Holographic security labels are currently manufactured in large quantities using embossed foil mass-production techniques. A variety of levels of security are provided by a combination of multiple images, image complexity, multiple colours, multiple illumination formats, messages, coded messages, overt images, covert images and label removal prevention.
Semi-transparent embossed reflection holograms, designed to overlay visible printed documentation are known. U.S. Pat. No. 5,351,142 discloses a reflection hologram comprising a transparent embossed layer with a reflectivity which is enhanced by a layer of tin tungsten oxide. U.S. Pat. No. 5,781,316 discloses a cost-effective method of making a reflection hologram comprising a transparent embossed layer with a reflectivity which is enhanced by a layer of zinc sulfide. U.S. Pat. No. 4,856,857 discloses a reflection hologram is enhanced by a layer of zinc sulfide. U.S. Pat. No. 4,856,857 discloses a reflection hologram comprising a transparent embossed layer with a reflectivity which is enhanced by an overlayer of different refractive index. These methods produce embossed reflection hologram structures which produce a stable image, i.e. one which is designed not to change in visibility or appearance during normal operating conditions.
U.S. Pat. No. 5,838,466 discloses a reflection hologram comprising a transparent embossed layer with a reflectivity which is suppressed by the addition of a transparent layer which is removed by hand in order to make the holographic image visible. This device is a means of providing a covert embossed reflection hologram which can be revealed easily by manual removal of an index matching layer.
Another way of providing covert holographic images is to form the stored image so that it is read only by a focussed beam of light, as disclosed in U.S. Pat. No. 5,742,411.
Outside the field of holographic security labels but in the field of chemical sensing, several devices and methods have been described which operate by modifying the optically diffractive properties of diffraction gratings and other surface structures in order to sense the presence or concentration of chemical analytes. WO88/07273, EP0254575 and U.S. Pat. No. 5,118,608 all disclose methods of treating a diffraction grating with a polymer to which a chemical ligand has been attached so that the optical properties of the grating are altered by binding of a chemical analyte to the ligand. Optical devices of this type seek to sense small changes in intensity or colour of diffracted light in order to interpret such changes as analyte presence or concentration. They are not image-forming devices or security labels.
WO99/63408 describes an alternative method of producing a holographic sensor. A sequential treatment technique is used, wherein the polymer film is made first and sensitive silver halide particles are added subsequently. These particles are introduced by diffusing soluble salts into the polymer matrix where they react to form an insoluble light-sensitive precipitate. The holographic image is then recorded.
WO01/50113 describes a holographic sensor which comprises a plurality of holographic recordings. The presence or appearance of each holographic image is visible to the eye as a function of the response of the sensor to the analyte; that response may involve the appearance or disappearance, or a change in, a visible image. Typically, each image has a reflection spectrum characterised by its location in the invisible or visible spectrum of light. The location in the spectrum may be unique to each image, such that the images are separable by wavelength-selective means, and are therefore wavelength-multiplexed. During recordal, the swelling state of the support medium may be varied for each exposure, to produce images which replay at different wavelengths.
WO04/081676 describes a “silverless” holographic sensor, in which the holographic fringes are defined by different degrees of swellability in a liquid. The holographic image is recorded by selective (de)polymerisation of the support medium, wherein the medium is in a swellable state during the recording. A particular procedure involves two polymerisation steps, the first forming a sensitive polymeric matrix and the second forming, in selected parts of the matrix, a different degree or type of polymerisation, thereby forming a holographic image. The second step may involve further cross-linking of the matrix, or the formation of an interpenetrating polymer.
The present invention is based on the realisation that sensors of the type described above may have limited utility in the field of security. It is based also on the discovery of various techniques by which holographic devices can be made more difficult to forge. In particular, the present invention provides an improved embossed reflection hologram or diffraction pattern device for application to an article or product such that a covert image can be revealed by a deliberate, chemically-specific action to remove or alter the properties of an index-matching layer in order to test the authenticity of the holographic device and/or that of the article or product to which it is attached.
According to a first aspect of the invention, in a hologram or diffraction pattern device adapted to display an image alterable by an interrogator, the device comprises an image-former and an image-concealer; wherein the image-former is adapted such that light reflected from or transmitted through the image-former forms at least one holographic or diffraction image; wherein the image-concealer acts to attenuate the holographic image; and wherein the action of the interrogator is to alter the attenuation of the holographic or diffraction image by the image-concealer. In some embodiments, the image-former forms a serialized image, such as a holographic serialized image. The image formed by the image-former can be a bar code, such as a holographic bar code.
According to a second aspect of the invention, a hologram or diffraction pattern device comprises a relief pattern in one surface of a first sheet of material (which may be termed an image-former) such that reflected light forms one or more holographic or diffraction images, and a layer of chemically-sensitive material applied to the relief pattern which combines the properties of hiding the holographic or diffraction image formed by the relief pattern with those properties which render the layer susceptible to degradation by one or more specific chemical reagents. In some embodiments, the holographic or diffraction image comprises a serialized image, such as a holographic serialized image. The holographic or diffraction image can be a bar code (e.g., a holographic bar code).
A third aspect of the invention is a holographic device comprising a medium and, disposed therein, a hologram, wherein the medium comprises a birefringent material in which the hologram is recorded. In some embodiments, the hologram comprises a serialized image. The hologram can comprise a bar code.
Another aspect of the invention is a method of verifying the authenticity of a holographic or diffraction device, the device providing a holographic or diffraction image which changes in response to interrogating by a specific interrogation means, the method comprising the steps of:
applying the specific interrogation means to the device;
viewing the image; and
establishing whether the resulting image is consistent with an authentic device.
A further aspect is a method of verifying the authenticity of a product, the product having a holographic or diffraction device thereon, the device providing a holographic or diffraction image which changes in response to interrogation by a specific interrogation means, the method comprising the steps of:
applying the specific interrogation means to the device;
viewing the image; and
establishing whether the resulting image is consistent with a device previously applied to the authentic product.
Yet another aspect of the invention is a method for concealing or revealing a holographic or diffraction image, comprising the steps of;
applying an image-concealer to attenuate the holographic or diffraction image formed by an image-former; and
interrogating the image-concealer using an interrogation means to vary the attenuation of the image and thereby conceal or reveal the image.
A yet further aspect of the invention is a method of production of a holographic device, which comprises the recording of a hologram by selective (de)polymerisation of a polymeric medium, wherein the medium is in a swellable state during the recording, and wherein the degree of exposure is varied across the medium during the recording.
Yet another aspect of the present invention is based on the discovery that, by contracting the support medium when the holographic image is recorded, the replay wavelength and, in turn, the sensitivity of the resulting sensor is increased. Accordingly, a method of production of a holographic sensor comprises:
(a) disposing within a contractable or expandable holographic support medium a holographic recording material;
(b) contracting or expanding the medium; and
(c) recording a holographic image in the contracted or expanded medium;
wherein the recording material is disposed in the medium prior to its contraction or expansion.
Controlling the degree of contraction or expansion of the medium during the recording process allows the replay wavelength and, in turn, the sensitivity of the resulting sensor to be accurately controlled. Sensors produced in this way may be used for the detection of an analyte or in security/authentication.
a and 2b show sectional schematics of devices according to further embodiments of the present invention incorporating both overt and covert images. The holographic devices have a first group of one or more images that are visible under normal conditions and are therefore described as overt, and also have a second group of one or more images which are invisible under normal conditions and are therefore described as covert. The overt holograms in this case are carried in a volume distribution of complex refractive index 5 formed by silver, silver salt, cross-linked polymer, photopolymer or other method of creating a volume hologram supported in an appropriate matrix. The second group of holograms is carried by a reflective embossed surface 2. This surface 2 may be that of the material which carries the first, overt, volume holograms (
A description of example embodiments of the invention follows.
The present invention provides an improved embossed reflection holographic device which can be used to test the authenticity of the device or an article to which it is attached. The device may be embossed.
In alternative embodiments, the first sheet of material may comprise a volume distribution of complex index of refraction which forms one or more visible images in reflection, as well as or instead of a relief pattern, or there may be also be provided a second sheet of material underlying the first sheet of material comprising a volume distribution of complex index of refraction which forms one or more visible images in reflection or transmission.
The first sheet of material may be opaque. Alternatively, the first sheet of material may be optically transparent and have a refractive index which is similar to that of the layer of chemically-sensitive material. The first sheet of material may contain within its volume a distribution of complex index of refraction which forms one or more holographic or diffraction images.
The layer of chemically-sensitive material may be opaque. Alternatively, the layer of chemically-sensitive material may be optically transparent and have a refractive index which is similar to that of the first sheet of material.
The layer of chemically-sensitive material may be composed in whole or in part of one or more substrates to one or more enzymes, or of one or more materials which can be dissolved by one or more solvents.
Preferably, the image formation means comprises a relief surface such that when light reflects from the relief surface, the reflected light forms an image. The relief surface may be opaque.
Preferably, the image concealment means comprises a layer of material, the optical properties of which act to attenuate the or each image. The interrogation means preferably comprises a chemical reagent which acts specifically on the image concealment means.
The interrogator may act to alter the optical properties of the image concealment means, e.g. it may act to remove some or all of the image concealment means.
The image concealment means may comprise a substrate of an enzyme, or may comprise material which can be dissolved by a solvent. The means may be in contact with the relief surface of the image formation means and have a refractive index similar to the refractive index of the relief surface of the image formation means. The optical properties of the image concealment means which are altered by the chemical reagents may comprise the refractive index of all or part of the image concealment means. The means may be positioned such that light reflected from or incident on the image formation means passes through it. The absorption of light by the image concealment means may act to attenuate the or each image; wherein the absorption of light by the image concealment means is altered by the action of the interrogation means. The scattering of light by the image concealment means may act to attenuate the or each image; wherein the scattering of light by the image concealment means is altered by the action of the interrogation means.
The image formation means may alternatively or further comprise a volume distribution of complex index of refraction which forms one or more visible images in reflection. The means may comprise a plurality of layers wherein the top layer comprises the relief surface and wherein an underlying layer comprises a volume distribution of complex index of refraction which forms one or more visible images in reflection or transmission.
A preferred embodiment of the invention may thus be a device comprising one or more covert holograms or a combination of covert and overt security holograms which are designed to be interrogated by specific chemicals in order to indicate authenticity of a product to which the device is attached or, in the absence of a positive response, to indicate that the product may be a fake. The procedure provides, in addition, an indicator of authenticity of the holographic device itself. In such a device, a reflection hologram may be created in the form of a contoured, or relief, surface without any metal coating, the reflectivity being due to the difference in refractive index between the contoured material and its immediate environment. During manufacture, the holographic image may then be rendered invisible by application over the relief surface of a transparent layer which has a similar refractive index to that of the hologram. The material of the layer is preferably chosen to be able to be degraded, removed or have its refractive index altered by the action of a specific chemical or specific mixture of chemicals. The image revealed may advantageously be difficult to copy or counterfeit and is therefore of security value in itself.
In alternative embodiments, diffraction images rather than holograms may be generated.
Following the foregoing description, it will be apparent to the skilled person that the invention envisages a range of possible embodiments. In terms of principles of operation, these include the following.
The image-former may comprise a holographic or diffraction device of any kind. For example, it may comprise a surface relief element, such as an embossed surface, or a volume element, such as a phase hologram or an absorption hologram, or may comprise both surface relief and volume elements, for example for producing different images.
If a surface relief element is to be used to generate a covert image, it may be combined with an image-concealer either for matching the refractive index of the surface relief element, to suppress reflection, or comprising an opaque or scattering layer for obscuring the image.
If a volume element is to be used to generate a covert image, it may be combined with an image-concealer either comprising an opaque or scattering layer for obscuring the image, or comprising a colour filtering function if the image is coloured, again for obscuring the image. Where a colour filtering function is used, interrogation would either alter the colour of the filter or remove the filter.
If a surface relief element is to be used to generate an overt image, while for example the device also comprises a volume element to form a covert image, the image-concealer may comprise a colour filtering function.
If a volume element is to be used to generate an overt image, while for example the device also comprises a surface relief element to form a covert image, the image-concealer may be transparent and may match the refractive index of the surface relief element.
Where a refractive index matching technique or a colour filtration technique is used to hide or reveal an image, it should be noted that the application of a corresponding interrogation technique may either reveal the image, which was previously hidden by the image-concealer, or hide the image, which was previously not hidden by the image-concealer. An example might be if a refractive-index-matching image-concealer covers a surface relief image-former, in which the refractive index of the image-concealer matches that of the image-former, to hide the image, only when an interrogation means is applied.
As described above, an interrogation means may comprise any means for modifying, altering or removing an image-concealer so as to reveal or hide an image. Examples include water, detergents, the application of heating or cooling (for example to change the refractive index of a material), solvents, enzymes, acids or bases.
In a further embodiment, an image-concealer may obscure only part of the area of an underlying image-former.
A hologram of the invention may be recorded in a birefringent support medium. Without wishing to be bound by theory, it is believed that it is virtually impossible to forge such a hologram. This is because, during “copying”, the light reflected from the original hologram has a different polarisation state to that hitting the recording material. This results in a faulty copy, since a hologram cannot be formed using light of different polarisation states. Holograms of this type can be formed by incorporating, for example by polymerisation, liquid crystal or optically active groups (e.g. L-cysteine) in the holographic support medium. The hologram can be viewed using, for example, a polarising filter, the image appearing then disappearing as the polarisation of reflected light is changed by the medium.
The invention is also concerned with techniques for producing holograms having a colour gradient. It has been discovered that when the “silverless” polymerisation method is used, the replay wavelength of the resulting image is dependent on the exposure time during recording. This effect is particularly pronounced for images formed by selective (de)polymerisation using a free radical inhibitor. It follows that, if the degree of exposure is varied across the recording medium, the resulting hologram replays at a plurality of wavelengths. The degree of exposure can be varied, for example, using a grey-scale mask. This methodology is much simpler than conventional techniques, as the support medium does not have to be expanded or contracted for each exposure. The invention thus provides a simple yet viable means of producing a hologram having a complex colour gradient, such a gradient being virtually impossible to forge.
There are two primary techniques that may be used, to create improved security with volume holograms. The first involves the use of multiple colours and/or colour gradients within the holographic image, to make forgery much more difficult. The second approach uses sensor holograms with specific sensitivieties, allowing images to appear or disappear when the sensor is interrogated with a specific stimulus or set of stimuli. An array of these sensor holograms can also be used to enhance the security features. A combination of these two techniques can create volume holograms which are very difficult to forge.
For the first technique, holograms with different colour images or a gradient of colour images are produced by controlling the swelling state of the polymer material during the recording process. This can be achieved by pre-swelling/pre-contracting the polymer in different solvents, moisture, heat, pressure or chemicals before recording the hologram. This can also be achieved by chemically and selectively hardening or softening areas of the polymer. The extent of the swelling of the polymer will determine the replay of colour of the holographic image when the hologram is dry. Both systems can also be used to create a swelling gradient, to produce a gradient of colours in the holographic image. Using the multiple colours and/or a gradient of colours will make it near impossible to forge the hologram using a single laser and very difficult to forge even with multiple lasers of differing frequencies. Images of different colours can also be superimposed onto one another by recording them at different swelling states of the polymer which would also make forgery very difficult. This system can also be used to create images which appear or disappear when the polymer is in a specific swelling state, adding to the security features.
In the second technique, smart polymers sensitive to specific stimuli are used as the recording material for the holograms. Using the first technique, multi-coloured images can be recorded with the smart polymer and they can be made to change, appear or disappear when the polymer is subjected to a specific stimulus which the smart polymer responds to. Regular variation of the smart polymer used in the recording process and the use of an array of different smart polymers can further add to the security features of this system.
The holographic effect may be exhibited by illumination (e.g. under white light, UV or infra-red radiation), specific temperature, magnetic or pressure conditions, or particular chemical, biochemical or biological stimuli. The hologram may be an image of an object or a 2- or 3-dimensional effect, and may be in the form of a pattern which is only visible under magnification.
Holograms of the invention may be used to authenticate an article. The hologram may be applied to an article using a transferable holographic film which is, for example, provided on a hot stamping tape. The article may be a transaction card, banknote, passport, identification card, smart card, driving license, share certificate, bond, cheque, cheque card, tax banderole, gift voucher, postage stamp, rail or air ticket, telephone card, lottery card, event ticket, credit or debit card, business card, or an item used in consumer, brand and product protection for the purpose of distinguishing genuine products from counterfeit products and identifying stolen products. The holograms may be used to provide product and pack information for intelligent packaging applications. “Intelligent packaging” refers to a system that comprises part of, or an attachment to, a container, wrapper or enclosure, to monitor, indicate or test product information or quality or environmental conditions that will affect product quality, shelf life or safety and typical applications, such as indicators showing time-temperature, freshness, moisture, alcohol, gas, physical damage and the like. The article may be a tramper-proof label or seal.
Alternatively, the holograms can be applied to products with a decorative element or application such as any industrial or handicraft item, including but not limited to items of jewelry, items of clothing (including footwear), fabric, furniture, toys, gifts, household items (including crockery and glassware), architecture (including glass, tile, paint, metals, bricks, ceramics, wood, plastics and other internal and external installations), art (including pictures, sculpture, pottery and light installations), stationery (including greetings cards, letterheads and promotional material) and sporting goods.
The invention is particularly relevant to holographic sensors.
A holographic sensor of the type used in this invention generally comprises a support medium and, disposed throughout the volume of the medium, a hologram. The support medium interacts with an analyte resulting in a variation of a physical property of the medium. This variation induces a change in an optical characteristic of the holographic element, such as its polarisability, reflectance, refractance or absorbance. If any change occurs whilst the hologram is being replayed by incident broad band, non-ionising electromagnetic radiation, then a colour change may be observed.
There are a number of basic ways to change a physical property, and thus vary an optical characteristic. The physical property that varies is preferably the size of the holographic element. This variation may be achieved by incorporating specific groups into the support matrix, where these groups undergo a conformational change upon interaction with the analyte, and cause an expansion or contraction of the support medium. Such a group is preferably the specific binding conjugate of an analyte species. Another way of changing the physical property to change the active water content of the support medium.
A holographic sensor may be used for detection of a variety of analytes, simply by modifying the composition of the support medium. The medium preferably comprises a polymer matrix, the composition of which must be optimised to obtain a high quality film, i.e. a film having a uniform matrix in which holographic fringes can be formed. The matrix may be formed from the copolymerisation of, say, (meth)acrylamide and/or (meth)acrylate-derived monomers, and may be cross-linked. In particular, the monomer HEMA (hydroxyethyl methacrylate) is readily polymerisable and cross-linkable. PolyHEMA is a versatile support material since it is swellable, hydrophilic and widely biocompatible. Other materials suitable for use in the invention are described in WO95/26499 and WO99/63408, the contents of which are incorporated herein by reference. A “smart” polymer is preferred i.e. a material that responds to the presence of one or more specific analytes in its environment by, say, a change in volume. The sensor may be prepared according to the methods described in WO95/26499, WO99/63408 and WO04/081676.
The property of the holographic element which varies may be its charge density, volume, shape, density, viscosity, strength, hardness, charge, hydrophobicity, swellability, integrity, cross-link density or any other physical property. Variation of the or each physical property, in turn, causes a variation of an optical characteristic, such as polarisability, reflectance, refractance or absorbance of the holographic element.
The interaction can be detected remotely, using non-ionising radiation. The extent of interaction between the holographic medium and the analyte species is reflected in the degree of change of the physical property, which is detected as a variation in an optical characteristic, preferably a shift in wavelength of non-ionising radiation.
Controlling the degree of contraction or expansion of the medium during the recording process allows the replay wavelength and, in turn, the sensitivity of the resulting sensor to be accurately controlled. A holographic sensor having a controlled sensitivity can be produced by disposing within a contractable or expandable holographic support medium a holographic recording material; contracting or expanding the medium; and recording a holographic image in the contracted or expanded medium; wherein the recording material is disposed in the medium prior to its contraction or expansion. Contraction or expansion of the support medium may be achieved by immersing the medium in a suitable liquid during the recording process. For the purposes of illustration only, an acrylamide-based support medium can be contracted using a solution of NaNO3 or ethanol. In this case, the replay wavelength and sensitivity of the resulting sensor may be accurately controlled by controlling the concentration of the solution.
Holographic sensors may be used in a test strip, chip, cartridge, swab, tube, pipette or any form of liquid sampling or testing device, and products or processes relating to human or veterinary prognostics, theranostics, diagnostics or medicines. The sensors may be used in a contact lens, sub-conjuctival implant, sub-dermal implant, test strip, chip, cartridge, swab, tube, breathalyzer, catheter, any form or blood, urine or body fluid sampling or analysis device. Holographic sensors may also be used in a product or process relating to petrochemical and chemical analysis and testing, for example in a testing device such as a test strip, chip, cartridge, swab, tube, pipette or any form of liquid sampling or analysis device.
Contraction or expansion of the support medium may be achieved by immersing the medium in a suitable liquid during the recording process. For the purposes of illustration only, an acrylamide-based support medium can be contracted using a solution of NaNO3 or ethanol. In this case, the replay wavelength and sensitivity of the resulting sensor may be accurately controlled by controlling the concentration of the solution.
The devices described herein can contain any desired holographic image or diffraction patter image. For example, a holographic image or diffraction patter image of an object or a 2- or 3-dimensional effect, and may be in the form of a pattern which is only visible under magnification. If desired the holographic image or diffraction patter image can provide information that gives the device, or article to which the device is applied or incorporated, a unique traceable identity. For example, the devices described herein can contain a holographic serialization image, such as a bar code or other suitable serialization image (e.g., a string of digits/numbers). Many types of bar codes are known and can be used in the invention, such as bar codes based on linear (one dimensional) symbologies (e.g., Code 39, UPC-A, UPC-E, EAN-8, EAN-13, RSS-14), two dimensional symbologies (PDF417, Data Matrix, Aztec Code), composite symbologies, and high density geometric symbol sets. (See, e.g., US2005/0285761 and US2007/0040032 the entire contents of each of these documents are incorporated herein by reference).
For serialization of articles that contain a device of the invention or have a device of the invention (e.g., sensor hologram) applied thereto, each article will need a separate serialization image, such as a unique bar code. Thus, the devices of the invention should be produced en masse using a process that produces hologram that have distinct serialised identities (barcode or number or other suitable serialization image). This can be accomplished using the following methods.
A general method for producing suitable holograms involves recording the hologram using a “master” and a suitable recording medium.
H1 master images can be recorded on standard holographic plates which are coated with holographic light sensitive emulsion, for example Colour Holographics BB plates. H1 masters are created as the initial holographic plates using any desired 2D or 3D art. From the H1 masters the H2 plates are formed combining all the images in the H1 master(s) where necessary. The H2 plates are the templates from which the final H3 product is formed. They have the property that the image is close to the film plane and is thus viewable in ordinary light. The H3 hologram should be identical to the H2 but is often recorded on commercial relevant material. In addition, the H3 can be recorded as a “contact copy” using an overhead white laser beam. The length of time exposure of the holographic plate can vary depending upon design preferences or requirements, but typically will be seconds such as 1 second to about 60 seconds depending on the laser, exposure requires, and other factors.
Generally, holographic plates are chemically sensitised, and after exposure are chemically developed and chemically bleached to produce the visible image. For example, Colour Holographics BB plates can be sensitised with 1-20% (w/w) aqueous triethanolamine (TEA) solution before exposure. Following exposure of the holographic plates, they are developed. Typical developer formulations contain equal volumes of the following: 20 g/l-50 g/l Ascorbic acid, 2 g/l-10 g/l aminophenol (METOL), 10 g/l-40 g/l sodium hydroxide, and 50 g/l-150 g/l sodium carbonate. A typical development time is 1 second to several minutes.
Following development, the holograms are usually ‘fixed’ with a sodium thiosulphate solution (10-30 (w/v) sodium thiosulphate (aq) for approximately 5 minutes to remove any residual silver halide that was not developed. The hologram plate may then be bleached using, for example, an iron II EDTA solution (20 g/l-40 g/l Iron II sulphate, 20 g/l-40 g/l EDAT di-sodium salt, 20 g/l-40 g/l Potassium bromide, 10 g/l-30 g/l aluminum sulphate and 20 g/l-40 gill sodium hydrogen sulphate). The exact concentrations of the developer and bleach may depend on the conditions and exposure times and be within the skill of the person recording the holograms.
In the usual H3 recording process, the ‘H2 master’ and the recording medium (H3) are placed in intimate contact on a flat-bed or stretched around a circular drum. A copy of the hologram is then made by laser exposure. The beam usually passes through the recording medium and then through the master or it may pass through the recording medium and be reflected by the master (if metallized). The laser exposure may be pulsed or continuous. The film may be held stationary during exposure (step and repeat) or it may move with the drum. Unique identities can be recorded in consecutive holograms (serialized holograms) by modifying this general procedure as described below.
In a first method, the mirror or master behind the recording medium is replaced with a smooth reflective metallic shim containing ‘wheels’ with numbers (e.g., 0 through 9). These numbers could be engraved on the wheel, be defined by areas of different reflectivity, or produced using any other suitable method. The shim will resemble a date-time stamp, such as the type used in banks. The shim would have cogs (e.g., two or more cogs) which have different numbers and which can be rotated with respect to each other to produce different strings of digits. The rotation of the cogs can be automated (e.g. by clockwork) and would be in-phase with the film passing through the machine.
In another method, different serialised barcodes/digits are printed (e.g. with an ink-jet printer) in black ink on a film substrate, and the resulting printed film substrate is laminated onto the recording medium, and then used as a mask during the laser exposure. After recording, the laminate mask would be removed leaving a film of the same hologram with different barcodes/digits over each image. The mask and film substrate should be passed over the drum/plate together without slippage with respect to each other. Index matching could be used if desired.
In another methods, a transparent (black on glass) liquid crystal display (LCD) type device is positioned in front of or behind the recording medium (i.e. with no master present) and exposes with a laser. The image in the LCD can be controlled and serialized using a computer. Other types of display devices, such as optical display devices can be substituted for the LCD and used in a similar way, if desired.
Specific embodiments of the present invention will now be described by way of example with reference to the drawings. A first embodiment of the invention is illustrated in
The purpose of such a chemically-specific optical holographic device in the area of product security is provision of a restricted means of authenticating products which, for purposes of maintaining a brand image or otherwise, should not have an obvious mark, the device being substantially transparent.
Another preferred embodiment of the invention is illustrated in
One application of any of the embodiments of the invention described above may be as a transparent label which is attached to a bottle of an alcoholic beverage with no apparent image and acting as a product authentication device which would need to be included by counterfeiters if they were to replicate the product packaging. In one case, the overlayer (the layer 3) would remain in place until its removal by a specific chemical mixture applied by a person employed to investigate the distribution of counterfeit products. The image revealed by such an operation can be proprietary to the brand owner of the product and therefore act as a further security device.
The following Examples illustrate the invention.
One example of the device which is a subject of this invention uses a visible hologram which is a surface-embossed holographic grating impressed into a clear plastic such as polyester or polyvinyl chloride. As a result of constructive interference and Bragg reflection, a distinctive colour is observed from such a surface when it is illuminated with broad-band light. In this example, the colour may be in the mauve region of the spectrum. In order to make the colour disappear, a layer of gelatin is coated onto the embossed surface. The characteristics of the resulting device are that the reflected colour is in the visible region while the coating is saturated with water, which alters the refractive index of the gelatin, but when the coating dries out the entire film is transparent because the refractive index of the gelatin then matches that of the clear plastic beneath. This particular (gelatin) film can be removed by washing in hot water or, alternatively, by applying a proteolytic enzyme such as trypsin to dissolve the film. This approach can be extended to a wide range of other enzymes or mixtures of enzymes if the gelatin overlayer is replaced by one made from one or more different polymer materials which carry, in part or in whole, one or more components which are cleavable by a specific enzyme or group of specific enzymes. A particular example of a substrate is starch, which would be removed by the action of the enzyme amylase.
Another example of the device is similar to Example 1 but instead of the overlayer including enzyme substrates it is formed from a polymer or mix of polymers which are soluble, swellable or contractable in specific solvents. Changing the thickness changes the refractive index by virtue of both density change and addition of a solvent to the structure. One method which may be employed to coat the relief pattern is the solvent cast method, although this is not exclusive. For example, a layer of cellulose acetate can be solvent cast in acetone and the device interrogated by dissolving off the cellulose acetate layer in acetone.
Another example of the device is of the type previously described as Example 1 or 2 but with the addition of an underlayer comprising a volume hologram which provides an always visible (overt) image.
A holographic support medium was formed by copolymerising 60 mol % acrylamide, 30 mol % methacrylamide, 5 mol % methylenebisacrylamide (a cross-linker) and 5 mol % 2-acrylamido-2-methyl-1-propanesulphonic acid. Silver halide was then immobilised within the medium. The medium was then immersed in water and a holographic image recorded. Four more sensors were formed in this way, each formed using one of the following solutions in place of water: 2M NaNO3, 20% (v/v) ethanol, 7M NaNO3 and 40% (v/v) ethanol (ordered in terms of their increasing contracting effect on the support medium). The resulting sensors were tested for their response to sodium chloride solutions of varying ionic strengths.
A sample hologram was made using a single continuous wave laser working at 633 nm. The recording material was gelatine and different sections of the polymer were pre-soaked in different solutions to produce various colours. A green section was the result of a pre-soak in 5% diethylene glycol and 10% triethanolamine in water, a blue section was due to a pre-soak in 10% diethylene glycol and 5% triethanolamine in water, a red-orange section had not been pre-soaked at all. This 3-colour hologram would be impossible to forge with a single laser. Mixing the pre-soak mixtures to form a gradient with different diethylene glycol and triethanolamine concentrations produce a gradient of colours across the holograms which would be impossible to forge.
The teachings of all patents, published applications and references cited herein are incorporated by reference in their entirety.
While this invention has been particularly shown and described with references to example embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention encompassed by the appended claims.
Number | Date | Country | Kind |
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GB 0423544.6 | Oct 2004 | GB | national |
GB 0416128.7 | Jul 2004 | GB | national |
GB 0412718.9 | Jun 2004 | GB | national |
This application is a continuation-in-part of U.S. application Ser. No. 11/402,709, which is the U.S. National Stage of International Application No. PCT/GB2005/002226, filed on Jun. 6, 2005, published in English, which claims priority to 1) United Kingdom Application No. GB 0423544.6, filed Oct. 22, 2004; 2) United Kingdom Application No. GB 0416128.7, filed Jul. 19, 2004; 3) and United Kingdom Application No. GB 0412718.9, filed Jun. 8, 2004. The entire teachings of the above applications are incorporated herein by reference.
Number | Date | Country | |
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Parent | PCT/GB05/02226 | Jun 2005 | US |
Child | 11402709 | Apr 2006 | US |
Number | Date | Country | |
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Parent | 11402709 | Apr 2006 | US |
Child | 11789689 | Apr 2007 | US |