A Comparative Study of Adhesion Evaluation Methods on Ophthalmic AR Coating Lens

: Ophthalmic resin lenses are widely used to correct myopia and defend harmful light waves. Ophthalmic lens with anti-reﬂective (AR) coating has become the mainstream product in the lens market. The AR coating is composed by inorganic metal oxides, which is very di ﬀ erent to the organic lens substrate in thermal expansion coe ﬃ cients. In a normal wearing environment, coating delaminating often occurs resulting that AR function is disabled. How to evaluate adhesion of the AR coating is important. In this paper, a specially designed cutting tool was used to scratch two grids on each surface of the lens. The peel o ﬀ operation was carried out with the tape within speciﬁed adhesion range. The coating detachment was evaluated by visual inspection and microscopy based on the methods deﬁned in ISO 2409 and GB 10810.4, the applicability was compared and discussed.


Introduction
The vital role of the eye is to create the external world image. The imaging quality of a real object is, however, affected by refractive errors, dispersion, diffraction effects, and scattering [1,2]. The vision impairment proportion of the population has increased substantially [3,4]. To correct eyesight as well as to protect eyes against hazardous exposure to ultraviolet radiation [5], ophthalmic resin lenses are widely used and prevalent globally due to convenience and cost performance [6,7].
Surface coatings like primer coating, abrasion resistant hard coating, and anti-reflective (AR) coating are designed to improve optical quality of ophthalmic lens [8]. Of these functional coatings, AR coating is the most widely used. Usually, one or more thin films deposit sequentially on lens surface to form AR coating. By destructive interference between the light waves reflected from the surfaces and interfaces of thin films, an AR coating reduces the reflected light intensity for better transparency as well as vision [9]. The vast majority of commercial AR coatings on ophthalmic lenses are produced by physical vapor deposition (PVD) techniques [10,11]. Oxide coatings are well known to minimize surface reflections [12]. AR coatings are usually composed of inorganic metal oxides, like silica, titania, or zirconia [13,14]. However, during deposition process of the above inorganic

Materials and Methods
Sixteen pieces of AR coating lenses with a diameter of 70 mm as well as convex and concave curvature between 0.00 and 8.00 D were used as evaluation samples numbered from No. 1 to No. 16 (Note: in lens industry, curvature = (refractive index − 1)/radius of curvature). All of them were offered by China National Inspection Testing Center for Ophthalmic Optics Glass and Enamel Products (Shanghai, China).
Two positions were selected on convex surface of lens and the other two positions were selected on concave surfaces of the same lens. All four positions were selected at 5-10 mm from the lens edge. They were named as position A, position B, position C, and position D as shown in Figure 1. A flaw was not allowed in the selected positions.
Coatings 2020, 10, x FOR PEER REVIEW 2 of 11 like silica, titania, or zirconia [13,14]. However, during deposition process of the above inorganic metal oxides onto resin lens surface, several factors are still under investigation, namely low surface compatibility, deposited films homogeneity, and reflective behavior [15]. Large difference in thermal expansion coefficients between AR coating and resin lens substrate causes low surface compatibility which restricts the achievable level of durability and adhesion of AR coating [9]. In the case of avoiding coating detachment, adhesion evaluation method shall be a primary and key indicator for examining the durability of coatings at initial stage [16,17]. It is noteworthy that no formal standardized approach exists to evaluate coating adhesion of ophthalmic lens, although ISO 8980.4 [18] specifies durability test method for AR coatings on ophthalmic lens. Pull-off, twist-off, peel-off test, bend test, impact test as well as their combination or derivation test are standardized methods to measure adhesion of metallic coatings on metallic substrates [19], paints and varnishes on deformable or rigid panel [20][21][22], coatings for automobile construction [23], and adhesives [24,25]. However, these test methods are not suitable for ophthalmic resin lens for reasons like specific application, characterization aim, substrate limit, and so on. Another type of test method for adhesion can be catalogued to scratch/cut type. Under certain conditions, special cutting tools are used to draw expectant patterns on the coated samples, and partly detached coatings are removed by tape with action of "paste" and "peel off". Results are obtained by inspecting the flaking situation of the patterns [26][27][28][29][30][31]. This type of test is flexible and unlimited by substrate shape. It is amicable for testing ophthalmic lens with convex and concave surface. As far as we know, evaluating adhesion of AR coatings for ophthalmic lenses by scratch/cut test has been scarcely reported in the literature. In this work, we used a special blade set to draw 100 small squares on AR coatings of lenses, and then a tape with specific adhesive force range to "paste" and "peel off" squares. We carried out systematic research and comparative analysis using two inspections to evaluating coating adhesion on ophthalmic resin lens according to different characterization method.

Materials and Methods
Sixteen pieces of AR coating lenses with a diameter of 70 mm as well as convex and concave curvature between 0.00 and 8.00 D were used as evaluation samples numbered from No. 1 to No. 16 (Note: in lens industry, curvature = (refractive index − 1)/radius of curvature). All of them were offered by China National Inspection Testing Center for Ophthalmic Optics Glass and Enamel Products (Shanghai, China).
Two positions were selected on convex surface of lens and the other two positions were selected on concave surfaces of the same lens. All four positions were selected at 5-10 mm from the lens edge. They were named as position A, position B, position C, and position D as shown in Figure  1. A flaw was not allowed in the selected positions.   The lens was placed and stabilized by finger pressure on a fixed tabletop. A hand-held cutting tool with five blades (Figure 2) was applied to scratch the lens surface. The cutting tool was moved under uniform pressure in one direction with moderate force, and then 6 parallel scratches of 1 mm spacing and 20 mm long were engraved. The scratch depth penetrated the coating down to the substrate lens. Another parallel scratch series were engraved perpendicularly across the center of the former scratch series. Therefore, a grid set (Figure 1, position A) was formed. The rest grid positions of lens were scratched in the same way. Finally, a total of 100 small squares on the lens were formed.
Coatings 2020, 10, x FOR PEER REVIEW 3 of 11 The lens was placed and stabilized by finger pressure on a fixed tabletop. A hand-held cutting tool with five blades (Figure 2) was applied to scratch the lens surface. The cutting tool was moved under uniform pressure in one direction with moderate force, and then 6 parallel scratches of 1 mm spacing and 20 mm long were engraved. The scratch depth penetrated the coating down to the substrate lens. Another parallel scratch series were engraved perpendicularly across the center of the former scratch series. Therefore, a grid set (Figure 1, position A) was formed. The rest grid positions of lens were scratched in the same way. Finally, a total of 100 small squares on the lens were formed. A piece of tape (Scotch 600 industrial model, 3M Company, Shanghai, China, a specification of 25.4 mm × 65.8 m and adhesion strength of 44 N/100 mm) which was 75 mm long was cut. The tape was pasted on intersection of orthogonal scratches, covering the grid set center. The tape was pasted along one direction of scratches as shown in Figure 3. The tape smoothed by finger and air bubbles between the tape and the lens were squeezed with an eraser to remove. Good contact between tape and lens was essential. After waiting for 90 ± 30 s, the tape was removed backward at a direction parallel to the lens surface (as close as 180°), evenly and quickly. The coating detachment situation was evaluated using visual inspection and stereo microscope (SZ61 model, 20× magnification, OLYMPUS, Tokyo, Japan) observation, respectively.
The whole experiment process was carried out at a temperature of (23 ± 2) °C and a relative humidity of (50 ± 5)%. A piece of tape (Scotch 600 industrial model, 3M Company, Shanghai, China, a specification of 25.4 mm × 65.8 m and adhesion strength of 44 N/100 mm) which was 75 mm long was cut. The tape was pasted on intersection of orthogonal scratches, covering the grid set center. The tape was pasted along one direction of scratches as shown in Figure 3. The tape smoothed by finger and air bubbles between the tape and the lens were squeezed with an eraser to remove. Good contact between tape and lens was essential.
Coatings 2020, 10, x FOR PEER REVIEW 3 of 11 The lens was placed and stabilized by finger pressure on a fixed tabletop. A hand-held cutting tool with five blades (Figure 2) was applied to scratch the lens surface. The cutting tool was moved under uniform pressure in one direction with moderate force, and then 6 parallel scratches of 1 mm spacing and 20 mm long were engraved. The scratch depth penetrated the coating down to the substrate lens. Another parallel scratch series were engraved perpendicularly across the center of the former scratch series. Therefore, a grid set ( Figure 1, position A) was formed. The rest grid positions of lens were scratched in the same way. Finally, a total of 100 small squares on the lens were formed. A piece of tape (Scotch 600 industrial model, 3M Company, Shanghai, China, a specification of 25.4 mm × 65.8 m and adhesion strength of 44 N/100 mm) which was 75 mm long was cut. The tape was pasted on intersection of orthogonal scratches, covering the grid set center. The tape was pasted along one direction of scratches as shown in Figure 3. The tape smoothed by finger and air bubbles between the tape and the lens were squeezed with an eraser to remove. Good contact between tape and lens was essential. After waiting for 90 ± 30 s, the tape was removed backward at a direction parallel to the lens surface (as close as 180°), evenly and quickly. The coating detachment situation was evaluated using visual inspection and stereo microscope (SZ61 model, 20× magnification, OLYMPUS, Tokyo, Japan) observation, respectively.
The whole experiment process was carried out at a temperature of (23 ± 2) °C and a relative humidity of (50 ± 5)%. After waiting for 90 ± 30 s, the tape was removed backward at a direction parallel to the lens surface (as close as 180 • ), evenly and quickly. The coating detachment situation was evaluated using visual inspection and stereo microscope (SZ61 model, 20× magnification, OLYMPUS, Tokyo, Japan) observation, respectively.
The whole experiment process was carried out at a temperature of (23 ± 2) • C and a relative humidity of (50 ± 5)%.
Due to the bent face designed to achieve vision correction effect, adhesion performance as well as thickness of the AR coating deposited via PVD on ophthalmic lens may vary at different positions for each lens. In order to be identical, position A and B locate on convex surface while position C and D locate on concave surface on lens. The following results show a discrepancy of adhesion performance at different positions exists. A microscope magnification image of No. 6 sample is taken as an example shown in Figure 5. From Figure 5, it is visible that coating adhesion performances at position A and C are not as good as those at position B and D.  Due to the bent face designed to achieve vision correction effect, adhesion performance as well as thickness of the AR coating deposited via PVD on ophthalmic lens may vary at different positions for each lens. In order to be identical, position A and B locate on convex surface while position C and D locate on concave surface on lens. The following results show a discrepancy of adhesion performance at different positions exists. A microscope magnification image of No. 6 sample is taken as an example shown in Figure 5. From Figure 5, it is visible that coating adhesion performances at position A and C are not as good as those at position B and D.

Results and Discussion
Compared to base-lens without AR coatings, the AR coatings on No. 1-16 samples reduce the reflected light intensity as illustrated in Figure 4, implying the effectiveness of the AR coating. Due to the bent face designed to achieve vision correction effect, adhesion performance as well as thickness of the AR coating deposited via PVD on ophthalmic lens may vary at different positions for each lens. In order to be identical, position A and B locate on convex surface while position C and D locate on concave surface on lens. The following results show a discrepancy of adhesion performance at different positions exists. A microscope magnification image of No. 6 sample is taken as an example shown in Figure 5. From Figure 5, it is visible that coating adhesion performances at position A and C are not as good as those at position B and D.   According to ISO 2409:2013 [27] widely applied in paints and varnishes on plate substrate, coating detachment level can be divided into six classifications mainly based on detachment percent of grid area. The evaluation criterion is listed below (Table 1). According to ISO 2409:2013 [27] widely applied in paints and varnishes on plate substrate, coating detachment level can be divided into six classifications mainly based on detachment percent of grid area. The evaluation criterion is listed below (Table 1).

Classification
Description Appearance of Grid Sets 0 The edges of the cuts are completely smooth and none of the squares of the lattice is detached. -1 Detachment of small flakes of the coating at the inter-sections of the cuts. A cross-cut area not greater than 5% is affected.

2
The coating has flaked along the edges and/or at intersections of the cuts. A cross-cut area greater than 5%, but not greater than 15%, is affected. 3 The coating has flaked along the edges of the cuts partly or wholly in large ribbons, and/or it has flaked partly or wholly on different parts of the squares. A cross-cut area greater than 15%, but not greater than 35%, is affected.

4
The coating has flaked along the edges of the cuts in large ribbons, and/or some squares have detached partly or wholly. A cross-cut area greater than 35%, but not greater than 65%, is affected.

5
Any degree of flaking that cannot even be classified by classification 4. -Based on Table 1, detachment area of the No. 6 sample at position A ( Figure 5a) is greater than 65% which can be classified into Classification 5. All 25 squares of the grid set at position A occur detached phenomenon. But at position C, only 40-44% of area can be recognized as detachment from AR coating of the lens which can be classified into Classification 4. It is noteworthy that there are 14 squares of the grid set existing detached phenomenon while five squares detach completely from the AR coating of lens. However, the AR coating at position B and D show good adhesion as no detachment appears (Classification 0). The large discrepancy at different positions on the same AR coating of one lens suggests that it is necessary to select four positions to evaluate coating adhesion performance as precise as possible. Thus, four positions named as position A to D are examined on each lens to evaluate adhesion integrally in order to avoid randomness. To evaluate adhesion strictly, 2 The coating has flaked along the edges and/or at intersections of the cuts. A cross-cut area greater than 5%, but not greater than 15%, is affected.
According to ISO 2409:2013 [27] widely applied in paints and varnishes on plate substrate, coating detachment level can be divided into six classifications mainly based on detachment percent of grid area. The evaluation criterion is listed below ( Table 1). Detachment of small flakes of the coating at the inter-sections of the cuts. A cross-cut area not greater than 5% is affected. 2 The coating has flaked along the edges and/or at intersections of the cuts. A cross-cut area greater than 5%, but not greater than 15%, is affected. 3 The coating has flaked along the edges of the cuts partly or wholly in large ribbons, and/or it has flaked partly or wholly on different parts of the squares. A cross-cut area greater than 15%, but not greater than 35%, is affected.

4
The coating has flaked along the edges of the cuts in large ribbons, and/or some squares have detached partly or wholly. A cross-cut area greater than 35%, but not greater than 65%, is affected.

5
Any degree of flaking that cannot even be classified by classification 4. -Based on Table 1, detachment area of the No. 6 sample at position A ( Figure 5a) is greater than 65% which can be classified into Classification 5. All 25 squares of the grid set at position A occur detached phenomenon. But at position C, only 40-44% of area can be recognized as detachment from AR coating of the lens which can be classified into Classification 4. It is noteworthy that there are 14 squares of the grid set existing detached phenomenon while five squares detach completely from the AR coating of lens. However, the AR coating at position B and D show good adhesion as no detachment appears (Classification 0). The large discrepancy at different positions on the same AR coating of one lens suggests that it is necessary to select four positions to evaluate coating adhesion performance as precise as possible. Thus, four positions named as position A to D are examined on each lens to evaluate adhesion integrally in order to avoid randomness. To evaluate adhesion strictly, 3 The coating has flaked along the edges of the cuts partly or wholly in large ribbons, and/or it has flaked partly or wholly on different parts of the squares. A cross-cut area greater than 15%, but not greater than 35%, is affected.

Classification
Description Appearance of Grid Sets 0 The edges of the cuts are completely smooth and none of the squares of the lattice is detached. -1 Detachment of small flakes of the coating at the inter-sections of the cuts. A cross-cut area not greater than 5% is affected. 2 The coating has flaked along the edges and/or at intersections of the cuts. A cross-cut area greater than 5%, but not greater than 15%, is affected. 3 The coating has flaked along the edges of the cuts partly or wholly in large ribbons, and/or it has flaked partly or wholly on different parts of the squares. A cross-cut area greater than 15%, but not greater than 35%, is affected.

4
The coating has flaked along the edges of the cuts in large ribbons, and/or some squares have detached partly or wholly. A cross-cut area greater than 35%, but not greater than 65%, is affected.

5
Any degree of flaking that cannot even be classified by classification 4. -Based on Table 1, detachment area of the No. 6 sample at position A ( Figure 5a) is greater than 65% which can be classified into Classification 5. All 25 squares of the grid set at position A occur detached phenomenon. But at position C, only 40-44% of area can be recognized as detachment from AR coating of the lens which can be classified into Classification 4. It is noteworthy that there are 14 squares of the grid set existing detached phenomenon while five squares detach completely from the AR coating of lens. However, the AR coating at position B and D show good adhesion as no detachment appears (Classification 0). The large discrepancy at different positions on the same AR coating of one lens suggests that it is necessary to select four positions to evaluate coating adhesion performance as precise as possible. Thus, four positions named as position A to D are examined on each lens to evaluate adhesion integrally in order to avoid randomness. To evaluate adhesion strictly, 4 The coating has flaked along the edges of the cuts in large ribbons, and/or some squares have detached partly or wholly. A cross-cut area greater than 35%, but not greater than 65%, is affected.

Classification
Description of Grid Sets 0 The edges of the cuts are completely smooth and none of the squares of the lattice is detached. -1 Detachment of small flakes of the coating at the inter-sections of the cuts. A cross-cut area not greater than 5% is affected. 2 The coating has flaked along the edges and/or at intersections of the cuts. A cross-cut area greater than 5%, but not greater than 15%, is affected.

3
The coating has flaked along the edges of the cuts partly or wholly in large ribbons, and/or it has flaked partly or wholly on different parts of the squares. A cross-cut area greater than 15%, but not greater than 35%, is affected.

4
The coating has flaked along the edges of the cuts in large ribbons, and/or some squares have detached partly or wholly. A cross-cut area greater than 35%, but not greater than 65%, is affected.

5
Any degree of flaking that cannot even be classified by classification 4. -Based on Table 1, detachment area of the No. 6 sample at position A (Figure 5a) is greater than 65% which can be classified into Classification 5. All 25 squares of the grid set at position A occur detached phenomenon. But at position C, only 40-44% of area can be recognized as detachment from AR coating of the lens which can be classified into Classification 4. It is noteworthy that there are 14 squares of the grid set existing detached phenomenon while five squares detach completely from the AR coating of lens. However, the AR coating at position B and D show good adhesion as no detachment appears (Classification 0). The large discrepancy at different positions on the same AR coating of one lens suggests that it is necessary to select four positions to evaluate coating adhesion performance as precise as possible. Thus, four positions named as position A to D are examined on each lens to evaluate adhesion integrally in order to avoid randomness. To evaluate adhesion strictly, 5 Any degree of flaking that cannot even be classified by classification 4. -Based on Table 1, detachment area of the No. 6 sample at position A (Figure 5a) is greater than 65% which can be classified into Classification 5. All 25 squares of the grid set at position A occur detached phenomenon. But at position C, only 40-44% of area can be recognized as detachment from AR coating of the lens which can be classified into Classification 4. It is noteworthy that there are 14 squares of the grid set existing detached phenomenon while five squares detach completely from the AR coating of lens. However, the AR coating at position B and D show good adhesion as no detachment appears (Classification 0). The large discrepancy at different positions on the same AR coating of one lens suggests that it is necessary to select four positions to evaluate coating adhesion performance as precise as possible. Thus, four positions named as position A to D are examined on each lens to evaluate adhesion integrally in order to avoid randomness. To evaluate adhesion strictly, the worst classification of four positions is chosen as the final result. Therefore, for the No. 6 sample, the adhesion result can be catalogued into Classification 5.
As an account of this criterion, the results of the remaining lens samples are evaluated by visual inspection and microscope observation, respectively, in the same test environment and shown in Table 2. None of the 16 lenses shows optimal coating adhesion of Classification 0, implying that it is necessary to evaluate adhesion of coatings at the initial stage. For comparison, the classification results of Table 2  On the other hand, for coating adhesion that is not that good (like Classification 2), irregular grids are more widespread on lenses. So, the test operator may add the level of partially detached grid subjectively. Magnifying the tiny grids can redress misjudgment, resulting increased classification for lenses of No. 8 1  2  2  2  1  1  3  4  4  4  1  2  5  3  3  6  5  5  7  2  2  8  4  3  9  4  3  10  1  1  11  1  2  12  2  2  13  1  1  14  1  1  15  3  3  16 5 5  Microscopic observation has the advantage of saving clear and magnifying photographed images. From the point of reproducibility, microscopic observation seems more suitable than visual inspection in evaluating detachment area. Moreover, owing to magnifying photographed images, detachment area can be evaluated more precisely. However, microscopic observation relies on microscopy equipment which is not common or essential in lens manufacture factory. It is impracticable to evaluate adhesion by microscopic observation after AR coating deposited on lens in most of lens manufacture factory. Besides, considering that ISO 2409 method requires comprehensive evaluation of the area ratio of detachment area, evaluation is highly demanding on the test operator's professional experience and professional level. Result discrepancy among different test operators caused by subjective factor seems in existence. To avoid difficulty of evaluation detachment area, another evaluation criterion on account of counting detachment flakes amount is carried out as following.
In fact, evaluation criterion in Table 3 is from Chinese standard GB 10810. 4 [32]. According to specification of currently effective standard GB 10810.4, the results are shown in Table 4. As mentioned above, there are four positions selected to evaluate adhesion, therefore, average detachment amount is introduced as an index to determine whether coating adhesion is qualified or not integrally. The value of "average detachment amount" equals that the sum value of detachment amount at four positions (A-D) is divided by four.

Classification Description
-The edges of the cuts shall be completely smooth; none of the squares of the lattice shall be detached.
It can be seen that the value of average detachment amount for each lens is close, though the value of sum detachment amount is quite different when judging by visual and microscopic observations, respectively. According to GB 10810.4, the proportion of detachment amount shall be smaller than 15%, in other words, the average detachment amount shall be less than 3.75. When No. 5, 9, and 14 lenses are judged by the two observation means, adverse evaluations of qualified and unqualified occur, as shown in Figure 7. By visual inspection, No. 5, 9, and 14 lenses are qualified. The reason may be that lens sample is transparent and the scratching 100 squares are tiny. It is easy to ignore part of partially detached grids.
Coatings 2020, 10, x FOR PEER REVIEW 8 of 11 observations, respectively. According to GB 10810.4, the proportion of detachment amount shall be smaller than 15%, in other words, the average detachment amount shall be less than 3.75. When No. 5, 9, and 14 lenses are judged by the two observation means, adverse evaluations of qualified and unqualified occur, as shown in Figure 7. By visual inspection, No. 5, 9, and 14 lenses are qualified. The reason may be that lens sample is transparent and the scratching 100 squares are tiny. It is easy to ignore part of partially detached grids.  Table 5 is the microscope image of the three lenses of No. 5, 9, and 14. It can be seen that if the coating has flaked neatly and partially along the edges, results obtained by visual inspection and microscope observation are in discrepancy. The reason may be that lens sample is transparent and the scratching 100 squares are tiny. It is easy to ignore part of partially detached grids, especially in counting detachment amount.
Microscope observation with magnification effect can make tiny detachment much more apparently than visual inspection which is beneficial to obtain precise result. Although there are many advantages by microscope observation, it is more suitable in an elaborate lab test. It should be recognized that wider application in evaluating AR coating adhesion happens in factories for lens coating where it is scarcely possible to fit microscope equipment. Visual inspection is still an epidemic and effective means. A difference of 18.75% exists between visual inspection and microscopic observation according to counting detachment amount. Regarding lower difference and wider application for detachment amount evaluation (GB 10810.4) than detachment area evaluation (ISO 2409), detachment amount evaluation is recommended. It is worth mentioning that counting detachment amount is easier to operate and less error-prone. In addition, bent lens surface causes deformation of detachment area comparing to plane surface. Evaluation detachment area of tiny scratching grids is also more difficult.
In further work, more lens samples and test labs as well as manufacture factories should be involved in adhesion test for AR coating on ophthalmic lens so that an optimization standardized characterization method can be investigated.  Table 5 is the microscope image of the three lenses of No. 5, 9, and 14. It can be seen that if the coating has flaked neatly and partially along the edges, results obtained by visual inspection and microscope observation are in discrepancy. The reason may be that lens sample is transparent and the scratching 100 squares are tiny. It is easy to ignore part of partially detached grids, especially in counting detachment amount.

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means Coatings 2020, 10, x FOR PEER REVIEW 10 of 12 Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO 2409) and an 18.75% difference based on counting detachment amount (GB 10810.4) by using visual inspection and microscope observation, implying that counting the detachment amount is more Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO 2409) and an 18.75% difference based on counting detachment amount (GB 10810.4) by using visual inspection and microscope observation, implying that counting the detachment amount is more Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO 2409) and an 18.75% difference based on counting detachment amount (GB 10810.4) by using visual inspection and microscope observation, implying that counting the detachment amount is more Coatings 2020, 10, x FOR PEER REVIEW 10 of 12

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO 2409) and an 18.75% difference based on counting detachment amount (GB 10810.4) by using visual inspection and microscope observation, implying that counting the detachment amount is more Microscope observation with magnification effect can make tiny detachment much more apparently than visual inspection which is beneficial to obtain precise result. Although there are many advantages by microscope observation, it is more suitable in an elaborate lab test. It should be recognized that wider application in evaluating AR coating adhesion happens in factories for lens coating where it is scarcely possible to fit microscope equipment. Visual inspection is still an epidemic and effective means. A difference of 18.75% exists between visual inspection and microscopic observation according to counting detachment amount. Regarding lower difference and wider application for detachment amount evaluation (GB 10810.4) than detachment area evaluation (ISO 2409), detachment amount evaluation is recommended. It is worth mentioning that counting detachment amount is easier to operate and less error-prone. In addition, bent lens surface causes deformation of detachment area comparing to plane surface. Evaluation detachment area of tiny scratching grids is also more difficult.
In further work, more lens samples and test labs as well as manufacture factories should be involved in adhesion test for AR coating on ophthalmic lens so that an optimization standardized characterization method can be investigated.

Conclusions
In this paper, two evaluation methods (ISO 2409 and GB 10810.4) and two inspection means (visual inspection and microscope observation) for evaluating adhesion of an AR coating on ophthalmic lenses are studied. There is a 25% difference based on evaluation detachment area (ISO 2409) and an 18.75% difference based on counting detachment amount (GB 10810.4) by using visual inspection and microscope observation, implying that counting the detachment amount is more consistent. It is comprehensible that counting the amount is easier and more objective than estimating area. Transparent, bent lens surface, as well as tiny grids, exacerbate difficulty in estimating area. Although microscope images can be recorded to watch repeatedly and be evaluated by different testers to estimate deviation, it is more suitable in a lab testing scene. Visual inspection has the advantage of more application scenarios due to independence of certain equipment. Although visual inspection and microscopic observation results have statistics discrepancy, they are still within acceptable limits.