This application is a national stage under 35 U.S.C. 371 of International Application PCT/GB2015/050787, filed on Mar. 18, 2015 (currently published). International Application PCT/GB2015/050787 cites the priority of British Patent Application No. 1406707.8, filed Apr. 15, 2014.
This invention relates to a method for analysing a liquid when inside a container, where the container is at least partially transparent to visible light. The method can be applied to many fields, but finds particular use in the detection of counterfeit or adulterated alcoholic beverages, for example whisky.
Estimates for the revenue and taxation losses to industry and government arising from the counterfeiting of Scotch whisky are of necessity inexact, but are certainly of sufficient scale to make authentication a high priority. A number of techniques have been used in attempts to discriminate real from fake whiskies and to detect the watering down of authentic brands. These include:
To date, however, it has not been possible to provide a portable instrument capable of “in the field” testing with high reliability without breaking the seal of the container to remove a sample for analysis (for example, opening the bottle of whisky being analysed). The industry standard technology for authentication remains gas chromatography carried out in a central analytical laboratory.
This invention seeks to address this problem through the use of optical spectroscopy in transmission, rather than in reflectance, mode to provide the basis for an “in the bottle” and “in the field” screening test, for example as a screening test for the authenticity of whisky and other high value liquors.
This invention relates to method for analysing a liquid when inside a container in order to detect counterfeiting or adulteration of the liquid, the container being at least partially transparent to visible light, the method comprising the steps of:
An important advantage of the method of the present invention is that it allows the liquid inside a container to be analysed without the container needing to be opened. This is particularly important when analysing alcoholic beverages in bottles because, once opened, these products cannot be sold. In some embodiments, the container is sealed (eg it is closed).
In the context of this invention, the term “adulteration” is used to mean the addition of a foreign substance to the liquid being tested. An example of adulteration is the addition of water to the liquid, for example to a whisky. Also in the context of this invention, the term “counterfeit” is used to refer to a liquid which is presented (for example, for sale) as being something other than what it actually is. Examples of counterfeiting include misrepresenting a blended whisky as a malt whisky, or misrepresenting a mixture of ethanol and a caramel colourant as a whisky. In some embodiments, the first and second spectra are selected such that they are suitable for detecting a suspected type of adulteration or counterfeiting. The term “area of overlap” is used to mean the parts of the wavelength range of the first and second spectra which overlap. In step (c), calculating the ratio of the first and second spectra preferably comprises calculating the ratio (R(λ)) of the first and second spectral intensities at each wavelength in the area of overlap.
Preferably, the container comprises glass or plastic.
It is preferred that the liquid comprises alcohol (preferably ethanol), preferably that it is an alcoholic (preferably ethanolic) beverage. The alcoholic beverage may comprise one or more of the following: vodka, gin, cognac, brandy, bitters, rum, tequila, whisky or wine. However, the method of this invention is applicable to non-alcoholic beverages, as well as to other alcoholic beverages. Preferably, the alcoholic beverage is a coloured alcoholic beverage (ie it is not clear). Preferred coloured alcoholic beverages include cognac, brandy, bitters, dark rum, tequila, whisky and wine.
The term “spectrum” is used to refer to measurements at at least two different wavelengths. In general, in order to obtain the best possible data from the method of the invention it is preferable to obtain a spectrum comprising as many readings as possible across as broad a wavelength range as possible. However, it is possible to distinguish adulterated/counterfeit from unadulterated/non-counterfeit liquids with fewer readings and using narrower wavelength ranges. Once the skilled person is aware of how to detect a particular type of counterfeiting and/or adulteration using the method of the invention, determining the number of readings and the wavelength range required to detect that type of adulteration/counterfeiting of a particular liquid would be a matter of routine experimentation.
In some embodiments, the first and/or second spectra include measurements made across the wavelength range 350-500 nm. Preferably, the first and/or second spectra include measurements made across the wavelength range of 300-600 nm, more preferably 300-750 nm, even more preferably 300-850 nm. Preferably, the wavelength range of the first and second spectra is substantially identical.
Preferably, the transmission spectrum is measured using a light source, more preferably a white light source (ie comprising a mixture of wavelengths in the visible range). In some embodiments, the white light source is a halogen lamp. Preferably, the transmission spectrum is measured using a light source comprising one or more optical fibres.
The reference measurement may be stored electronically (for example on a hard disk), and may be stored either locally (eg with respect to the place of the first and second spectral measurements, such as within the spectrometer being used to make the measurements) or accessed remotely (eg from a remote server).
This invention will be further described by reference to the following Figures which are not intended to limit the scope of the invention claimed, in which:
A detailed description of one embodiment of the method of this invention is set out below.
A broad-band optical source (for example one or more optical fibres connected to a halogen light source) with an intensity I(λ) dλ photons·cm−2·s−1 in the wavelength interval λ, λ+dλ is used to illuminate an at least partially transparent (normally glass or plastic) bottle through a small contact aperture of area dλ. Contact with the bottle on the entrance (ie of light from the source) and exit (ie of light from the bottle to the detector) surfaces may be conveniently established using one or more (ie single or bundled) optical fibres. The optical fibres are mounted so as to exclude ambient light.
A bottle (ie a container) containing a liquid for analysis according to the method of the invention is shown in
If transmission measurements are made for two orientations of the bottle (ie two different source-detector axes, through the at least partially transparent parts of the bottle), as indicated in
Ts(λ)=tglass(λ)·twhisky(λ,ds)·Q(λ)·I(λ)dA+Nd (1a)
and
Tl(λ)=tglass(λ)·twhisky(λ,dl)·Q(λ)·I(λ)dA+Nd (1b)
where ds and dl are, respectively, the lengths of the shorter and the longer of two optical paths through the bottle. In the above equation, tglass(λ) is the optical absorbance of the glass bottle, twhisky(λ,ds) is the optical absorbance of the whisky through the shorter optical path through the bottle and twhisky(λ,dl) is the optical absorbance of the whisky through the longer optical path through the bottle. Q(λ) denotes the optical quantum efficiency (counts per incident photon) of the spectrometer which detects the transmitted flux, combining both detector and wavelength-dispersive element (ie grating) contributions.
If the walls of the bottle are effectively of constant thickness and/or very highly transparent, the terms describing the glass transmission can effectively be “divided out”. Then, provided the signal level in both orientations is much greater than the background count rate Nd, the ratio:
R(λ)=Ts/Tl (2)
is a property of the bottle geometry (ds and dl) and of the whisky's optical absorbance only. According to Mackenzie and Aylott (Analyst 129 (2004) 607-612), whisky is very strongly absorbing in the ultraviolet band 200-400 nm, with absorbances exceeding 50%, even for path lengths as small as 1 mm. Thus, we can anticipate that, for a given bottle geometry, there will be a minimum working wavelength below which eq. (2) will become the uninformative division of one background count rate by another. This can be determined by the skilled person using routine experimentation on the sample being tested.
Although the ratio R(λ) above can be measured without knowing the geometry of the bottle, a knowledge of the bottle geometry—described by the lengths ds and dl—allows the estimation of the wavelength-dependent linear attenuation coefficient μ(λ)—a property of the whisky in isolation;
Equations (2) and (3) are the basis for a comparative, rather than an analytical technique. The measurements obtained are compared to a database of known whisky “signature” measurements for R(λ) and/or μ(λ).
The variance S:
is used to quantify the difference between unknown (R) and reference (RO) spectra. N is the number of measurements made. Table 1 below shows values of S calculated for N=594 points equally spaced between wavelength limits 400 nm and 600 nm.
An extensive sample set of whiskies was provided by the Scotch Whisky Research Institute (SWRI). This was supplemented by dilution and other trials on commercially-sourced blends and malts. The distinctive “signature” produced from “long” and “short” optical spectra measured after transmission of a quasi white light input source through two distinct liquid path lengths (dl and ds, respectively) can be used to discriminate between “real” and “fake” material. This can also form the basis for a comparative (rather than analytical) field-deployable instrument.
The samples were analysed in all the examples below using a medium-performance portable spectrometer. For this analysis, a Hamamatsu type C10082CA Mini-Spectrometer based on a one dimensional, back-thinned, 2048-pixel CCD (charge coupled device) which was capable of providing better than 6 nm wavelength resolution in the 200-800 nm band (actually 164-845 nm) from a holographic grating ruled in quartz was used. The manufacturer's software was used to acquire all data. The spectral accumulation times were typically in the range 0.1-1 s. The roll-off in sensitivity at both the upper and lower limits of the bandpass was determined by the CCD, operating uncooled. The manufacturer's claimed temperature dependence of wavelength (0.04 nm/° C.) would provide excellent operational stability in a “field-portable” embodiment.
The 2048 channels of the Type C10082CA detector oversample the grating response by a factor:
˜6 nm/[600 nm/2048]
or about 20 times. If added precision is required, therefore, binning-up pixels is an available tool, together with the co-adding of many individual spectra at full resolution. The data reported below consists mainly of individual 0.2 s spectra, smoothed by a “top-hat” or “box-car” filter 7 pixels (˜2.3 nm) wide. The source of illumination used was a conventional halogen source with an effective temperature of 3100K and single optical fibres.
An initial series of measurements were made on a standard half-bottle (ie 350 ml) of supermarket own-brand blended whisky. The short axis (i.e. front-to-back of the bottle) path length was (43±1) mm and the long axis (i.e. side-to-side) path length was (87±1) mm
The integration time for each spectrum was adjusted appropriately in the range 0.05-0.2 s in order to avoid saturation of the detected signals in the mid-range of wavelengths. While the “Light Source” spectrum ((1) above) and the “Glass only” transmission spectrum ((2) above) both extend down to 350 nm, the very high blue/UV absorption of the whisky itself suppresses values of R between 350 and 425 nm unless the background levels in the long and short axes are accounted for. In
The left-hand axis of
In
The effects of successive dilution of an own-brand blend with distilled water were investigated using the background correction method described above involving averaging the first few detector pixels to give an estimate of Nd. Three samples were analysed (ie measuring “short” and “long” spectra to enable calculation of the ratio R(λ)) across the wavelength range 425-575 nm and the results are shown in
The data in
To confirm that the peak in the spectral ratio in
According to the formulation of equation (2) a perfectly transparent medium should give a ratio value of unity, independent of wavelength. This ideal is approached for air-containing bottle of
A further sample set was analysed using the same method (ie measuring “short” and “long” spectra to enable calculation of the ratio R(λ)). The compositions of this reference sample set are shown in Table 1 below. The reference set consisted of a number of Blends (labelled A, C, F and G), a Single Malt (labelled H) and approximations to them based largely on “neutral spirit” (i.e. an ethanol-water mixture) plus various additives, in particular the E150 family of caramels. The results of measurements on a subset of samples are shown in
The degree of variability between the samples was tested. Variability could be due to (a) batch-to-batch variation in the production process or (b) non-reproducibility in the measurement process, for the authentic product.
As shown in Table 1 above, the difference in the parameter S between any one of the Blend C samples and the average for that population is less than ˜0.1, with the exceptional value of 0.37 recorded for sample C(2). On that basis, every one of the eight counterfeit attempts except one—Sample 10, for which S equals 0.38—would be clearly classified as fake, and even Sample 10 would be flagged as lying right at the limit of the known variability of the authentic product.
Number | Date | Country | Kind |
---|---|---|---|
1406707.8 | Apr 2014 | GB | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/GB2015/050787 | 3/18/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/159043 | 10/22/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5753511 | Selinfreund | May 1998 | A |
7840360 | Micheels et al. | Nov 2010 | B1 |
20010055115 | Garver | Dec 2001 | A1 |
20040000653 | Nordlund | Jan 2004 | A1 |
20080218733 | Benes | Sep 2008 | A1 |
20110184681 | Augustine et al. | Jul 2011 | A1 |
Number | Date | Country |
---|---|---|
101256143 | Sep 2008 | CN |
103645144 | Mar 2014 | CN |
2071320 | Jun 2009 | EP |
2297377 | Jul 1996 | GB |
0233404 | Apr 2002 | WO |
2014138136 | Sep 2014 | WO |
Entry |
---|
Pisani, Francesca “International Search Report and Written Opinion—International Application No. PCT/GB2015/050787” May 18, 2015; European Patent Office as ISA; pp. 1-9. |
Number | Date | Country | |
---|---|---|---|
20170030881 A1 | Feb 2017 | US |