RU2639807C1 - Protective element for polygraphic products and fraud-proof polygraphic product - Google Patents

Abstract

FIELD: physics.SUBSTANCE: protective element is proposed comprising luminescent regions forming latent colour images visible when irradiated by exciting radiation of UV-band, made with inks containing nanocrystalline materials based on quantum dots. One part of the image is characterized by the spectral composition of the radiation consisting of one narrow-band line, and the other part of the image is characterized by the spectral composition of the radiation consisting of at least two narrow-band lines. The luminescent colours of the mentioned images are identical when viewed with the naked eye, but are different when viewed through the narrow band colour filters that ensure the selection of the spectral composition of the luminescent radiation. The stated task is also solved by the polygraphic product which comprises a protective element characterized above.EFFECT: creation of a reliable protective element, the authenticity of which can be verified visually with the help of simple technical means.5 cl, 2 dwg

Description

The invention relates to the field of protection against counterfeiting, as well as for marking, identification of paper and plastic printing products, such as securities, identification documents.

Various protective elements are known that are used for marking, identifying and counterfeiting printing products, in particular printing elements having color-changing properties based on moire, holographic, diffraction and other optical-physical effects. Such elements are formed on surfaces or in the volume of protected products. As protective elements, printed images made with inks luminescent in the visible or infrared ranges when exposed to exciting radiation are widely used.

The most promising is the use of nanostructured luminescent compounds, the so-called quantum dots.

The possibility of using luminescent marking, which provides a high level of protection, is known due to the use of luminescent labels containing semiconductor nanocrystalline structures based on quantum dots (QDs). The presence of the effect of size quantization in QDs provides unique properties. Thus, a change in the size of QDs from one material causes a change in the band of their luminescence in a wide spectral range. The use of nanocrystals of semiconductor compounds as QDs is more promising since, unlike dyes, it is possible to efficiently excite the luminescence of nanocrystals of different sizes with a single light source, both laser and broadband. Nanocrystals exhibit narrower and more symmetrical luminescence bands than conventional organic dyes (A.B. Baranov et al. “Practical Use of Nanostructures, St. Petersburg, 2014, pp. 73-76).

In recent years, various methods of protection against counterfeiting of valuable products using nanoparticles have been actively developed.

For example, a protection method is known in which a passive protective label of a predetermined structure is formed on a valuable product, particles of silicon or porous silicon of nanoscale level of at least three different sizes are used as the material of the passive protective label, and the presence and authenticity of the security label can be controlled provide a method of analysis of the effects of luminescence during external exposure to probing electromagnetic radiation of the visible optical range and detection of inform active signs of the security tag in its optical response to the mentioned external influence followed by visual and automatic comparison of the registered parameters of the security tag's informative features with the informative features contained in the database of the detection tool. Probing electromagnetic radiation is generated for each size of a nanoparticle of the aforementioned substance, first with a frequency and power characteristic of excitation of luminescence of a nanoparticle of a corresponding size, and then with increased power, which reduces the contrast of luminescence (RU 2359328, 06/20/2009).

A known method of encoding and decoding data, in which encoding involves applying a luminescent dye to an object of a matrix code, and decoding involves reading information using an optoelectronic device and decrypting it using a previously created algorithm. Data is applied by at least three different luminescent dyes, which significantly differ from each other in color, intensity and luminescence lifetime. Information decoding includes illuminating the matrix code with a light source and fixing the luminescent radiation with an optoelectronic device, record data on the spatial configuration of the matrix code, the spectral band, the intensity and duration of the luminescent glow and transmit them to a decoding device (RU 2436157, 12/10/2011).

Due to the well-known shape of the luminescence spectra of quantum dots, analysis of the luminescence spectrum of their mixture provides reliable identification of components and the establishment of their quantitative contributions. However, such an analysis requires the use of special expensive spectral equipment, which is a drawback when conducting the authentication of printed materials.

Thus, the known methods of protecting products using quantum dots are highly effective, but expensive. In this regard, there is a need to develop new effective security elements for printing products, characterized by ease of authenticity control.

Closest to the proposed invention is a technical solution described below.

A luminescent image is known containing a series of non-overlapping cells based on at least two luminescent materials that emit different colors upon excitation. For each cell, a point of luminescent material is determined, having a size of no more than the size of the cell, while some of the points emit radiation of combining colors to form a third color. The combination of radiation from adjacent cells forms an image zone with a given color. The luminescent dots are located in combinations decoded by a filter (US 2006/0201362, 09/14/2006).

A disadvantage of the known solution is the ease of forgery due to a fairly simple analysis of the used luminescent materials located in the corresponding cells.

The problem solved by the present invention is the creation of a reliable security element, the authenticity of which can be checked visually using the simplest technical means.

The problem is solved by the described protective element for printing products, containing luminescent areas forming latent color images, visible when irradiated with UV radiation, made with inks containing nanocrystalline materials based on quantum dots, and one part of the image is characterized by the spectral composition of radiation, consisting from one narrow-band line, and the other part of the image is characterized by the spectral composition of radiation, consisting of of at least two narrow-band lines, while the luminescence colors of the above images are the same when observed with the naked eye, but are different when observed through narrow-band filters, allowing selection of the spectral composition of the luminescent radiation.

Preferably, one part of the image is made with paints based on quantum dots of the same type and the same particle size, and the other part of the image is made with paints based on quantum dots of two or more types and sizes. According to the invention, one part of the image can be made of material based on quantum dots luminescent with yellow radiation, and the other part of the image can be made of material based on a mixture of quantum dots luminescent with red and green radiation, respectively.

The problem is also solved by a printing product, which contains a protective element, described above.

The technical result achieved by the present invention is to increase the degree of protection of the product while maintaining ease of control of its authenticity.

The possibility of implementing the invention with the achievement of a technical result in the scope of the claimed combination of features is explained below and is illustrated using figures 1 and 2.

In FIG. 1 shows the characteristic sensitivity spectra of the human eye. In FIG. 2 shows images of a security element for printing products made on a paper or plastic substrate.

The proposed technical solution takes into account the properties of human vision and the monochromaticity of the luminescent radiation of quantum dots. The human eye has a rather crude spectral differentiation mechanism that uses receptors (cones) with only three overlapping spectral zones of spectrum sensitivity (Marks, WB, Dobelle, WH & MacNichol, EF Visual pigments of single primate cones. Science (1964) 143: 1181-1183 )

An example of a specific implementation of the invention, not limiting its scope.

In FIG. Figure 1 shows the characteristic sensitivity spectra for cones sensitive to radiation in the blue (curve C), green (curve 3), and red (curve K) regions of the spectrum. Dashed lines also show the possible arrangement of QD spectra of three different sizes, luminescent in the green (3), yellow (G), and red (K) spectral regions. The luminescence radiation of quantum dots is almost monochromatic with a spectrum width of about 70 nm - 40 nm and a wavelength determined by their size and chemical composition. Since the sensitivity curves of the red and green cones overlap strongly, the emission of a mixture of quantum dots luminescing with red (λ≈620 nm) and green (λ≈520 nm) radiation will be perceived as yellow radiation having a hue determined by the concentrations of red and green dots . The color of the luminescence of such a mixture, with an appropriate choice of the concentrations of red and green quantum dots, can practically not differ from the color of the luminescence of quantum dots luminescing with yellow (λ≈580 nm) radiation.

With an appropriate selection of QD concentrations, it is possible to achieve a complete coincidence of the color perception of the luminescence of the composition from a mixture of red and green dots with the color perception of luminescence from the one-component composition of quantum dots luminescing with yellow radiation (λ≈580 nm). The nonmonochromatic composition of the radiation of a mixture of red and green QDs can be detected using spectrally selective optical devices, the simplest of which are narrow-band filters. The selection of the sizes, chemical composition of the QDs and their concentrations, ensuring the coincidence of the luminescence color of the mixture of red and green QDs with the luminescence color of the yellow QDs, is a rather complicated technological task, which is practically impossible for counterfeiters.

When observing the proposed protective element in natural light or when illuminated with ultraviolet radiation, used to detect luminescent marks on securities, banknotes and other objects, its structure is indistinguishable, since the colors of its various elements (lettering, background, etc.) are visually indistinguishable, although and have different spectral compositions (luminesce by simple or compound radiation). Image elements become distinguishable when observing a protective element using appropriately selected filters that transmit radiation of the components of the composite radiation to different degrees.

As an example of a possible implementation of the proposed protective element. In FIG. 2 shows images of a security mark made on a black paper or plastic substrate 1, in the form of a rectangular region 2 filled with transparent fluorescent dye with quantum dots, luminescent yellow radiation at a wavelength of 580 nm, and an image 3 of the letter “A” formed inside it, made by transparent luminescent paint with a mixed composition of quantum dots of two types (sizes), luminescent at wavelengths of 520 nm and 620 nm. The concentration of quantum dots in the mixed composition is selected in such a way that the luminescence color of the ink used to make the image of the letter “A” maximally matches the color of the luminescent radiation of the paint in the background rectangular region, i.e. with a color of radiation at a wavelength of 580 nm. Upon direct observation of the label with the naked eye, neither the background rectangular region, nor the image of the letter "A" are practically invisible (Fig. 2a). When the label is illuminated with exciting luminescence by UV radiation, for example, with a wavelength of 365 nm and when observed with the naked eye, a bright yellow rectangular region will be observed (Fig. 2b). The image of the letter “A” will practically not appear, since the color of its luminescence coincides with the color of the luminescence of the background rectangular region (in Fig. 2b, the contrast of the letter “A” is increased for clarity). When observing a luminescent label through a narrow-band red filter with a passband in the region of 620 nm, the brightness and contrast of the background rectangular region sharply decrease, and the image of the letter “A” becomes clearly visible with a pronounced reddish tint (Fig. 2c). Similarly, when observing a luminescent label through a narrow-band green filter with a passband in the region of 520 nm, the contrast and brightness of the background rectangular region also decrease sharply, and the image of the letter “A” becomes distinguishable and takes on a greenish tint (Fig. 2d). When observing the label through a narrow-band yellow filter with a passband in the region of 580 nm, the background region becomes clearly distinguishable and yellow, the image of the letter "A" becomes dark gray and will also clearly differ (Fig. 2d).

Thus, observation of the obtained luminescent label through narrow-band filters allows revealing the latent structure of the label and thereby visualizing it in a simple and reliable way.

It is clear from the application materials that various known compounds based on elements of groups II-VI of the periodic table with a well-defined crystal structure and a narrow particle size distribution can be used as quantum dots. In addition, it should be noted that the use of semiconductor quantum dots in the manufacture of a protective element is promising, which are characterized by the ability to luminescence at any given wavelength.

Additionally, the following should be noted. Compared with the known products containing paints based on traditional organic or inorganic phosphors in the protective element, the effect of changing the color contrasts of images using filters cannot be achieved. This is due to the fact that, in contrast to narrow-band monochromatic luminescence spectra that are characteristic of quantum dots, the luminescence spectra of traditional phosphors are broadband.

Claims (5)

1. A protective element for printing products containing luminescent areas forming latent color images visible when irradiated with UV radiation, made with inks containing nanocrystalline materials based on quantum dots, and one part of the image is characterized by a spectral composition of radiation, consisting of one narrow-band line, and the other part of the image is characterized by the spectral composition of the radiation, consisting of at least two narrow-band lines, pr This color luminescence said images are the same when viewed with the naked eye, but they are different when viewed through uzkopolosye filters, providing a selection of the spectral composition of the luminescence radiation. 2. The security element according to claim 1, characterized in that the hidden color images are configured to be recognized by reading devices in high-speed modes of counting and sorting equipment. 3. The security element according to claim 1, characterized in that one part of the image is made with paints based on quantum dots of the same type and the same particle size, and the other part of the image is made with paints based on quantum dots of two or more types and sizes of particles. 4. The security element according to claim 1 or 2, characterized in that one part of the image is made of material based on quantum dots luminescent with yellow radiation, and the other part of the image is made of material based on a mixture of quantum dots luminescent with red and green radiation respectively. 5. A fake-protected printing product containing a security element described in paragraph 1

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