There are multiple well-recognized and peer-reviewed global datasets that can be used to assess water availability and water pollution. Each of these datasets are based on different inputs, modeling approaches, and assumptions. Therefore, in SBTN Step 1: Assess and Step 2: Interpret & Prioritize, companies are required to consult different global datasets for a robust and comprehensive State of Nature (SoN) assessment for water availability and water pollution. To streamline this process, WWF, the World Resources Institute (WRI), and SBTN worked together to develop two ready-to-use unified layers of SoN – one for water availability and one for water pollution – in line with the Technical Guidance for Steps 1: Assess and Step 2: Interpret & Prioritize. The result is a single file (shapefile) containing the maximum value both for water availability and for water pollution, as well as the datasets’ raw values (as references). This data is publicly available for download from this repository. These unified layers will make it easier for companies to implement a robust approach, and they will lead to more aligned and comparable results between companies. A temporary App is available at https://arcg.is/0z9mOD0 to help companies assess the SoN for water availability and water pollution around their operations and supply chain locations. In the future, these layers will become available both in the WRI’s Aqueduct and in the WWF Risk Filter Suite. For the SoN for water availability, the following datasets were considered: Baseline water stress (Hofste et al. 2019), data available here Water depletion (Brauman et al. 2016), data available here Blue water scarcity (Mekonnen & Hoekstra 2016), data upon request to the authors For the SoN for water pollution, the following datasets were considered: Coastal Eutrophication Potential (Hofste et al. 2019), data available here Nitrate-Nitrite Concentration (Damania et al. 2019), data available here Periphyton Growth Potential (McDowell et al. 2020), data available here In general, the same processing steps were performed for all datasets: Compute the area-weighted median of each dataset at a common spatial resolution, i.e. HydroSHEDS HydroBasins Level 6 in this case. Classify datasets to a common range as reclassifying raw values to 1-5 values, where 0 (zero) was used for cells or features with no data. See the documentation for more details. Identify the maximum value between the classified datasets, separately, for Water Availability and for Water Pollution. For transparency and reproducibility, the code is publicly available at https://github.com/rafaexx/sbtn-SoN-water

{"references": ["Brauman, K. A., Richter, B. D., Postel, S., Malsy, M., & Fl\u00f6rke, M. (2016). Water depletion: An improved metric for incorporating seasonal and dryyear water scarcity into water risk assessments. Elem Sci Anth, 4. https://doi.org/10.12952/journal.elementa.000083", "Damania, R., Desbureaux, S., Rodella, A. S., Russ, J., & Zaveri, E. (2019). Quality unknown: The invisible water crisis. Washington, DC: World Bank. http://hdl.handle.net/10986/32245", "GRDC (2020). WMO Basins and Sub-Basins / Global Runoff Data Centre, GRDC. 3rd, rev. ext. ed. Koblenz, Germany: Federal Institute of Hydrology (BfG). https://www.bafg.de/GRDC/EN/02_srvcs/22_gslrs/223_WMO/wmo_regions_node.html", "Hofste, R., Kuzma, S., Walker, S., ... & Sutanudjaja, E.H. (2019). Aqueduct 3.0: Updated decision relevant global water risk indicators. Technical note. Washington, DC: World Resources Institute. https://doi.org/10.46830/writn.18.00146", "Lehner, B., Grill G. (2013). Global river hydrography and network routing: baseline data and new approaches to study the world's large river systems. Hydrological Processes, 27(15): 2171\u20132186. https://doi.org/10.1002/hyp.9740", "McDowell, R. W., Noble, A., Pletnyakov, P., Haggard, B. E., Mosley, L. M. (2020). Global mapping of freshwater nutrient enrichment and periphyton growth potential. Scientific Reports, 10. https://doi.org/10.1038/s41598-020-60279-w", "Mekonnen, M. M., & Hoekstra, A. Y. (2016). Four billion people facing severe water scarcity. Science advances, 2(2), e1500323. https://doi.org/10.1126/sciadv.1500323"]}