RU2614980C1 - Security marking and product containing this marking - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: security marking is made using inorganic luminescent compounds based on rare earth and alkali metals containing substituent elements. The protective marking, based on these compounds, has a Stokes and / or anti-Stokes luminescence in the wavelength range of 400-2500 nm, which arises under the influence of the exciting radiation lying in the spectral range of 700-1000 nm. Marking luminescence has the property to change its intensity without changing its spectral composition under the influence of the stimulating radiation in the spectral range of 300-700 nm. The protective marking is entered into the basis of the value document, or applied to its surface by printing.

EFFECT: high level of the product protection against counterfeit.

9 cl, 11 ex, 1 tbl

Description

The invention relates to the field of protection of products from counterfeiting and is intended for instrumental determination of the authenticity of protected printing products.

Recently, with increasing competition among manufacturers of security printing products, as well as the growing technical capabilities of potential counterfeiters, complex security features have become increasingly relevant. Such protective features are understood as technical solutions in which, during instrument control, authenticity is checked not one but two or more parameters related in a specified way, or a specific reaction to two or more simultaneously specified actions is evaluated.

Examples of such complex effects include the dependence of the UV luminescence of a substance on the temperature applied to it, or the angle of rotation of the plane of polarization of linearly polarized radiation under the influence of an external electric field, or a reversible color change of a substance under the influence of heat and light.

Usually, to increase the operational performance and reliability of control of valuable documents, chemical and / or elemental control of substances included in the protective label is complicated, in order to eliminate the influence of well-known interference and imitators, they increase the selectivity and sensitivity of control methods, and thus try to minimize weight (percentage) amount of protective substances in the overall composition of the labeling material.

An important requirement for security features for instrument and machine authentication is also their secrecy. In this regard, decisions that do not show their properties in the visible range of the spectrum are of practical interest for creating comprehensive security features.

One of the most popular physical phenomena used in the protection of valuable documents is the luminescence of substances under the influence of exciting radiation (light) and is called photoluminescence.

The widespread occurrence of the phenomenon of photoluminescence in protecting the authenticity of valuable documents is due to the simplicity of its control, the possibility of contactless control, high speed, high selectivity of modern instrument control methods used.

The proposed solution is based on the known physical phenomena of photostimulation (“flash” or flashing) and optical quenching of photoluminescence, which are fundamental in nature and described below.

Both phenomena under consideration possess the required set of properties and can be considered as the basis for creating protective features with a complex (combined) effect. Moreover, it is obvious that luminescent compositions with non-standard optical properties, unknown to the population, and unused in industry, can be of particular interest in solving the task of protecting against forgery of valuable documents.

The effect of optical quenching by infrared radiation of the visible luminescence of inorganic compounds based on zinc sulfide is explained in the literature on the basis of a simplified zone model. In this model, IR quenching of luminescence is associated with the release of holes with emission centers ionized by UV radiation into the valence band, followed by their non-radiative recombination at the quenching centers formed by specially introduced impurity quenching ions. The situation basically remains the same if the quencher is not a hole trap, but a deep electron trap. Here the recombination interaction of impurity centers occurs, which usually have effective charges of opposite signs. A hole freed by thermal vibrations from the center of luminescence migrates to the quenching center that has captured the electron and recombines with it. In addition, small electron traps can play the role of quenching centers. With decreasing temperature, the time spent by electrons in them increases, and therefore the possibility of recombination of the latter with holes increases. The degree of quenching, that is, the fraction of nonradiative transitions, depends on the density of the excitation power. As in the case of the interaction of two luminescence centers, this is explained by the fact that with an increase in the intensity of the exciting radiation, the recombination rate increases faster (proportionally to N _a ⋅n - where N _{a is the} number of ionized centers, n is the number of free electrons) than the rate of hole release from ionized centers extinguishing. As a result, the quenching effect changes. The degree of quenching also depends on the duration of the stimulating radiation pulses (τ). Obviously, if the pulse duration (τ) is less than the time of hole capture at the ionized emission centers, then the holes will not have time to return to the above centers.

Inorganic compounds having photostimulated luminescence or quenching of luminescence in the visible spectrum are known in the art. Examples of known formulations are shown in table 1.

Of the compounds presented, the composition of ZnS-Cu, Me, Cl, where Me-Co ²⁺ for quenching and Me-Pb ₂₊ , Sm ₃₊ or Mn ₂₊ for flash, should be classified as practically important. Studies of IR sensitivity spectra, flash spectra (green for Pb ₂₊ , red for Sm ₃₊ and orange for Mn ₂₊ ), as well as the kinetics of the afterglow of visible luminescence, showed that these compounds work according to the following scheme:

where e _c is the electron in the conduction band, ap _v is the hole in the valence band.

The amount of light accumulated in such luminescent compounds under optimal conditions of UV excitation reaches 10 ¹⁴ -10 ¹⁵ quanta · cm ^-2 , i.e. commensurate with the total number of impurity centers at the penetration depth of the exciting radiation (~ 50 μm for λ _exc ⁼ 365 nm and С _Cu ≈3⋅10 ¹⁷ cm ^-3 ). At the same time, the efficiency of ZnS-Cu, Me, Cl luminescent compounds is limited primarily by the incomplete absorption of the recorded luminescent radiation, which is no more than 10-15%.

Thus, the currently known optically sensitive luminescent compounds based on zinc sulfide are designed to detect only quenching of visible luminescence when exposed to radiation in the region from 0.7 to 1.0 μm.

The main disadvantage of these compounds, which excludes the possibility of their use as luminescent compounds with photostimulated quenching of luminescence upon excitation by radiation in the range from 0.7 to 1.0 μm and stimulation by UV radiation, is the absence of ions in their composition that provide, when excited by radiation, in the range from 0.7 to 1.0 μm, Stokes or anti-Stokes luminescence in the specified spectral region.

In this regard, to solve this problem, it is required to use other classes of compounds that are capable of providing photostimulated quenching of the luminescence obtained upon excitation in the spectral region 700–2500 nm due to the effect of radiation in the wavelength range from 300 to 700 nm.

The necessary parameters of luminescent compounds with photostimulated quenching (“intensity modulation”) of luminescence in the spectral range of 700–2500 nm when exposed to radiation in the wavelength range of 300–700 nm are as follows:

- the presence of rare earth ions or their pairs (for example, Yb - Er) in the composition of the compounds, which, when excited by laser radiation in the range from 700 to 1000 nm, provide Stokes and anti-Stokes luminescence in the region of 700-2500 nm;

- the presence in the composition of compounds of ions forming donor levels in the band gap (deep electron traps) with a low probability of release of the electrons located on them. The formation of such traps can be achieved by partial heterovalent substitution of cations of the pigment matrix by other ions, which have a large electron capture cross section;

- the presence of ions in the composition of compounds that form acceptor levels in the band gap of the crystal (deep hole traps). The formation of this type of traps can be achieved due to the partial heterovalent substitution of cations of the pigment matrix by other ions, which have a large hole capture cross section.

By selecting quenchers or sensitizers spatially located near the luminescence centers, it is possible to purposefully organize channels for selecting charge carriers from the luminescence centers or vice versa of the inflow. In both cases, modulation of stationary photoluminescence is observed (negative - quenching, positive - synergistic flaring). Moreover, when applying only electromagnetic oscillations corresponding to the frequency (wavelength) of a change in the intensity of the luminescence signal, it is not observed at all.

Using this approach, it is possible to choose luminescent compounds with modulation of stationary Stokes and anti-Stokes luminescence based on inorganic substances - sulfides, oxides, oxysulfides, phosphates, compositional compounds of alkaline earth, rare earth elements having both recombination and intracenter luminescence mechanisms.

This principle, which underlies the creation of protective markings, can also be considered in conjunction with other types of impacts. In particular, of practical interest are inorganic luminescent compounds, which have a pronounced property of thermal quenching of luminescence, and at the same time additionally contain metal ions, due to which they acquire ferromagnetic properties. During magnetization reversal of such substances with a high frequency, a change in the temperature of their luminescence centers is observed, and, as a result, a change in the luminescence intensity due to the effect of thermal quenching or thermal emission.

From US 4387112, a technical solution is known that uses inorganic luminescent compounds with rare earth ions for the authenticity of valuable documents with anti-Stokes luminescence in the visible spectrum.

At the present stage, this solution does not provide the necessary level of security due to the availability of these luminescent compounds in the free market. Also, this solution does not have the property of changing the intensity of luminescent radiation when exposed to stimulating radiation.

From US 4047033, a method is known for instrumental authenticity verification of a valuable document based on the use of inorganic compounds with rare-earth ions based on the SrS compound having flare (photostimulated) luminescence in the visible range of the optical spectrum.

The disadvantage is the use of the visible range of the spectrum when registering a sign.

From RU 2379192 C1, a valuable document with a protective marking is known based on an inorganic luminescent compound containing rare-earth metal ions, which has the phenomenon of photostimulated luminescence in the visible range of the optical spectrum. This solution is aimed at solving the problem of creating a security feature based on the visual dynamic effect, which consists in the apparent flashing and spreading of the luminescence brightness bands, and is not aimed at creating a hidden security label for instrumental authentication.

From RU 2388054, luminescent materials are known having an invisible but machine-readable spectral code formed by at least two materials with overlapping spectral bands as a response. Each of the materials is a powder pigment and contains a matrix with an embedded phosphor.

Closest to the proposed invention is the invention according to RU 2379195 C1.

The known invention describes a protective labeling based on an inorganic luminescent compound containing rare earth metal ions, including based on rare earth metal phosphates containing replacement elements. A well-known solution is aimed at instrument control of the authenticity of a valuable document. It involves authenticity control taking into account the totality of the optical properties of the compound used, namely: the luminescence spectrum, the excitation spectrum, the dependence of the intensity of the spectral bands on the power of the exciting radiation and the kinetics of their acceleration and / or attenuation.

However, the above solution does not provide the desired reaction with the integrated effect of radiation on the protective label, and in this regard, the degree of protection of inorganic compounds used in the known solution is insufficient.

The objective of the proposed invention is the development of protective markings that increase the level of security of the product with expert or machine determination of its authenticity, which is based on the phenomena of both optical quenching of luminescence and photostimulation of luminescence.

The problem is solved by the proposed protective marking for instrument control of the authenticity of the product, made on the basis of inorganic luminescent compounds of rare-earth and alkaline-earth elements containing replacement elements having a chemical composition corresponding to the following empirical formula:

where Ln ₁ is one of the ions La ₃₊ , Gd ₃₊ , Y ₃₊ and / or any of their combinations;

Ln ₂ is one of the ions Yb ₃₊ , Er ₃₊ , Nd ₃₊ , Ce ₃₊ , Tm ₃₊ , But ₃₊ and / or any of them

combinations;

Me ₁ is one of the ions Mg ₂₊ , Ca ₂₊ , Sr ₂₊ , Ba _2+;

Me ₂ - one of the ions Ti ₄₊ , Zr ₄₊ , Si ₄₊ , Ge ₄₊ , Sn ₄₊ ;

0≤x≤0.60;

0.01≤y≤0.10;

0.005≤z≤0.05;

0≤n≤1;

0≤m≤1;

n + m = 1,

and the structure of the crystalline structure, which is characterized by a high concentration of associated nonradiative capture centers of free charge carriers formed around the luminescence centers, due to which the proposed marking has Stokes and / or anti-Stokes luminescence in the spectral range 400-2500 nm arising under the influence of exciting radiation lying in the spectral range of 700-1000 nm, and a change in the given law of the luminescence intensity without changing its spectral composition under the air Corollary stimulating radiation lying within the spectral range of 300-700 nm.

Particles of inorganic luminescent compounds that are part of the protective markings can be characterized by sizes from 0.1 μm to 50 μm. Inorganic luminescent compound can be introduced into paint, transparent varnish, coating, printing binder, adhesive layer, as well as into a paper base, polymer base, rubber, metal layer, composite material.

The problem is also solved by the proposed product, made in the form of a valuable document that contains the protective markings described above. The product can be a banknote, an excise stamp, a postage stamp, a passport, a travel document, a driver’s license, an identity card, a security paper, a plastic card, a label, a payment document. Protective marking on the product can be made in the form of geometric figures, guilloche elements, graphic or alphanumeric characters.

Preferably, the marking is colorless and indistinguishable in daylight.

The determination of the authenticity of the marking may consist in the fact that they produce an excitation radiation in the spectral range of 700-1000 nm, and the change in the intensity of the excitation radiation over time is described by a harmonic function or the sum of harmonic functions. A change in the intensity of Stokes and / or anti-Stokes luminescence is recorded in the wavelength range of 400-2500 nm. Parameters proportional to the degree of distortion of the original harmonic signal are calculated. The stimulating source is switched on in the spectral range of 300-700 nm, the change in parameter values is recorded.

In addition, the authenticity of the product with the declared protective markings can be evaluated as follows. Excitation radiation is produced in the spectral range of 700-1000 nm, the wavelength of the stimulating radiation in the spectral range of 300-700 nm is successively changed, the dependence of the luminescent radiation intensity in the wavelength range of 400-2500 nm on the wavelength of the stimulating radiation is fixed.

In another case, the determination of the authenticity of a valuable document with the declared security marking was carried out as follows. They produce exciting radiation in the spectral range of 700-1000 nm, fix the level of luminescent radiation in the wavelength range of 400-2500 nm, produce stimulating radiation in the spectral range of 300-700 nm, change the power of stimulating radiation, and fix the dependence of the intensity of luminescent radiation on the intensity of stimulating radiation.

From the foregoing, the obvious advantages of the proposed invention, which are based on the use of a complex feature of authenticity. The complexity consists in a certain reaction of the claimed luminescent substance to a double optical effect, which is not inherent in publicly available materials known from the prior art, including the technical solution adopted for the prototype.

It is advisable to use the proposed protective marking in the event that some non-random information is applied to the protective marking, the safety of which must be ensured at least during the period of authentication, and as a maximum during the period of circulation of the product. It seems promising to apply protective information that is temporary in nature. Declared safety marking has this property. Thus, in the scope of the claimed combination of features, a technical result is achieved, namely, an increase in the level of security, the possibility of expert or machine authentication, the possibility of multiple verification of the authenticity of the product, eliminating the inadvertent detection of hidden information between verification cycles, is ensured. An additional advantage is the ability to apply and read hidden information, which is randomly generated, but appears and is read using double exposure directly in the process of machine control and, therefore, cannot be reproduced consciously.

The proposed technical solution is illustrated by specific examples.

Example 1

A valuable document in the form of a banknote, contains on the reverse side a colorless protective marking of a rectangular shape made by offset printing.

The security label contains 80% binder, and 20% inorganic luminescent compound with an average particle size of 3 μm, with the following formula:

When processing areas of protective markings with exciting laser radiation of 975 nm, the initial Stokes luminescence intensity of ytterbium ions (Yb ₃₊ ) in the spectral range of 990-1100 and erbium ions (Er ₃₊ ) in the spectral ranges of 540-660 nm (anti-stokes luminescence) is instrumentally measured and recorded ) and 1500-1600 nm (Stokes luminescence).

When the protective marking areas are exposed to modulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, while the dependence of the Stokes luminescence intensity of ions (Yb ₃₊ , Er ₃₊ ) is also measured, depending on the intensity of the stimulating radiation.

In this case, the spectral composition of the luminescent study is estimated, since only the intensity of the spectral bands of luminescence changes, and not its spectral composition.

After removing the stimulating radiation, the luminescence intensity is restored.

Thus, the totality of the measured parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the stimulating radiation, inherent only for this chemical compound, is instrumental measured and, based on the results obtained, establish the authenticity of the document.

Example 2

A valuable document in the form of an excise stamp contains on the front side a transparent protective marking of a rectangular shape made by screen printing.

The protective marking contains 90% of a binder and 10% of an inorganic luminescent compound in the form of particles with an average size of 10 μm of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation in the range of 805 nm, the Stokes luminescence of Nd ₃₊ ions is observed in the spectral range of 1060–1370 nm, with a burning speed characterized by a time constant of 0.3 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective labeling parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the excitation, but also on the modulating radiation, as well as the change in the rate of rise and decay of luminescence, characteristic only for this substance, are instrumentally measured, and the authenticity is determined by the measurement results products.

Example 3

A valuable document in the form of an excise stamp contains on the front side a colorless protective marking of square shape, an area of 1 cm ² , made by offset printing.

The protective marking contains 85% of the binder and 15% of the inorganic luminescent compound in the form of particles with an average size of 2 μm of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation with a wavelength of 975 nm, the Stokes luminescence of Yb ₃₊ ions is observed in the range of 990-1100 nm, with a burning speed characterized by a time constant of 3 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

The magnitude of the change in the acceleration / attenuation rate of the luminescence band depending on the power of the applied stimulating radiation will be characteristic only for a given chemical substance.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective labeling parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of luminescence, which are characteristic only for a substance with the indicated chemical composition, are instrumentally measured, and according to the results measurements establish the authenticity of the product.

Example 4

A valuable document in the form of a banknote contains a protective marking in the composition of the paper base, located throughout the product area, made at the paper production stage.

The protective marking was introduced in an amount of 10% in the paper and is an inorganic luminescent compound in the form of particles with an average size of 20 microns of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation with a wavelength of 940 nm, the Stokes luminescence of Yb ₃₊ ions is observed in the range of 990-1100 nm, with a burning speed characterized by a time constant of 3 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

The magnitude of the change in the acceleration / attenuation rate of the luminescence band depending on the power of the applied stimulating radiation will be characteristic only for a given chemical substance.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective labeling parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, which is characteristic only for this chemical compound, are instrumentally measured and determined by the measurement results the authenticity of the product.

Example 5

Valuable document in the form of a banknote, contains on the back side a colorless protective marking in the form of a strip 2 cm wide, located along the short side of the banknote, made by strip introduction into a paper web at the stage of manufacturing a paper base.

The protective marking is introduced into the pulp in an amount of 10%, and is an inorganic luminescent compound with an average particle size of 15 μm, of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation with a wavelength of 975 nm, Stokes luminescence of Yb ₃₊ ions is observed in the range 990-1100 nm, with a Stokes luminescence acceleration rate characterized by a time constant of 3 ms, and Tm ₃₊ ions luminescence in the regions of 0.465- 0.495, 0.79-0.84 (anti-Stokes luminescence), and 1.65-1.98 μm (Stokes luminescence), with a Stokes luminescence acceleration rate characterized by a time constant of 3.5 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of acceleration and decay of luminescence correspond to predetermined values that are characteristic only for a given chemical substance.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 6

A valuable document in the form of an identity card contains on the front side a protective black marking in the form of a text block with personal data of the owner of the document, made by inkjet printing.

Protective labeling contains 95% binder and 5% inorganic luminescent compounds in the form of particles with an average size of 0.2 μm of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation with a wavelength of 940 nm, anti-Stokes luminescence of Ho ₃₊ ions is observed in the region of 0.54-0.56 μm, and Stokes luminescence of Yb ₃₊ and Ho ₃₊ ions is in the range of 0.96-1.12. 1.15-1.22 and 1.9-2.1 μm, with the Stokes luminescence ignition rates characteristic only for a given chemical compound.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 7

A valuable document in the form of a travel document, contains on the front side a colorless protective marking of a round shape with an area of 1.5 cm ² , made by the method of flexographic printing.

Protective labeling contains 80% binder and 20% inorganic luminescent compounds in the form of particles with an average size of 3 μm of the following composition:

In the treatment of parts of the security marking excitation pulsed laser radiation with a wavelength of 940 nm is observed Yb ₃₊ and Er ₃₊ ions Stokes luminescence in spectral regions 0.9-1.1 and 1.5-1.6 micrometers, respectively, at speeds buildup / decay Stokes luminescence characteristic only for compound with this chemical composition.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rate of increase and decay of the spectral bands of Stokes luminescence correspond to the specified values.

After removing the stimulating radiation, the intensity of the spectral bands of luminescence is restored, the speed of acceleration and attenuation of the spectral bands, characterized by a constant luminescence time, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 8

A valuable document in the form of a composite material token contains a protective marking in the base material introduced between the IR transparent layers of the multilayer carrier as a separate layer, and the concentration of the protective marking material in the bulk of the base of this layer is 10%.

The protective marking is made on the basis of an inorganic luminescent compound with an average particle size of 2.5 μm, of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation in the range of 940 nm, the Stokes luminescence of Yb ₃₊ ions is observed in the region of 0.99-1.1 μm, with a burning speed characterized by a time constant of 3.5 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range of 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured, while the rate of increase and decay of the luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 9

A valuable document in the form of a bank card, contains on the reverse side a metallized magnetic strip for storing special / official banking information, which includes protective marking, the concentration of which in the metallized layer is 5%.

The protective marking is based on an inorganic luminescent compound with an average particle size of 0.3 μm, of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation in the range of 975 nm, anti-Stokes luminescence of Yb ₃₊ and Er ₃₊ ions is observed in the regions 0.99-1.1 and 1.5-1.6 μm, respectively, with a Stokes luminescence acceleration rate of 5 ms for Yb _{3 +} and 3.5 ms for Er ₃₊ .

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 10

A valuable document in the form of an identity card on a plastic basis, contains between the layers transparent in the infrared range of the spectrum, as part of the adhesive layer, a protective marking for instrumental determination of the authenticity of the document.

The adhesive layer contains 80% of the base adhesive and 20% of an inorganic luminescent compound with an average particle size of 1 μm, of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation in the range of 980 nm, the Stokes luminescence of Yb ₃₊ ions is observed in the region of 0.99-1.1 μm, with a burning speed characterized by a time constant of 3.2 ms.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range of 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured, while the rate of increase and decay of the luminescence is measured, and the invariance of its spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Example 11

A valuable document in the form of an identity card contains on the front side a colorless protective marking of a rectangular shape, made by offset printing as a substrate for a photograph of the owner of the document.

Protective labeling contains 80% binder and 20% inorganic luminescent compounds with an average particle size of 5 microns of the following composition:

When processing areas of protective markings with exciting pulsed laser radiation with a wavelength of 805 nm, Stokes luminescence of Nd ₃₊ ions is observed in the regions of 0.86-0.95, 1.03-1.12, and 1.3-1.45 μm, with luminescence acceleration / decay rates that are characteristic only for this compound.

When exposed to protective marking areas with pulsed stimulating radiation in the spectral range of 300-700 nm, the change in the intensity of the indicated luminescence is instrumentally measured due to optical quenching, and at the same time, the rate of increase and decay of the luminescence bands is measured, and the invariance of their spectral composition is evaluated.

It is believed that the authenticity of the document is established if only the intensity of the spectral bands of luminescence has changed, and not its spectral composition, and at the same time, the rates of luminescence acceleration and decay correspond to predetermined values.

After removal of the stimulating radiation, the luminescence intensity is restored, the acceleration and decay rates of the spectral bands, characterized by the luminescence time constant, take their initial value.

The combination of the above protective marking parameters, including the luminescence spectrum, the dependence of the intensity of the spectral bands not only on the exciting, but also on the modulating radiation, as well as the change in the rate of rise and decay of the luminescence, are instrumentally measured, and the authenticity of the product is established from the measurement results.

Claims (21)

1. Protective labeling for instrument control of the authenticity of the product, made on the basis of composite crystalline inorganic luminescent compounds of rare earth and alkaline earth elements, characterized in that it has a chemical composition corresponding to the following empirical formula:

where Ln ₁ is one of the ions La ₃₊ , Gd ₃₊ , Y ₃₊ and / or any of their combinations; Ln ₂ is one of the ions Yb ₃₊ , Er ₃₊ , Nd ₃₊ , Ce ₃₊ , Tm ₃₊ , But ₃₊ and / or any of their combinations; Me ₁ is one of the ions Mg ₂₊ , Ca ₂₊ , Sr ₂₊ , Ba ₂₊ ; Me ₂ - one of the ions Ti ₄₊ , Zr ₄₊ , Si ₄₊ , Ge ₄₊ , Sn ₄₊ ; 0≤x≤0.60; 0.01≤y≤0.10; 0.005≤z≤0.05; 0≤n≤1; 0≤m≤1; n + m = 1, and the structure of the crystalline structure, which is characterized by a high concentration of associated nonradiative capture centers of free charge carriers formed around the luminescence centers, due to which the proposed marking has Stokes and / or anti-Stokes luminescence in the spectral range 400-2500 nm arising under the influence of exciting radiation lying in the spectral range of 700-1000 nm, and a change in the given law of the luminescence intensity without changing its spectral composition under the air Corollary stimulating radiation lying within the spectral range of 300-700 nm. 2. The protective marking according to claim 1, characterized in that the particle size of the inorganic luminescent compound is from 0.1 μm to 50 μm. 3. The protective marking according to claim 1, characterized in that the inorganic compound is introduced into the paint, transparent varnish, coating, printing binder, adhesive layer. 4. The protective marking according to claim 1, characterized in that the inorganic compound is introduced into the paper base, polymer base, rubber, metal layer, composite material. 5. The product is in the form of a valuable document containing the protective marking described in paragraphs. 1-4. 6. The product according to claim 5, characterized in that the protective marking is included in the base of the document, or applied as a layer on the surface of the base of the document, or applied as an adhesive layer between the inner layers of the multilayer product. 7. The product according to claim 5, characterized in that it consists of a banknote, excise stamp, postage stamp, passport, travel document, driver's license, identity card, security paper, plastic card, label, payment document. 8. The product according to claim 5, characterized in that the protective marking is made in the form of geometric figures, guilloche elements, graphic or alphanumeric characters. 9. The product according to claim 5, characterized in that the marking is colorless and indistinguishable in daylight.