Patent Number: 061635901
Section: claims

1. A sample cell for use in x-ray imaging, including structure defining a chamber for a sample, and mounted to said structure, a body of a substance excitable by an appropriate incident beam to generate x-ray radiation, the cell being arranged so that, in use, at least a portion of the x-ray radiation traverses said chamber to irradiate the sample therein and thereafter exits the structure for detection. 2. A sample cell according to claim 1 wherein said cell is an integral self-contained unit adapted and dimensioned to be inserted in complementary holder means of an electron microscope or microprobe at a position where the electron beam of the microscope is focused on said body of excitable substance, and thereby provides said incident beam for exciting said substance to generate x-ray radiation. 3. A sample cell according to claim 1 wherein said substance is excitable by an incident focused beam of electromagnetic radiation to generate x-ray radiation. 4. A sample cell according to claim 1, wherein said cell is an array of layers, of dimensions parallel to the plane of the layers in the range of about 1 micron to 10 millimeters. 5. A sample cell according to claim 4 adapted for use in phase contrast imaging, wherein said layers through which the excited x-ray radiation passes are highly homogeneous and have very smooth surfaces for preserving high spatial coherence of the incident beam in the radiation that irradiates the sample, and thereby optimizing useful contrast in the image. 6. A sample cell according to claim 1 wherein said body of excitable substance is a layer of the substance applied to the structure defining the cell. 7. A sample cell according to claim 6 wherein said layer of excitable substance is of a thickness in the range 10 to 1000 nm, and arranged so that, in use, the separation of this layer from the sample is in the range of 1 to 1000 .mu.m. 8. A sample cell according to claim 6 wherein said structure includes a substrate and/or spacer layer, transparent generally to x-rays or to a selected x-ray energy band(s), separating the layer of excitable substance from the sample. 9. A sample cell according to claim 8 wherein said substrate and/or spacer layer is strongly absorbing for energies outside said selected x-ray energy band(s) in order to enhance the chromatic coherence of the x-ray beam contributing to the image. 10. A sample cell according to claim 1 wherein said body is a divided or patterned array of body portions retained on a common substrate. 11. A sample cell according to claim 10 wherein said divided or patterned array of body portions comprises an array of spots spaced on a common substrate. 12. A sample cell according to claim 11 wherein said spots are of diameter about 0.2 micron. 13. A sample cell according to claim 12 wherein said spots are arranged whereby said incident beam is wider than each spot. 14. A sample cell according to claim 11 wherein said spots are arranged whereby said incident beam is wider than each spot. 15. A sample cell according to claim 1 wherein said chamber is open. 16. A sample cell according to claim 15 wherein said chamber is arranged to be hermetically sealed after placement of a sample in the chamber. 17. A sample cell according to claim 1 wherein said chamber is adapted to be enclosed, and said structure includes an x-ray transparent window by which the said x-ray radiation exits the structure for detection. 18. A sample cell according to claim 1 in combination with an energy detector. 19. A kit of components adapted to form a sample cell according to claim 1 wherein in situ in holder means of an electron microscope or microprobe at a position where said electron beam is focused on said body of excitable substance, and thereby provides said incident beam for exciting said substance to generate x-ray radiation. 20. A method of deriving a magnified x-ray image of one or more internal boundaries or other features of a sample, comprising: disposing the sample in a sample cell including a body of an excitable substance and a chamber for holding the sample;  fitting the cell into holder means of an electron microscope or microprobe at a position where an electron beam generated by the microscope or microprobe is focused on said body of excitable substance;  irradiating said excitable substance with said electron beam to cause the substance to generate x-ray radiation, at least a portion of which traverses the chamber to irradiate the sample, including the one or more internal boundaries or other features, and thereafter exits the cell structure; and  detecting and recording at least a portion of said radiation exiting the cell structure after it has irradiated the sample, to provide an image of the one or more internal boundaries or other features of the sample.  a sample cell including means to support a sample and a body of a substance excitable by an appropriate incident beam to generate x-ray radiation, said body being retained on a substrate disposed in use between said body and said sample and thereby serving as a spacer;  a detection device located external to the sample cell for detecting x-ray radiation that has traversed the sample cell; and  means to adjust the relative position of said sample and said body. 21. A method according to claim 20 wherein said x-ray imaging is phase-contrast imaging or a mixture of absorption-contrast and phase-contrast. 22. A method according to claim 21 wherein said incident x-ray beam and said radiation that irradiates said sample are highly spatially coherent, for optimizing useful contrast in the image. 23. A method according to claim 20 wherein said electron beam is focused to a width in the range 10 to 1000 nm in said body of excitable substance. 24. A method according to claim 20 wherein the sample cell utilized is an array of layers, of dimensions parallel to the plane of the layers in the range of about 1 micron to about 10 millimeters, and wherein said layers through which the excited x-ray radiation passes are highly homogeneous and have very smooth surfaces for preserving high spatial coherence of the incident beam in the radiation that irradiates the sample, thereby optimizing useful contrast in the image. 25. A method according to claim 20 wherein the x-ray radiation generated by the excitable substance is in the medium to hard x-ray range, i.e. in the range 1 keV to 1 MeV, and is substantially polychromatic. 26. A method according to claim 20 wherein the x-ray radiation generated by the excitable substance is substantially monochromatic, and the method further includes enhancing the degree of monochromaticity of this x-ray radiation. 27. A method according to claim 20 wherein said body is an array of spots spaced on a common substrate, and wherein said electron beam is wider than each spot. 28. An x-ray microscope or microprobe having means to generate a focused electron beam, a sample cell adapted to be retained in holder means at a position where said electron beam is focused on said body of excitable substance, and thereby provides said incident beam for exciting said substance to generate x-ray radiation, and a detector located externally of the sample cell, said x-ray radiation traversing a portion of the sample cell to irradiate a sample, whereby at least a portion of the x-rays irradiating the sample exits the sample cell and is detected. 29. An x-ray microscope or microprobe according to claim 28 wherein the electron beam is focused to a width in the range 10 to 1000 nm in said body of excitable substance. 30. An x-ray microscope or microprobe according to claim 28 wherein said means to generate a focused electron beam includes a field emission tip electron source. 31. An x-ray microscope or microprobe according to claim 28 further including an energy detector. 32. An x-ray microscopic imaging configuration comprising: 33. An x-ray microscopic imaging configuration according to claim 32 wherein said substrate is also a filter of said x-ray radiation. 34. An x-ray microscopic imaging configuration according to claim 32 wherein said substance is excitable by an incident electron beam. 35. An x-ray microscopic imaging configuration according to claim 32 wherein said substance is excitable by an incident focused beam of electromagnetic radiation to generate x-ray radiation. 36. An x-ray microscopic imaging configuration according to claim 32 adapted for use in phase contrast imaging, wherein said body and said substrate are layers that are highly homogeneous and have very smooth surfaces after and including the exit boundary of said body for preserving high spatial coherence of the incident beam in the radiation that irradiates the sample, and thereby optimizing useful contrast in the image. 37. An x-ray imaging configuration according to claim 32 wherein said body is a divided or patterned array of body portions retained on a common substrate. 38. An x-ray imaging configuration according to claim 37 wherein said divided or patterned array of body portions comprises an array of spots spaced on a common substrate. 39. An x-ray imaging configuration according to claim 38 wherein said spots are of diameter about 0.2 micron. 40. An x-ray imaging configuration according to claim 39 wherein said spots are arranged whereby said incident beam is wider than each spot. 41. An x-ray imaging configuration according to claim 38 wherein said spots are arranged whereby said incident beam is wider than each spot.