D. Blake, R. Walroth, P. Sarrazin, T. Bristow, M. Gailhanou, R. Downs, K. Thompson
{"title":"MapX:用于可居住性和生物特征研究的原位x射线微成像仪","authors":"D. Blake, R. Walroth, P. Sarrazin, T. Bristow, M. Gailhanou, R. Downs, K. Thompson","doi":"10.5194/epsc2020-70","DOIUrl":null,"url":null,"abstract":"<p><strong>   Introduction:</strong> The search for evidence of life or its processes on Mars takes on two major themes: 1), the identification of environments that have or once had the potential to harbor life (habitability); and 2), the detection of morphological or chemical features suggestive of extinct or extant life (biosignatures).  Compositional heterogeneity at the mm-to-100µm scale can reveal geological processes indicative of past or present habitability, and morphological and compositional heterogeneity on a similar length scale can provide evidence of life’s processes.  The Mapping X-ray Fluorescence Spectrometer (MapX) is an arm-based in-situ instrument designed to identify these features on planetary surfaces [1].</p>\n<p> <strong>Instrument Description: </strong>MapX is a full-field elemental imager capable of analyzing samples in situ without sample preparation. MapX has no moving parts, a 1-cm depth of field, and is designed to utilize <sup>244</sup>Cm radioisotope sources, eliminating the need for a High Voltage Power Supply or X-ray tube.  Figure 1 shows a schematic of the instrument, which consists of X-ray / ϒ-ray / α-particle sources, a focusing optic, and a CCD. The focusing lens is an X-ray micro-pore optic (MPO) which focuses X-ray photons 1:1 onto the CCD. The MPO has a large depth of field (~1cm) allowing rough unprepared surfaces to be imaged with minimal loss of resolution. The CCD is read out fast enough (several frames per second) so that each pixel records either a single photon from the sample or background. The number of electron hole pairs generated in a single pixel is directly proportional to the energy of the X-ray photon, and after summing a large number of individual frames, an XRF spectrum is generated for each pixel of the CCD. Each individual 0.3 sec. frame is a complete image; however many frames are necessary to produce quantifiable XRF spectra. Longer collection times will allow for improved signal to noise, but in the event a collection is interrupted the partial data will still yield a complete image.  Downlinked data products include:  Elemental maps 11<Z<40, instrument-selected [2] Regions of Interest (ROI) having common compositions, and quantifiable XRF spectra from ROI.  </p>\n<p><img src=\"data:image/png;base64, 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","PeriodicalId":108352,"journal":{"name":"Bulletin of the AAS","volume":"152 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2020-10-08","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"MapX: An In-situ X-ray µ-Mapper for Habitability and Biosignature Studies\",\"authors\":\"D. Blake, R. Walroth, P. Sarrazin, T. Bristow, M. Gailhanou, R. Downs, K. Thompson\",\"doi\":\"10.5194/epsc2020-70\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><strong>   Introduction:</strong> The search for evidence of life or its processes on Mars takes on two major themes: 1), the identification of environments that have or once had the potential to harbor life (habitability); and 2), the detection of morphological or chemical features suggestive of extinct or extant life (biosignatures).  Compositional heterogeneity at the mm-to-100µm scale can reveal geological processes indicative of past or present habitability, and morphological and compositional heterogeneity on a similar length scale can provide evidence of life’s processes.  The Mapping X-ray Fluorescence Spectrometer (MapX) is an arm-based in-situ instrument designed to identify these features on planetary surfaces [1].</p>\\n<p> <strong>Instrument Description: </strong>MapX is a full-field elemental imager capable of analyzing samples in situ without sample preparation. MapX has no moving parts, a 1-cm depth of field, and is designed to utilize <sup>244</sup>Cm radioisotope sources, eliminating the need for a High Voltage Power Supply or X-ray tube.  Figure 1 shows a schematic of the instrument, which consists of X-ray / ϒ-ray / α-particle sources, a focusing optic, and a CCD. The focusing lens is an X-ray micro-pore optic (MPO) which focuses X-ray photons 1:1 onto the CCD. The MPO has a large depth of field (~1cm) allowing rough unprepared surfaces to be imaged with minimal loss of resolution. The CCD is read out fast enough (several frames per second) so that each pixel records either a single photon from the sample or background. The number of electron hole pairs generated in a single pixel is directly proportional to the energy of the X-ray photon, and after summing a large number of individual frames, an XRF spectrum is generated for each pixel of the CCD. Each individual 0.3 sec. frame is a complete image; however many frames are necessary to produce quantifiable XRF spectra. Longer collection times will allow for improved signal to noise, but in the event a collection is interrupted the partial data will still yield a complete image.  Downlinked data products include:  Elemental maps 11<Z<40, instrument-selected [2] Regions of Interest (ROI) having common compositions, and quantifiable XRF spectra from ROI.  </p>\\n<p><img src=\\\"data:image/png;base64, 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MapX: An In-situ X-ray µ-Mapper for Habitability and Biosignature Studies
Introduction: The search for evidence of life or its processes on Mars takes on two major themes: 1), the identification of environments that have or once had the potential to harbor life (habitability); and 2), the detection of morphological or chemical features suggestive of extinct or extant life (biosignatures). Compositional heterogeneity at the mm-to-100µm scale can reveal geological processes indicative of past or present habitability, and morphological and compositional heterogeneity on a similar length scale can provide evidence of life’s processes. The Mapping X-ray Fluorescence Spectrometer (MapX) is an arm-based in-situ instrument designed to identify these features on planetary surfaces [1].
Instrument Description: MapX is a full-field elemental imager capable of analyzing samples in situ without sample preparation. MapX has no moving parts, a 1-cm depth of field, and is designed to utilize 244Cm radioisotope sources, eliminating the need for a High Voltage Power Supply or X-ray tube. Figure 1 shows a schematic of the instrument, which consists of X-ray / ϒ-ray / α-particle sources, a focusing optic, and a CCD. The focusing lens is an X-ray micro-pore optic (MPO) which focuses X-ray photons 1:1 onto the CCD. The MPO has a large depth of field (~1cm) allowing rough unprepared surfaces to be imaged with minimal loss of resolution. The CCD is read out fast enough (several frames per second) so that each pixel records either a single photon from the sample or background. The number of electron hole pairs generated in a single pixel is directly proportional to the energy of the X-ray photon, and after summing a large number of individual frames, an XRF spectrum is generated for each pixel of the CCD. Each individual 0.3 sec. frame is a complete image; however many frames are necessary to produce quantifiable XRF spectra. Longer collection times will allow for improved signal to noise, but in the event a collection is interrupted the partial data will still yield a complete image. Downlinked data products include: Elemental maps 11
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京公网安备 11010802042870号
