KR102632898B1 - Security film for forgery prevention and forgery authentication method using the same - Google Patents

Abstract

The present invention relates to a security film for preventing forgery and a forgery authentication method using the same. More specifically, in order to check whether a laminated security film has been forged or altered, the pattern layer is visible when separating the attachment surface of the film and the base layer. This relates to a security film that prevents reuse of the security film by including a physical tag that cannot be identified and at the same time checks forgery and tampering by buckling through mechanical stimulation and a forgery authentication method using the same.
A security film according to an embodiment of the present invention includes a base layer formed of a flexible material and including a high wrinkle area and a low wrinkle area; a pattern layer formed in a high wrinkle area of the base layer and having a Young's modulus greater than that of the base layer; And an upper layer that covers the low wrinkle area of the base layer and the pattern layer, and has a Young's modulus that is greater than that of the base layer and smaller than that of the pattern layer; wherein the pattern layer has a physical taggant inside ( taggant) may form invaginations.

Description

Security film for forgery prevention and forgery authentication method using the same {Security film for forgery prevention and forgery authentication method using the same}

The present invention relates to a security film for preventing forgery and a forgery authentication method using the same. More specifically, in order to check whether a laminated security film has been forged or altered, the pattern layer is visible when separating the attachment surface of the film and the base layer. This relates to a security film that prevents reuse of the security film by including a physical tag that cannot be identified and at the same time checks forgery and tampering by buckling through mechanical stimulation and a forgery authentication method using the same.

In modern times, various new products are being developed according to technological advancements, and transactions of the developed products are actively taking place online. However, unfortunately, cloning technology has also advanced greatly, making it difficult to distinguish between genuine and replica products. In the case of high-priced products, various anti-counterfeiting technologies are applied, but in the case of somewhat low-priced products that are inevitably distributed in large quantities, it is difficult to apply them, and in the case of items such as food, medical products, and cosmetics, they are directly related to human health and even life. It appears that social attention is needed.

Among anti-counterfeiting technologies, the anti-counterfeiting system using a photonic crystal-based pattern, which is widely used, has the disadvantage of being always visible in the presence of light, which is not suitable for hiding information, so its utility as an anti-counterfeiting system is limited.

Accordingly, much development is being conducted on a new type of anti-counterfeiting device that has a fast response to external stimuli (tensile, compression, bending, torsion, etc.) using a reflective method that allows structural color to appear.

In the case of an anti-counterfeiting device that is responsive to the external stimulus, a layer of a flexible material with a predetermined rigidity is built into the device, and the device is loaded using an external stimulus authentication method such as tension, compression, twisting, or bending. You can display an image based on the structural color that appears by adding .

Here, in the case of the buckling authentication method, which checks forgery and tampering by applying an external stimulus to the device in which the above-mentioned film layer is built, an image of a certain size is expressed by structural color, and the device itself is It needs to be made with a thickness and area greater than enough for the image to be displayed, and as a result, there are limits to its application to very small-sized devices.

In addition, with the development of authentication methods in which such structural colors are expressed, forgery technology is also gradually evolving. Therefore, applying only a single anti-counterfeiting method may not be able to respond to evolving forgery and forgery technology, so along with the buckling authentication method, micro-sized There is a need to improve security through a multi-authentication method that applies authentication methods together.

The present invention is applied to a security film to prevent forgery and tampering. An external stimulus is applied to layers with different Young's moduli, and a means of preventing tampering that enables authentication through buckling is applied to form a security film. When separating the pattern layer and the base layer, we aim to provide a security film that can prevent reuse of the security film by including a physical taggant that cannot be identified by the eye in the pattern layer, and a forgery authentication method using the same. .

A security film according to an embodiment of the present invention includes a base layer formed of a flexible material and including a high wrinkle area and a low wrinkle area; a pattern layer formed in a high wrinkle area of the base layer and having a Young's modulus greater than that of the base layer; And an upper layer that covers the low wrinkle area of the base layer and the pattern layer, and has a Young's modulus that is greater than that of the base layer and smaller than that of the pattern layer; wherein the pattern layer has a physical taggant inside ( taggant) may form invaginations.

In an exemplary embodiment, the physical taggant may be made of microparticles of 1 to 300 μm.

In an exemplary embodiment, the microparticles may be comprised in an amount of 1% by weight or less compared to the pattern layer.

In an exemplary embodiment, the microparticles may be plastic particles containing a polymer material and an organic dye and may have a specific image or text.

In an exemplary embodiment, the polymer material is any one selected from polyester, fluoropolymer, acrylate-methylmethacrylate copolymer, or polymethylstyrene. It may be made of a thermoplastic resin made of the above, or a thermosetting resin made of one or more selected from PMMA, PBA, or isocyanate resin.

In an exemplary embodiment, the organic dye may be a colored paint or a fluorescent dye.

In an exemplary embodiment, the base layer may be made of any one of EPU, polyurethane, Ecoflex, and rubber-based polymer materials.

In an exemplary embodiment, the plastic particles consisting of the specific image or specific text are formed with a certain rule at a plurality of positions in the pattern layer, and another image is formed by combining the specific image formed with a certain rule. Alternatively, another sentence may be formed by combining the specific texts.

In an exemplary embodiment, wrinkles are formed in the base layer, pattern layer, and upper layer by a single load selected from bending load, compression load, tensile load, shear load, or torsion load or by a combination of two or more loads, and the wrinkles are formed by the wrinkles. By creating a grating structure, different structural colors and images based on the structural colors can be formed.

In the forgery authentication method using a security film according to an embodiment of the present invention, the step of confirming forgery by structural color appearing when an external stimulus is applied to the base layer, pattern layer, and upper layer having different Young's moduli, and using a camera. Alternatively, it may include the step of confirming forgery and tampering by identifying the physical taggant embedded in the pattern layer through a microscope.

The present invention allows forgery to be confirmed using a buckling authentication method when an external stimulus is applied to laminated layers with different Young's moduli, and at the same time, a pattern containing a physical taggant containing micro particles that cannot be identified with the naked eye is embedded. Forgery can be confirmed by magnifying the layer with a camera or microscope to recognize the information, which has the effect of increasing the effectiveness of preventing forgery.

In particular, in a film structure in which multiple layers are stacked, if the pattern layer and the upper layer bonded to the base layer are separated for forgery, the physical taggant will be separated together, making it impossible to identify the physical taggant with a camera or microscope. This has the effect of preventing reuse of the film by allowing it to determine whether it has been forged or altered.

Figure 1 shows a cross-sectional view of a security film according to an embodiment of the present invention.
Figure 2 shows a diagram showing a state in which an image is formed by structural color using a buckling authentication method in a security film according to an embodiment of the present invention.
Figure 3 shows a diagram showing a state in which microparticles in a pattern are displayed when enlarged with a general camera on an image represented by structural color in a security film according to an embodiment of the present invention.
Figure 4 is a diagram showing a state in which another image or sentence is formed by combining a plurality of images or text in a pattern layer in a security film according to an embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 shows a cross-sectional view of a security film according to an embodiment of the present invention. Figure 2 shows a diagram showing a state in which an image is formed by structural color using a buckling authentication method in a security film according to an embodiment of the present invention. Figure 3 shows a diagram showing a state in which microparticles in a pattern are displayed when enlarged with a general camera on an image represented by structural color in a security film according to an embodiment of the present invention.

The security film disclosed in the present invention may have a structure in which a plurality of layers are stacked. A pattern formed of a flexible material, a base layer 10 including a high wrinkle area and a low wrinkle area, and a pattern formed on the high wrinkle area of the base layer 10, and having a Young's modulus greater than that of the base layer 10. An upper layer 30 covers the low wrinkle area of the layer 20 and the base layer 10 and the pattern layer 20, and has a Young's modulus that is greater than that of the base layer 10 and smaller than that of the pattern layer 20. Included, the pattern layer 20 may have a physical taggant (T) embedded therein that cannot be identified with the naked eye.

The base layer 10 may form a base among a plurality of layer structures formed by stacking. The base layer 10 may be made of a polymer material having a predetermined elasticity, and may be manufactured by the following method.

First, prepare a substrate made of polyethylene terephthalate (PET). Afterwards, epoxy (EPU) is cured on the upper surface of the substrate to form the base layer 10. In addition, it can be made of polypropylene or a natural material with excellent flexibility, and it is preferably made of a soft material that contains a plasticizer and has further improved flexibility. Specifically, the base layer 10 is made of EPU, polyurethane, polyurea, melamine resin, polydimethylsiloxane (PDMS), Ecoflex, and rubber. It is preferably made of any one of polymer materials.

Here, the external stimulus that can be applied to the security film may be a single load of compression, tension, pressing, or torsion load, including bending load, or a composite load of two or more, and the compressed deformation formed in the security film may be the compression, tension, or compression load. , may be deformation due to pressing, bending, or torsional loads.

Meanwhile, the step of forming the base layer 10 involves mixing the main material of EPU and the curing agent at a ratio of 10:1 and then removing air bubbles. Due to the low surface energy of EPU, a single EPU has poor adhesiveness. In order to solve this, it includes a process of mixing vinyl and platinum, removing air bubbles to increase adhesion with the pattern layer 20 to be formed on the top, and pouring and curing on the above-mentioned substrate. In addition, it is preferable to further include a process of plasma treating the cured base layer 10 to strengthen the interfacial bond with the pattern layer 20 formed on the top, and the Young's modulus of the base layer 10 formed in this way is It is desirable to have a range of 10 to 20 Mpa.

Next, a high hard material is printed on the high wrinkle area (FHW) of the upper surface of the base layer 10 to form a pattern layer 20. Here, the high hard material uses a material that is much harder than the base material, and therefore, it is desirable to use a material with a large Young's modulus value, for example, a Young's modulus in the range of 60 Gpa to 80 Gpa. A representative material that can be used as a high-hardness material is cellulose.

At this time, to describe the process of forming the pattern layer 20 in detail, the step of forming the pattern layer 20 is to mix cellulose powder and acetic acid in purified water (DI water) to form a high hardness. A step of manufacturing the material, a step of plasma treatment on the EPU before printing a hydrophilic cellulose solution on the upper surface of the EPU, which is a hydrophobic surface, to expand the area in contact with the cellulose droplets, and a step of increasing the adhesion between the EPU and cellulose, and using an inkjet printer. It includes the step of printing the high hard material on the base layer 10 according to the generated binary pattern.

Next, an acrylic solution is mixed with a reinforcing material that has at least one of the yield strength, tensile strength, impact strength, and shear strength greater than that of acrylic, and a medium hard material with a lower Young's modulus than a high hard material but a similar refractive index is applied to the base layer. The entire upper surface of (10) is impregnated to form an upper layer (30) spanning from the above-described high wrinkle area (FHW) to the low wrinkle area (FLW) adjacent to the high wrinkle area (FHW). A representative material that can be used as the reinforcing material is cellulose. In other words, the reinforcing material may be the same as the high hard material, and by using the same material as the high hard material, the adhesion between the pattern layer 20 and the upper layer 30 can be increased.

In addition, to describe the process of forming the upper layer 30 in detail, acrylic, a soft material (low hard material), is mixed with purified water and dissolved in hot water to create an acrylic aqueous solution. Thereafter, a step of mixing the prepared acrylic aqueous solution with a reinforcing material (cellulose) to produce a medium hard material with a Young's modulus lower than that of the high hard material but a generally similar refractive index, and the pattern layer 20 of the produced medium hard material. Before impregnating the formed base layer 10, the base layer 10 is plasma treated to increase the interfacial bonding force between the upper layer 30, the pattern layer 20, and the base layer 10, and the resulting medium hard material is fixed. It includes the step of impregnating from the wrinkle area (FHW) to the high wrinkle area (FHW) and the adjacent low wrinkle area (FLW), or impregnating the entire upper surface of the base layer 10. Here, the process of impregnating the medium hard material may use a spin coating method, a blade coating method, a spray coating method, or a dip coating method.

As described above, a high hard material is printed in the high wrinkle area (FHW) of the base layer 10 created on the substrate to form the pattern layer 20, and the low wrinkle area (FLW) adjacent to the high wrinkle area (FHW) is printed. ), the upper layer 30 is formed by impregnating the mid-wrinkle material, and then the upper layer 30 is cured together with the pattern layer 20 to produce a security film.

As in the above manufacturing method, durability can be improved when using a security film mixed with a medium-hard material and a reinforcing material that has at least one of the yield strength, tensile strength, impact strength, and shear strength greater than acrylic. There is an advantage.

If only acrylic is used as a medium-hard material, plastic deformation may occur when external stimulation due to bending occurs and a crack may be formed in the upper layer 30. The crack formed in this way clouds the surface of the security film, providing durability and anti-counterfeiting functions. can weaken.

On the other hand, when using acrylic as a medium-hard material and a security film mixed with reinforcing materials that have at least one of the yield strength, tensile strength, impact strength, and shear strength greater than acrylic, the fracture stress is high against deformation due to external stimuli. and strain rate, and at the same time, there is an advantage in that light transmission can also be maintained due to similar transmittance between the two.

Hereinafter, a security film according to an embodiment of the present invention manufactured using the above-described manufacturing method will be described.

As described above, the present invention allows the wrinkle structure on the surface of the structure formed by the deformation of the load to be used as a grating structure that represents the structural color, and is created as a grating structure by array of multiple wrinkles with different wavelengths according to differences in Young's modulus. This relates to a security film that allows various grating structures to form different structural colors and images based on the structural colors, and includes a base layer (10), a pattern layer (20), and an upper layer (30) having the physical properties described above. ), where the pattern layer 20 may be made of a hard polymer material, and a physical taggant (T) that cannot be identified with the naked eye may be embedded therein.

Here, the physical taggant (T) can be defined as an anti-counterfeiting physical additive containing identification information, and can be made of a microscopic size that cannot be recognized by the eye. It can take various forms, and information such as a specific number or company name can be provided in a microscopic size and checked with a camera or microscope to identify forgery or alteration.

Here, the physical taggant (T) may be made of microparticles of 1 to 300 μm.

The physical taggant (T) is made of a size that cannot be identified with the naked eye. In one embodiment, it is made of microparticles of 1 to 300 μm, so the taggant (T) can be identified only by magnifying a camera or using a microscope.

The table shown below shows the limits of the eye by focal length. The minimum size that a person with visual acuity 1.0 at a 10cm focal distance can see is about 29.1μm, and the minimum size a person can see at the limit is about 11.6μm. . Likewise, the minimum size that a person with visual acuity 1.0 can see at a 30cm focal length (smartphone) is about 87.3μm, and the minimum size a person can see at the limit is about 34.9μm.

Accordingly, the microparticles forming the physical taggant (T) embedded in the pattern layer 20 have a size of 1 to 300 μm, preferably 5 to 100 μm, so that the general public can identify the microparticles with the naked eye. Even if the presence of the taggant itself can be recognized by some people with good eyesight, it is impossible to identify the image or text formed by the microparticles, so the microparticles can only be identified using a camera or microscope. can do.

Additionally, the microparticles may be comprised in an amount of 1% by weight or less compared to the pattern layer 20. In order to limit the microparticles from being visible to the naked eye, in addition to the physical size described above, the pattern layer 20 may be restricted to contain only a portion of the total weight of the pattern layer 20 to make it difficult to confirm whether the microparticles themselves are contained. . In one embodiment, the microparticles consist of 1% by weight or less relative to the total weight of the pattern layer 20, so that it can be confirmed whether microparticles are contained only through a high-magnification camera or microscope, thereby further improving security. there is.

In an exemplary embodiment, the microparticles may be plastic particles containing a polymer material and an organic dye and may have a specific image or text.

The microparticles may be made of plastic particles containing polymer materials and organic dyes. The polymer material constituting the microparticles may be formed in the same manner as the hard polymer material constituting the pattern layer 20. In an exemplary embodiment, the polymer material is polyester, fluoropolymer. A thermoplastic resin made of one or more selected from (fluoropolymer), acrylate-methylmethacrylate copolymer, or polymethylstyrene, polymethyl methacylate (PMMA), poly It may be made of a thermosetting resin made of one or more selected from butyl acrylate (poly(butyl acrylate), PBA) or isocyanate resin.

Additionally, the organic dye may be made of colored paint or fluorescent dye. Here, the color of the particles can be identified through colored paints that constitute the organic dye, and the presence or absence of microparticles can also be identified by photoluminescence using a fluorescent dye.

In this way, security can be improved by forming various types of microparticles that limit not only the size but also the content, material, and color of the microparticles that form the physical taggant.

Figure 4 is a diagram showing a state in which another image or sentence is formed by combining a plurality of images or text in a pattern layer in a security film according to an embodiment of the present invention.

In an exemplary embodiment, the plastic particles consisting of the specific image or specific text are formed with a certain rule at a plurality of positions in the pattern layer 20, and the specific image formed with a certain rule is combined to form another An image may be formed, or another sentence may be formed by combining the specific text.

Microparticles forming the physical taggant or plastic particles composed of a specific image or specific text constituting the microparticles may be embedded in the pattern layer 20, and more specifically, at a plurality of positions within the pattern layer 20. Invaginations can be formed with certain rules. In one embodiment, the plurality of specific images constituting the plastic particles are composed of a plurality of carved images, and the carved images are combined to create another image, so that a single plastic particle can be viewed through a camera or microscope. In addition to the method of identification, it is possible to check for forgery or alteration by simultaneously checking all plastic particles made up of multiple images and identifying another image created by multiple specific images.

In another embodiment, a plurality of specific texts constituting the plastic particles may be arranged according to certain rules, and this may be identified through whether a single text exists, but when a plurality of specific texts are combined, You can also check for forgery by checking whether other sentences are completed.

Here, another sentence can be completed by combining multiple specific texts.

In an exemplary embodiment, the base layer 10, the pattern layer 20, and the upper layer 30 are subjected to a single load selected from bending load, compressive load, tensile load, shear load, or torsional load, or two or more combined loads. By forming wrinkles and creating a grating structure due to the wrinkles, different structural colors and images based on the structural colors can be formed.

The security effect can be increased by forming different images with structural colors that appear by setting different types or directions of the load applied to the security film. To form the grating structure, bending load, compressive load, tensile load, shear load or An external stimulus such as a torsional load is applied to create wrinkles, forming an image based on structural color.

Here, the load applied to the base layer 10, pattern layer 20, and upper layer 30 is bending load, compressive load, tensile load, and shearing load. ) or twisting load, which can be used to form different images.

Looking at the wrinkle formation principle that forms the grating structure, when an external stimulus is applied to the flexible base layer 10 and a bending load is applied in the direction of the upper layer 30 and the pattern layer 20, the thin and rigid upper layer 30 and the pattern layer 20 Buckling-type instability in the upper layer 30 and the pattern layer 20 due to mismatch in the mechanical properties of the base layer 10, which is thicker and softer than (20) and the upper layer 30 and the pattern layer 20. A wrinkle arrangement pattern with a periodic width is formed by (instability).

Here, the periodicity λ of the wrinkle arrangement is the thickness (h) and elastic modulus (E _f ) of the upper layer 30 and the pattern layer 20, and the elastic modulus (E _s ) of the base layer 10, which can be predicted through linear buckling theory. ) is determined as follows.

here, is the plane strain coefficient and is defined as E/(1-v ² ). v is the Poisson ratio. Equation 1 shows a model of the surface periodicity phenomenon and predicts the periodicity of the security film. In detail, the security film formed by laminating the upper layer 30, the pattern layer 20, and the base layer 10 of the present invention has a Young's modulus of the upper layer 30 and the pattern layer 20 compared to the Young's modulus of the base layer 10. Because it is very high, the upper layer 30 and the pattern layer 20 can be regarded as a film layer with rigidity, and the size (width) of each wavelength of the wrinkle is the upper layer 30, the pattern layer 20, and the base layer (10). ) is determined by the relative difference in Young's modulus (E) and the relative difference in thickness (h).

Here, because there is a relative difference in Young's modulus (E) and thickness (h) of the base layer 10, pattern layer 20, and upper layer 30, wrinkle arrangement patterns are formed differently. Due to the above-mentioned difference, the wrinkle structure (micro unit) formed in the high wrinkle area where the pattern layer 20 is formed and the wrinkle structure (nano unit) formed in the low wrinkle area where the upper layer 30 is formed are different. As a result, the saturation of the structural color and the image it represents are different.

In the forgery authentication method using a security film according to an embodiment of the present invention, the structural color that appears when an external stimulus is applied to the base layer 10, the pattern layer 20, and the upper layer 30 having different Young's moduli. It may include a step of confirming forgery and alteration by identifying a physical taggant embedded in the pattern layer 20 using a camera or a microscope.

More specifically, in the case of the forgery authentication method using the security film disclosed in the present invention, forgery and alteration can be confirmed by simultaneously performing the buckling authentication method and the authentication method for identifying the physical taggant. For example, the difference in Young's modulus (E) of the base layer 10, the pattern layer 20, and the upper layer 30 is used to form an image based on the structural color that appears when an external stimulus is applied, and whether or not it is forged or altered by the buckling method. can be confirmed, and the physical taggant formed in the pattern layer 20 and composed of micro particles cannot be identified with the naked eye, so it can be confirmed through a camera or microscope. The micro particles vary in size, content, material, and color. It can be identified in a variety of ways, and the anti-counterfeiting effect can be increased by checking for forgery and alteration by identifying a specific image or specific text from micro particles formed in various locations.

As mentioned above, the reuse of the film is prevented by a security film formed so that the physical taggant, which cannot be identified with the naked eye, is embedded in the pattern layer, more precisely, in the pattern layer where the structural color is expressed by external stimulation. You can. Specifically, in the case where the laminated layers are separated for forgery and tampering in a film in which several layers are laminated, unlike general films, the security film disclosed in the present invention contains a physical taggant that cannot be identified with the eye, so it cannot be used with a camera or microscope. It is possible to check whether a physical taggant exists or not. For example, if the film has not been forged or tampered with, the physical taggant is still present and can be identified with a camera or microscope, but if it has been tampered with or through an attempt at forgery, other layers attached to the base layer of the film have separated or some of the attachment surfaces have separated. If so, the physical taggant itself embedded in the pattern layer is separated and cannot be identified, so it is possible to check for forgery and tampering, thereby preventing reuse of the film.

Even if the effect is not described in the present specification, each of the above-described components may additionally have other effects in the present invention, and new effects that cannot be seen in the prior art are derived according to the organic combination relationship between each of the above-described components. can do.

In addition, the embodiments shown in the drawings may be modified and implemented in other forms, and if implemented including the configuration claimed in the claims of the present invention or implemented within the scope of equivalents, they should be considered to fall within the scope of the rights of the present invention. something to do.

10: Base layer
20: pattern layer
30: upper layer

Claims (10)

A base layer formed of a flexible material and including a high wrinkle area and a low wrinkle area;
a pattern layer formed in a high wrinkle area of the base layer and having a Young's modulus greater than that of the base layer; and
An upper layer covering the low radius area of the base layer and the pattern layer, and having a Young's modulus that is greater than that of the base layer and smaller than that of the pattern layer,
The pattern layer is formed with a physical taggant that cannot be identified with the naked eye.
The physical taggant consists of microparticles of 1 to 300 μm,
The microparticles are made of plastic particles containing polymer materials and organic dyes with a specific image or text,
A security film, characterized in that the plastic particles consisting of the specific image or the specific text are formed with a certain rule at a plurality of positions in the pattern layer. delete According to paragraph 1,
A security film, characterized in that the microparticles consist of 1% by weight or less compared to the pattern layer. delete According to paragraph 1,
The polymer material is,
A thermoplastic resin made of one or more selected from polyester, fluoropolymer, acrylate-methylmethacrylate copolymer, or polymethylstyrene,
A security film characterized in that it is made of a thermosetting resin consisting of one or more selected from polymethyl methacylate (PMMA), poly(butyl acrylate) (PBA), or isocyanate resin. According to paragraph 1,
The organic dye is,
A security film characterized by being made of colored paint or fluorescent dye. According to paragraph 1,
The base layer is,
A security film characterized by being made of any one of EPU, polyurethane, polyurea, melamine resin, polydimethylsiloxane (PDMS), and rubber-based polymer materials. According to paragraph 1,
Plastic particles consisting of the specific image or specific text,
A security film, characterized in that another image is formed by combining the specific image formed according to the certain rule, or another sentence is formed by combining the specific text. According to paragraph 1,
The base layer, pattern layer, and upper layer are,
Wrinkles are formed by a single load selected from bending load, compressive load, tensile load, shear load, or torsion load or by a combination of two or more loads, and a grating structure is created due to the wrinkles, so that different structural colors and the structural colors A security film characterized by forming an image. In the forgery authentication method using the security film according to any one of paragraphs 1, 3, and 5 to 9,
Confirming forgery and alteration by structural color that appears when an external stimulus is applied to the base layer, pattern layer, and upper layer having different Young's moduli;
A forgery authentication method using a security film, comprising the step of confirming forgery by identifying a physical taggant embedded in the pattern layer through a camera or microscope.

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