NSF Award
1248744
This Small Business Innovation Research Program (SBIR) Phase I project aims at developing the technology for a correlative x-ray imaging and analytical microscope that is able to produce 3-dimensional images with sub-micrometer resolution of samples and subsequently probe points or areas of this volume selectively for elemental (chemical) information. While commercial solutions (x-ray micro-tomography) already exist to obtain the high resolution 3-D images, these images only show a grey-scale mass density representation of the sample. No information about which compounds and elements the sample is made out of is available. The research focuses on demonstrating the ability to add an x-ray fluorescence capability to the x-ray imaging to unambiguously identify the elemental makeup with very high ultimate sensitivity (parts per million) with a focus on correlating exactly the elemental measurement with the location in the 3-D x-ray image of the sample. There is a growing need for this complementary capability both in the academic research area and in industrial use for targeted applications.<br/><br/><br/>The broader impact/commercial potential of this project is to enable the development of more energy efficient and environmentally friendly extraction and processing techniques for the natural resource sector. The first set of customers, directly contributing to the research by providing relevant samples and helping in defining the ultimate system requirements and specifications, come from the mining R&D and industrial market segment. These customers have adopted high-resolution x-ray imaging very rapidly in the past few years, realizing the inherent advantage of imaging ore samples at various stages during the process of extracting and purifying the valuables. While this capability is already helping to develop better, more efficient extraction processes, an analytical capability to get elemental and chemical information is becoming essential for continued progress. Obvious benefits from the availability of the new technology will be energy savings in the extraction processes by increasing efficiency and better use of available resources by not allowing valuables to enter the waste stream. As an indirect consequence, this leads long term to lower commodity prices and a general higher living standard. But the relevance of the research extends much further into areas of life science, material science and all areas requiring imaging and analytical capabilities.
