X-ray diffraction and fluorescence

An instrument capable of both X-ray diffraction, XRD, and X-ray fluorescence measurements, XRF, arranges an X-ray source 10 creating an incident X-ray beam directed to a sample on a sample stage. An X-ray detection system is mounted at a fixed angle 2θ for high energy energy dispersive XRD For XRF, an X-ray detection system is used.

FIELD OF INVENTION

The invention relates to an apparatus for both energy dispersive X-ray diffraction and X-ray fluorescence, and methods of operating the apparatus.

RELATED ART

X-ray diffraction (XRD) and X-ray fluorescence (XRF) are two well known ways of probing the structure and the elementary composion of samples. Generally, instruments are designed to carry out either one or the other method.

However, in some applications, instruments have been proposed that carry out both X-ray diffraction and X-ray fluorescence.

For example, U.S. Pat. No. 5,745,543 proposes an instrument that aims to overcome problems of low X-ray power arriving at the XRF detector by using a line-focus source, which enables XRD measurements, a plane or cylindrical analysis crystal together with a position-sensitive detector in the fluorescence measurement section. Thus no collimating system, which reduces the intensity, is used.

Another proposal is made by WO2008/107108 which includes a useful discussion of the difficulties that may be experienced when trying to combine XRD and XRF. In particular, the discussion highlights the difficulty of arranging an X-ray detector so that it can be moved over a wide angle range for XRD as well as being close to the sample for XRF. The intensity/sensitivity of each technique is optimised using a specific source for each.

Accordingly, there remains a need for smaller equipment with all, some or none of the following characteristics, in particular being easier to use, usable both for XRD and XRF, and which may be incorporated, for example, in production lines, manufacturing plants, and research institutions such as universities without incurring complex sample handling of more conventional designs.

SUMMARY OF INVENTION

The inventors have realised that the use of energy dispersive XRD is uniquely suitable for combination with XRF, and hence in a combined instrument which carries out both XRD and XRF.

Preferably, the range of energies used include high energy X-rays above 10 keV and preferably above 20 keV. The use of high energy energy dispersive (HEED) XRD is especially suitable as it allows good particle statistics. This can be done by using the continuum radiation of an XRF tube for XRD, rather than the characteristic lines of such a tube used for XRF. The characteristic lines suitable for XRF may be in the range of just below 3 keV (enhancing low Z number elements) and around 20 keV (enhancing the mid range elements). Using L-lines of 2.6 keV (eg Rh L-line) for XRD results in very poor penetration depth and thus poor particle statistics. Using instead the continuum radiation of such tube for diffraction allows the measurement in a suitable range of energy depending on the matrix of the sample.

DETAILED DESCRIPTION

Referring toFIG. 1, apparatus according to the invention includes a housing2which may be evacuated or gas filled (He) in case of wet/liquid sample, and a sample holder4for mounting a sample. The sample holder may be adapted for holding a particular kind of sample, in the example cement. The sample holder4extends laterally in a direction that will be referred to as the sample plane6indicated by dotted lines.

An X-ray source10is provided on one side of the sample plane in line with a beam conditioner system12for collimating the X-rays to form an X-ray beam in incident X-ray direction16. The X-ray source10is a source of both white X-rays, i.e. X-rays at a range of wavelengths, and characteristic lines. Further details will be discussed below. The X-ray source is mounted on an X-ray port14in the housing, which will be referred to as the X-ray source port14since it is for the purpose of mounting the X-ray source.

An X-ray port20is provided at a2θ angle, in this example on the opposite side of the sample plane to the X-ray source for mounting an X-ray detection system22. This X-ray detection system22is intended for energy dispersive X-ray diffraction measurement, so the X-ray port will be referred to as the XRD port20and the X-ray detection system as the XRD detection system22. A beam conditioner system24to collimate the beams is provided in front of the XRD port20in order to get a beam to the XRD detection system22.

In typical X-ray diffraction, the intensity of diffracted X-rays, which have the same energy as the incident X-rays, is measured as a function of angle2θ to determine the structure of the sample. The relationship between the angle2θ, the length scale d being probed and the wavelength λ is given by the well known Bragg equation nλ=2 d sin θ.

In contrast, in energy dispersive (ED) X-ray diffraction, a fixed angle2θ is used, and the variable is energy. Using the relation between energy and wavelength λ=hc/E combined with Bragg law Energy dispersive diffraction can be done. Thus, instead of keeping the wavelength λ fixed and varying2θ, the angle2θ is fixed and the wavelength λ varied, by measuring at a number of energies. Accordingly, the XRD detection system22is an energy-dispersive detector in the most simple design.

This approach is very unusual indeed, especially in high accuracy applications, but has been proposed for the purpose of explosives detection by G. Harding, “X-ray scatter tomography for explosives detection”, Radiation Physics and Chemistry volume 71 (2004) pages 869 to 881.

The inventors have realised that this very unusual approach to XRD is particularly suitable for combining with XRF applications.

A further port30is provided for mounting a further detection system32, in this case for XRF, so the port will be referred to as XRF port30and the detection system32as XRF detection system32. The port30is on the same side of the sample plane6as the source port14. The XRF port can be chosen to be located for transmission or reflection. The use of transmission is useful for high atomic number elements. However, for lower atomic number elements, the XRF port will be located on the same side of the sample plane6as the source port14, as shown.

The XRF measurement will be explained in less detail than the XRD measurement, since the XRF measurement is relatively conventional. It is the ED XRD measurement that is highly unusual.

As will be appreciated from the above description, the source must be a source of X-rays at multiple energies. For the energy-dispersive XRD, “white” X-ray radiation is needed, i.e. X-ray radiation in a continuous spectrum, in contrast to typical tubes for XRD which may use highly monochromatic X-rays (for example from the characteristic lines), or a monochromator to produce such monochromatic X-rays. Thus, if only XRD is considered, the X-ray source10for energy dispersive XRD would preferably use a metal target for an electron beam where the metal target18is of a metal of a high atomic number for example as the intensity of the continuum increases with the atomic number of the target. Suitable targets include materials like Ta, W, . . . Au.

However, the requirements for XRF are different. For XRF, it is preferred to use a source with discrete lines, and typically a metal target18made of a material chosen to give characteristic lines to enhance low Z-elements as well as the mid range elements. Materials like Mo, Rh, . . . Ag give characteristic lines in the low energy range as well as in the range of 20 keV. As those materials have already a rather high atomic number they are also suitable to use their white radiation for ED XRD. Choosing the right2θ angle interference with the characteristic lines and diffraction lines can be avoided.

Thus, in the apparatus according to the embodiment, materials with atomic numbers from 42 to 46, such as Mo, Rh or Ag are particularly preferred.

Ultimately, an advantage of the invention is that it does not require a goniometer or moving parts, simply one X-ray source and two X-ray detectors mounted to ports in fixed locations. This results in an X-ray device capable of both XRD and XRF at modest cost.

The apparatus may be tailored to particular samples, especially in particular industries. For example, for the cement industry, the amount of free lime may need to be measured and this has a peak corresponding to a particular value of d. Thus, the exact fixed angle2θ in a given instrument will depend on the intended sample, and hence the value of d, but typical angles2θ in the range 5° to 12° or even 20° are generally preferred. Bragg's law nλ=2 d sin θ gives suitable values of θ and hence2θ when the energy range is known, and hence the range of energy (rather than wavelength λ) is also known.

For the measurement of pharmaceutical samples, however, the length scale d may be much larger and in this case2θ needs to be smaller. Accordingly, for the measurement of such samples, a range of angles2θ in the range 0.1° to 5° is preferred. Thus, overall, values of2θ may be from 0.1° to 20°, and preferably in one of the narrower ranges 5° to 12° or 0.1° to 5°, preferably 0.1° to 1°, depending on the intended application.

In use, a sample is mounted on the sample stage, X-rays are directed onto the sample, and the X-ray spectra measured by both the XRD detection system22and the XRF detection system32.

In an example, a sample of cement was measured, the sample having a thickness between 3 mm and 4 mm. The angle2θ was 10.1° in the example.FIG. 2illustrates the results from the XRD detector with various energies. The peak of most interest for testing cement is the free lime peak of d=0.245 nm, (thus at 28 keV with 2θ=10.1 degree), which is clearly visible and marked. It will be seen that good XRD results can be achieved even in this highly unusual configuration.

The detection systems may typically be energy dispersive systems as described above. In such approaches, the apparatus can have no moving parts, and in particular no goniometer.

However, in alternative embodiments the detection system may comprises a wavelength dispersive element, such as a crystal, a goniometer and a conventional X-ray detector. These may be combined in an integrated detection system that may be mounted on the appropriate port.

In an alternative, the goniometer may be omitted, and a single position insensitive detector used.

Another approach uses a position sensitive detector in combination with such a wavelength dispersive element, so that the detection system measures X-ray intensity as a function of energy using the combination.

The embodiment described above includes a single XRD port and a single XRF port. Note however that the housing may have further ports, to allow the XRD and XRF detection systems to be moved to different angles, or to allow multiple measurements simultaneously. In particular, there may be advantages in having multiple XRF detection systems to simultaneously measure XRF radiation at different energy ranges. In some cases, some of these XRF ports may be mounted on the opposite side of the sample plane to the X-ray source, i.e. on the same side as the XRD port.

Further, embodiments may have a pair of XRD ports, or more. For example, there may be one XRD port at an angle2θ in the range 5° to 12° and one in the range 0.1° to 5° for the different applications as described above.

Further, the embodiment above is described with the X-ray source and detection systems fixed on the ports. However, the instrument may in some cases be supplied with the source and detectors absent, with simply the bare ports.