Patent Number: 056339089
Section: summary

The present invention relates to a portable micro-X-ray spectrometer, in particular to the measuring element located in the spectrometer by means of which the contents of elements on the surface of a specimen are measured and which is based on capillary optics and on a detector made by means of planar processing technics. Capillary optics have for instance been described in the Article Attaelmanan A. et al., Rev. Sci. Instrum. 65 (1), 1994. Capillary optics are based on a capillary tube through which the radiation is directed towards the object which is to be examined. Thanks to the capillary tube, the radiation is propagated substantially in a rectilinear and concentrated way, it being possible to direct the intensity of the radiation in its entirety towards the object to be examined. A detector made by planar processing technics may either be based on a diode made with high-resistive silicium or on a drift chamber. Diodes made with high-resistive silicon have for instance been described in the article Kemmer J., Nucl. Instr. and Meth. A169, (1980) p.499. Regarding drift chambers the article Rehak P. et al., Nucl. Instr. and Meth. A235 (1985) p. 224 and the article Chen W. et al., Nucl. Instr. and Meth. A326 (1993) p. 273 have been published, which describe a large drift chamber with a hole placed in an ion beam source which is sensitive in regard of space requirements. In a detector made by planar processing technics, the X-rays, which are natural for elements, from the elements in the object to be examined can be separated and identified also at room temperature, it not being necessary to put the detector into a low-temperature state, for instance surrounded by liquid nitrogen. The object of the present invention is to utilize the present level of technology to make it possible to make a portable X-ray spectrometer utilizing a detector made by means of capillary optics and planar processing technics, by which means it is to be possible to determine the contents of the elements on the surface of the specimen to be examined by means of an X-ray pulse. The essential characteristics of the invention are set forth in the appended claims. The main components of a measuring element in a portable X-ray spectrometer according to the invention are radiation source, capillary optics focusing the X-rays and an energy-dispersive detector made of semiconductor material. The radiation generated by the radiation source, which advantageously for instance may be an isotope source or an X-ray tube, is conducted to at least one capillary tube mounted in the immediate vicinity of the radiation source. The capillary tube is advantageously designed in such a way that the space in the tube decreases in the direction of propagation of the radiation by which means the radiation is focused and substantially the entire intensity of the radiation can be conducted towards the surface of the object to be examined. The radiation is conducted from the capillary tube through a hole in the detector, the radiation being directed towards the piece which is placed before the detector and which is to be examined. The atoms on the surface of the device to be examined then emit fluorescent X-rays which are characteristic for the kind of atom in question. The intensity of the generated fluorescent X-rays is measured by the detector, which can distinguish between the fluorescent radiation of the different elements by means of its energy-dispersive capability. The detector is furthermore connected to a multichannel analyzer which performs the identification of the elements. In a device according to the invention capillary tubes advantageously are used both as wave guides for the radiation and as focusing optics. By these means a microscopically thin X-ray beam can be obtained which has a high intensity. According to the invention the diameter of the capillary tube used is between 20-200, preferably 50-100 micron at the end closest to the radiation source. The capillary tube is shaped in such a way that the diameter of the capillary tube, seen from the radiation source, is smaller at the opposite end than at the end closest to the radiation source. The inner surface of the tube is advantageously at least partly conical. By these means the intensity of the radiation which is propagated in the capillary tube can be focused on an successively diminishing area by which means the usefulness of the intensity can be further increased. In a device according to the invention the capillary tube is, as seen from the detector, placed in such a way that the capillary tube is mounted in a hole substantially in the center of the detector. Depending on the diameter of the capillary tube, the diameter of the hole is between 50-200, preferably 80-140 microns. Thanks to the focusing of the capillary tube the radiation from the tube advantageously passes through the hole and does not essentially hit the detector. In a device according to the invention a configuration comprising several capillary tubes can also be used. In this case a hole is made in the detector for each capillary tube which goes through the detector. In a device according to the invention advantageously a detector made of high-resistive silicon is used, such as a diode or a drift chamber. This kind of detector gives a substantially good energy-dispersion with a Peltier cooler. The cooling devices of the detector thus can be made more simple than they for instance would be if liquid nitrogen in accordance with the prior art were used. In accordance with the invention the detector advantageously functions in the temperature range -30.degree. C.-30.degree. C. Thanks to the simple design of the cooling device, the specimen to be examined can be placed very close to the detector. When the device according to the invention is used the focused X-rays are conducted to the specimen to be examined, which is situated very close, by means of the capillary tube mounted in the hole made in the detector. The X-rays impinging on the surface of the specimen then cause fluorescent X-rays which are characteristic for the elements on the surface, a substantial part thereof being directed towards the detector. The detector receives a large part of the generated fluorescent X-rays, since the specimen is located very close to the detector. The results of the measurements will also be more reliable since the amount of radiation arriving at the detector increases. The location of the specimen very close to the detector means that the size of the entire X-ray spectrometer can be made very small, which improves the functionality of the device as a portable device.