CA2840322C - Method for marking an object with microdiamonds - Google Patents

Abstract

The invention relates to a method of marking an object. This method comprises the following steps: (a) Several fluorescent microdiamonds (10) are provided whose maximum dimension of each is less than 50 microns, (b) These microdiamonds (10) are distributed in a region (95) of this object ( 90) at positions, (c) These microdiamonds are fixed in this region (95).

Description

METHOD FOR MARKING AN OBJECT BY MICRODIAMENTS
The present invention relates to a method of marking an object.
In many situations, it is crucial to be able to that an object that has been manufactured is not an illegal copy of an object original.
In this description, "object" means any entity material having a mass, a surface and a volume.
A non-exhaustive list of such situations is:
¨ Counterfeiting of an object protected or not by a patent or patent application, by a design, by copyright, ¨ Counterfeiting an object whose mark is protected, ¨ Copy of an officer document, ¨ Copy of a bank note.
Current techniques for authenticating an original object include the engraving of a mark or a code on this object, the fixing on the object of a support bearing a hologram, the printing on this object of motives difficult to reproduce (eg watermarks) or invisible to the naked eye (eg printed with visible ink ultraviolet only), the weaving in this product of elements metallic (for example in banknotes).
However, more recently, the sophistication of the means of reproduction (printers, tools) makes it possible more and more easily counterfeiters and counterfeiters to make products that are totally identical to the originals.
The present invention aims to remedy these disadvantages.
The aim of the invention is to propose a method which makes it possible to mark a object so that it is extremely difficult, if not impossible, to reproduce this marking, an illegal copy or an infringement of that object, and that this marking is readable and identified by a device reading.
This goal is achieved by virtue of the fact that this method comprises the steps following:
(a) Several fluorescent microdiamonds are provided whose size maximum of each is less than 50 microns,

2 (b) These microdiamonds are distributed in a region of this object to positions, (c) These microdiamonds are fixed in this region.
Thanks to these provisions, the marking is invisible to the naked eye, and is therefore difficult to identify. In addition, microdiamonds can not be detected only through a microscope, and / or through a detector of fluorescence. So the global vision of the distribution in the region of the object carrying microdiamonds is inaccessible to a third party who is not equipped with such expensive equipment. Moreover, it will be practically impossible for a third party to reproduce on another object the distribution particular microdiamonds in this region, even assuming that a third party can obtain such microdiamonds.
Each original object is thus uniquely identifiable thanks to marking, and it is impossible or almost impossible to reproduce this marking on another object.
The invention also relates to a method of identifying a object.
According to the invention, this method comprises the following steps:
(a) Mark an object with fluorescent microdiamonds using the marking process according to the invention, (b) We read information about the distribution of these microdiamonds in this object using a detector once they are fixed in this object, (c) This information is stored so that this information can be subsequently be compared with information on the distribution of microdiamonds fixed in an object.
The invention also relates to an object that is marked with microdiamonds.
The invention will be well understood and its advantages will appear better, upon reading the following detailed description of an embodiment represented by way of non-limiting example. The description refers to attached drawings in which:
¨ Figure 1 is a view of an object in a region from which distributed microdiamonds by the method according to the invention,

3 ¨ Figure 2 is an enlarged view of region II of the object of the figure 1 schematically showing a distribution of microdiamonds in this region, ¨ Figure 3 is a map showing the intensities of fluorescence emitted by microdiamonds distributed in a region of an object by the method according to the invention.
By microdiamond is meant a diamond whose maximum dimension is less than 50 μm (1 μm = 1 micron = 10-6 μm). We hear by maximum dimension the length of the largest straight segment joining any two points of one of these diamonds.
A microdiamond is thus invisible to the naked eye. Indeed, the resolution maximum by the human eye is 1 minute arc (1 minute arc =
1/60 degree, where 90 degrees is a right angle), which corresponds to a maximum dimension for such a microdiamant of 50 μm at a distance of observation of 10 cm (centimeters).
Advantageously, the microdiamonds each have a dimension lower maximum, for example less than 1 micron. Their detection by a third party, for example a counterfeiter seeking to reproduce the marking according to the invention, which is not equipped with a detection device very sensitive is so impossible.
Even more advantageously, the microdiamonds each have a maximum dimension less than one hundred nanometers (1 nanometer = 10-9 m), or even less than ten nanometers. We speaks in this case of nanodiamonds.
The manufacture of such nanodiamonds is more difficult than that of microdiamonds larger than these nanodiamonds. Their detection is also more difficult because it requires a detection device yet more sensitive.
Several microdiamonds 10 are provided, and they are distributed in a region 95 of an object 90. For example, we place each of these microdiamonds 10 at a chosen position, so that microdiamonds 10 create a chosen pattern. Such an investment is in practice very complex to achieve because it involves the use of highly specialized and expensive tools (Atomic Force Microcoscope or AFM, optical forceps). So, the reproduction by a third party of this specific configuration of positions of microdiamonds would in practice be extremely difficult, if not impossible.

4 The term in the region means within the region or on the surface of the region.
Figure 1 shows an object 90 with a region 95 in which microdiamonds 10 are distributed. These microdiamonds 10 are visible in Figure 2 which is a magnification of this region 95 (Region II on the figure 1).
Advantageously, the microdiamonds 10 are positioned in the region 95 at random positions.
Such a random distribution is obtained for example by projecting the microdiamonds 10 in the region 95 of the object 90 using a device projection, in one operation or in several.
Any other means of randomly allocating microdiamonds 10 on object 90 can be used.
Thus, a distribution of microdiamonds 10 on an object 90 will be always distinct from a distribution of microdiamonds 10 on another object. This randomness makes it possible to clearly distinguish two objects.
This random distribution also has the advantage of being very easily achievable (using a projection device, as shown above), much more easily than an investment of each microdiamant 10 at a chosen position, and practically impossible to reproduce (see below).
Advantageously, the number of microdiamonds 10 is high in order to allow for a wider variety of distribution of rnicrodiamants. For example, this number of microdiamonds is at least equal to four.
The microdiamonds are then fixed in the region 95 so as to ensure durability of the marking according to the invention.
This fixation varies according to the nature of the object. For example, the microdiamonds 10 can be fixed in or on an element transparent which is itself incorporated on the surface or inside of the object 90 to form a part.
Thus, the microdiamonds 10 can be distributed in the region 95 then covered by a transparent element which is fixed on the object 90.
By transparent element, we mean an element through which fluorescence of a microdiamond is detectable.

WO 2012/17586

5 Alternatively, if the object 90 is partially or totally transparent, microdiamonds 10 can be incorporated in this part transparent object 90 at the time of manufacture of this object 90.
Advantageously, in the case where the region 95 comprises a volume 5 transparent, at least some of the microdiamonds 10 are distributed in three dimensions in this volume, not just on a surface in two dimensions.
Thus, these microdiamonds 10 are distributed in the thickness of the object 90 so that their fluorescence can be detected by means detection.
FIG. 3 is a map of the fluorescence intensity of each of the microdiamonds 10 with their positions in space in the region 95. For a given nnicrodiarner 10, this intensity is proportional to the height of the peak where this microdiamond is located 10.
Advantageously, the microdiamonds 10 are microdiamonds artificial because these diamonds have increased fluorescence. In effect, the fluorescence of a natural diamond is low, and the detection of this fluorescence requires a more sensitive detector. The use of artificial microdiamonds whose fluorescence is greater than that of Natural diamonds allows identification of objects easier.
The method according to the invention can be used to mark in particular any object, for example a product, a document, especially an official document such as a piece of identification, a bank note.
Advantageously, the process according to the invention is also can be used to mark drugs because microdiamonds are not not toxic to humans.
Microdiamonds 10 and their fluorescence property exhibit the advantage of being virtually unalterable and therefore last beyond the lifetime of the object 90 on which they are placed.
Microdiamonds 10 are invisible to the naked eye, so they do not affect not the external appearance of the object 90 if the region 95 is on the outside of the object 90.
The invention also relates to a method for identifying an object labeled with microdiamonds 10 according to the invention as described above.
above. For this, after the marking of an object, a piece of information

6 concerning the particular distribution of microdiamonds 10 in the region 95 of this object 90 is read through a detector. This information can to be stored, for example in a database.
This information may relate to the spatial distribution of microdiamonds 10, or can be directly this distribution.
In the latter case, the storage of this distribution is the storage of the position in the space of each of the microdiamonds 10, and one or several characteristics of these microdiamonds 10, as explained below.
below.
To observe the microdiamonds 10, and therefore their distribution in the region 95, it is advantageous to use a suitable fluorescence detector to detect the fluorescence of each microdiamant 10.
This distribution of microdiamonds 10 (obtained for example advantageously by random dispersion of microdiamonds in the region 95, as explained above) being particular, it is impossible to one-third to replicate this distribution. So, even assuming that a third can obtain such microdiamonds 10 and disperse them in a region of the copy of the original object, the very small size of each microdiamant 10 makes the individual displacement of each microdiamant 10 almost impossible. Reproduction on this copy of the subject of the microdiamonds 10 distribution on the original object is impossible.
It is therefore easy to identify if an object is an original object: if this object does not present microdiamonds 10, it is not an original object.
For some applications (for example the manufacture of a product cheap in mass production, like a pen), the mere absence of microdiamonds can identify a counterfeit item. It is not then necessary to store information on the distribution of microdiamonds on these objects. Indeed, it would not be profitable for a counterfeiter to acquire microdiamonds and integrate them into the production line of the product.
In other applications, if microdiamonds are present in this object, we compare their distribution with each of the distributions stored in the database. If this distribution is not one of the distributions stored in the database, then this object is not a original object.

7 Advantageously, one superimposes (for example numerically) on the region 95 where are the microdiamonds 10 a reading grid that does not holds that localized information in spatial coordinates chosen in advance (the reading grid does not retain the distribution of microdiamonds 10 only in certain positions). Thus, we add a coding additional to the only random distribution, since a counterfeiter should also know the reading grid used. The use of a reading grid also helps to reduce the amount of information store in the database.
Advantageously, the microdiamonds 10 which are distributed in the object 90 comprise at least two groups, the microdiamonds 10 of one of the groups having a fluorescence color different from the fluorescence color of the microdiamonds 10 of the other group.
For example, as observed by the inventors, in the case where fluorescence centers of a microdiamond are the centers called NV, obtained by the association of an interstitial nitrogen atom and a gap in carbon in the microdiamond lattice, the fluorescence takes place at 700 nm (nanometers), which corresponds to a certain color. If the atom interstitial is nickel, the fluorescence takes place at 800 nm, which corresponds to to a different color.
Thus, we obtain a greater variety of possible markings of an object by the method according to the invention. In addition, the reproduction of these tagging by a potential counterfeiter is even more difficult.
Advantageously, the microdiamonds 10 which are distributed in object 90 comprise at least two groups, the microdiamonds of one groups with different fluorescence intensity than the the fluorescence intensity of the microdiamonds 10 of the other group.
Thus, we obtain a greater variety of possible markings of an object by the method according to the invention. In addition, the reproduction of these tagging by a potential counterfeiter is even more difficult.
Figure 3 shows the distribution in region 95 of an object 90 of microdiamonds 10 and the fluorescence intensity of each of these microdiamonds 10. For a given microdiamant 10, this intensity is proportional to the height of the peak where this microdiamond is located 10.

8 In combination, the microdiamonds 10 can present both fluorescence colors and different fluorescence intensities.
In a variant, the process according to the invention is modified as follows:
An object 90 is labeled with fluorescent microdiamonds 10 in using the process according to the invention, and then the distribution of these microdiamonds 10 (or information on the distribution of these microdiamonds) on this object 90 using a spin detector once that they are fixed in this object 90.
This distribution is stored in such a way that this distribution and spins microdiamonds (or information concerning this distribution and the spins of microdiamonds) can later be compared with a distribution and spins microdiamonds (or information concerning this distribution and the spins of microdiamonds) microdiamonds fixed on an object.
Indeed, spin is a quantum information that characterizes by example each center NV (association of an interstitial nitrogen atom and a carbon gap) fluorescent microdiamonds. So he is possible to give each microdiamond a specific global spin.
Thus, microdiamonds 10 dispersed on an object 90 provide a spin mapping that will be specific to this dispersion. Given spin is a quantity that can not be affected and read, so known, that by a very particular and expensive quantum apparatus, the reproduction of a given microdiamond dispersion on an object by a counterfeiter is virtually impossible.
The present invention also relates to an object 90 which is labeled with fluorescent microdiamonds using the method of marking described above.

Claims (12)

1. A method of marking an object (90) characterized in that includes the following steps:
(a) Several fluorescent microdiamonds (10) are supplied whose maximum dimension of each is less than 50 microns, (b) distributing said microdiamonds (10) in a region (95) of said object (90) at positions, (c) fixing said microdiamonds in said region (95). 2. Method of marking an object (90) according to claim 1, characterized in that at least some of said positions are random. Method for marking an object (90) according to claim 1 or 2, characterized in that said region (95) comprises a volume and at least some of the microdiamonds (10) are distributed in three dimensions in this volume. 4. A method of marking an object (90) according to any one Claims 1 to 3, characterized in that said microdiamonds (10) which are distributed in said object (90) comprise at least two groups, the microdiamonds (10) of one of the groups with a fluorescence color different from the fluorescence color of the microdiamonds (10) from the other group. A method of marking an object (90) according to any one of Claims 1 to 4, characterized in that microdiamonds (10) which are distributed in said object (90) comprise at least two groups, the microdiamonds (10) of one of the groups having a fluorescence different from fluorescence intensity of microdiamonds (10) of the other group. 6. A method of marking an object according to any one of Claims 1 to 5, characterized in that said microdiamonds (10) have each a maximum dimension that is less than 100 nanometers. 7. A method of marking an object according to claim 6, characterized in that said microdiamonds (10) each have a maximum dimension that is less than 10 nanometers. 8. A method of identifying an object (90) characterized in that includes the following steps:

(a) said object (90) is marked with fluorescent microdiamonds (10) using the marking method according to any one of preceding claims, (b) One reads information relating to the distribution of said microdiamonds (10) into said object (90) using a detector once they are fixed in said object (90), (c) storing said information such that said information can be compared later with information relating to the distribution of microdiamonds (10) fixed in an object. 9. Process identification of an object according to claim 8 characterized in that, in step (b), said information is read using a fluorescence detector which detects the fluorescence of said microdiamonds (10). 10. A method of identifying an object according to claim 8 or 9 characterized in that said information is the distribution of said microdiamonds (10). 11. A method of identifying an object according to claim 10 characterized in that, in step (b), a reading grid is used which retains the distribution of said microdiamonds (10) in certain positions. 12. Object (90) characterized in that it is marked with microdiamonds (10) fluorescent using the marking method according to any of claims 1 to 7.