perceptible change in colour of the coating whether it is clean or stained. In this case, the stain is not easily seen on the lens. However, a compromise must be reached between designing the coating to best mask stains (which necessarily implies a reflectance of 2% when clean or soiled), and designing the coating to be as anti-reflective as possible when clean (which corresponds to a reflectance of 0%).
Table 1 illustrates the optical design for a stain-masking anti-reflection coating according to the present invention. Figure 3 illustrates the measured reflectance spectra of a hard resin lens coated on both sides with the coating, both when the coating is clean and when one surface of the coated lens is stained by a liquid of refractive index n=1.34. Clearly the reflectance is barely changed when the coating is soiled, and consequently stains are difficult to see on the lens. The reflectance of the uncoated substrate is also shown in the figure, demonstrating that the coating is indeed anti-reflective.
TABLE 1
Optical design for a stain-resistant anti-reflection coating
For comparison, Figure 4 shows the reflectance spectrum of a known commercial anti-reflection coating, both when clean and when stained on one side by a liquid of refractive index n=1.34. While the coating is more anti-reflective than the stain-masking coating of Figure 3 when clean, stains affect the reflectance of the coating in a far more significant manner. It will be appreciated that on this optical lens, oily or greasy contaminants will be far more visible.
EXAMPLE 2
The first example of the invention is a multi-layer coating that achieves a satisfactory compromise between anti-reflectivity and stain minimisation and the corresponding coated article.
For mirror coated lenses, (as opposed to anti-reflection coated lenses) the same analysis for the optical effect of oily or greasy stains applies, but in desiring to minimise the visibility of stains, there is no longer the additional constraint of wishing to minimise the intensity of reflections. The coating may be designed to reflect with the same colour whether clean or stained so that stains are less visible.
Table 2 illustrates the optical design for a stain-masking, blue mirror coating
according to the present invention. Figure 5 illustrates the measured reflectance spectra of a hard resin lens coated on one side with the coating, both when the coating is clean and when stained by a liquid of refractive index n=1.34. The reflectance is only slightly changed when the coating is soiled, and particularly near 550 nm where the human eye is most sensitive, the reflectance is almost unchanged when the coating is soiled. Consequently stains are difficult to see on the lens, as indeed is observed.
TABLE 2
Optical design for a stain-resistant, blue mirror coating
For comparison, Table 3 is the design for a prior art blue mirror coating that is identical to the previous coating (to the naked eye) when clean, but not having been specially designed for stain-masking performance, shows a more substantially modified reflectance spectrum when stained by a liquid of refractive index n=1.34, as indicated in Figure 6. It will be appreciated that on this lens, greasy contaminants are more visible than for the previous example.
TABLE 3
Optical design for a prior art, blue mirror coating
EXAMPLE 3
The stain masking mirror coating is not limited in colour to blue. With appropriate coating design software, it is possible to specifically design stain masking mirror coatings of a wide variety of hues and lightnesses. Table 4 summarises the coating designs and measured colours of both stain masking and non-stain masking mirror coatings that have been variously produced on tinted CR39, glass and polycarbonate lenses by the Applicants. The thicknesses of the Siθ2, Ti02 and Ti02/Pr2θ3 layers are indicated in nanometres. The colour coordinates are as measured for clean coatings and the ΔE is the colour shift when the coatings are stained by a liquid contaminant of refractive index n=1.466. The illuminant is the CIE llluminant C. Also indicated are the stained colour shifts expected from calculations, from which it can be seen that the design calculations give a good indication of the performance likely to be achieved in real coatings.
TABLE 4 Stain masking and non-stain masking mirror coatings
Amber Pink Blue Orange
Stain Normal Stain Normal Stain Normal Stain Normal mask mask mask mask
Lens
Cr 0.5 0.5 0.5 0.5 0.5 0.5 0.5 0.5
TiO2/Pr203 95 42 165.5 94.7
TiO2 31.6 60.1 117 98
SiO2 16 155 207 34.1 43.1 27.9 58 74
TiO2/Pr2O3 180.8 40.7 156.2
TiO2 47.5 178.5 110 97
SiO2 94.6 58.7 152.2 170 111.6 10.5 52
Lightness L* 36 39 33 38 39 32 36 38
Chroma C* 20 21 51 60 40 54 36 40
Hue h* 63 71 307 317 275 293 34 45
Stained ΔE 8 17 4 15 6 30 6 26
(Measured)
Stained ΔE 5 18 1 12 5 10 3 25
(Calculated)
Figure 7 illustrates the colour changes seen when the mirrors are soiled by a liquid contaminant of refractive index n=1.466. Observations suggest that colour changes of less than ΔE~6 are imperceptible and colour changes of less than ΔE~11 are perceptible but acceptable.
Clearly it is possible to produce the stain masking coating of the invention in a broad range of colours, and for a given desired mirror colour, the visibility of stains can be effectively minimised. Table 5 shows calculated designs for stain masking mirror coatings of different colours.
TABLE 5 Further stain masking mirror coating designs
Yellow Blue Green White Red Violet
Lens
Cr 0.5 0.5 0.5 0.5 0.5 0.5
TiO2 90 123 125 67 101 142
SiO2 125 154 160 115 129 63
TiO2 102 120 264 67 87 47
SiO2 170 106 81 176 137 159
TiO2 107 94
SiO2 83 80
Lightness L* 34 19 28 76 21 45
Chroma C* 49 42 35 72 44 64
Hue h* 71 292 173 103 7 292
Stained ΔE 7.1 3.6 7.3 4.9 4.1 3.4
It will be understood that the invention disclosed and defined in this specification extends to all alternative combinations of two or more of the individual features mentioned or evident from the text or drawings. All of these different combinations constitute various alternative aspects of the invention.