2022-06-212022-06-217/10/2022ICES-2022-305https://hdl.handle.net/2346/89814Richard Kidd, Jet Propulsion Laboratory, USMargie Homer, Jet Propulsion Laboratory, USAaron Noell, Jet Propulsion Laboratory, USJurij Simcic, Jet Propulsion Laboratory, USByunghoon Bae, Jet Propulsion Laboratory, USMarianne Gonzalez, NASA Jet Propulsion Laboratory, USValeria Lopez, Jet Propulsion Laboratory, USMurray Darrach, Jet Propulsion Laboratory, USStuart Pensinger, NASA Johnson Space Center, USMike Callahan, NASA Johnson Space Center, USEvan Neidholdt, KBRwyle, USNikki Gilbert, KBRwyle, USICES205: Advanced Life Support Sensor and Control TechnologyThe 51st International Conference on Environmental Systems was held in Saint Paul, Minnesota, US, on 10 July 2022 through 14 July 2022.On-orbit analysis of the total organic carbon (TOC) content of recycled water, as provided by the ISS TOCA, has been an indispensable tool for monitoring the performance of the WRS and for ensuring that water is fit for crew consumption. While TOC has been, and will continue to be an important metric for spacecraft water quality, it provides only limited insight into the total picture. As a measurement, TOC only provides a single �lump sum� quantity of all organic chemicals present in a water sample. Nor does the TOC measurement begin to address inorganic constituents, such as metals resulting from corrosion nor an intentionally-dosed biocide. For exploration missions beyond LEO, the return of water samples to Earth for analysis will be logistically challenging or impossible. The Spacecraft Water Impurity Monitor (SWIM) is a joint collaboration to develop an instrument platform that will perform in-flight measurements and deliver a more complete picture of water quality to decision makers. Eventually, missions to the moon, Mars, and beyond will be equipped with analytical capabilities equaling those found in terrestrial labs. Based on what we know about current and future spacecraft environments, SWIM will seek to provide enhanced analytical capability that enables NASA to confidently send astronauts on distant missions without the possibility of returned water samples. This paper discusses the challenges presented by exploration requirements and the research and development progress toward the goal of a total water analysis system. For organic analysis, one of the analysis technologies that the SWIM team have been developing is a liquid-injection gas chromatograph mass spectrometer system; these systems are the workhorses of analytical chemistry laboratories world-wide. For inorganic analysis, the team is exploring a number of technologies ranging from traditional liquid chromatography technologies (e.g. ion chromatography, capillary electrophoresis) to flight-heritage technology such as ion-specific electrodes.application/pdfengSWIM = Spacecraft Water Impurity MonitorTOC = total organic carbonTOCA = Total Organic Carbon AnalyzerOWM = Organic Water ModuleGC = gas chromatographMS = mass spectrometerQITMS = quadrupole ion trap mass spectrometerCE = capillary electrophoresisISP = ion specific electrodePresentation