Rapid shallowing can trigger dramatic ecological changes and challenges within and beyond arid, nutrient-rich lakes

Data used for the "Rapid shallowing can trigger dramatic ecological changes and challenges within and beyond arid, nutrient-rich lakes" manuscript.In addition to data generated from this study,Fig. 1 data modified after Hung, C., Diamond, C., Sinclair, R., Lee, I., Stenstrom, M., Freilich, M. A., Montgomery, Q., Marquez, C. & Lyons, T. Nutrient loading as a key cause of short- and long-term anthropogenic ecological degradation of the Salton Sea. Sci. Rep. 14, 31247 (2024) and Sherwood, J. E., Stagnitti, F., Kokkinn, M. J. & Williams, W. D. Dissolved oxygen concentrations in hypersaline waters. Limnol. Oceanogr. 36, 235–250 (1991).Fig. 2 and 5 data were adapted from Schroeder, Roy A., William H. Orem, and Yousif K. Kharaka. "Chemical evolution of the Salton Sea, California: nutrient and selenium dynamics." The Salton Sea: Proceedings of the Salton Sea Symposium, held in Desert Hot Springs, California, 13–14 January 2000. Springer Netherlands, 2002. and Reese, Brandi Kiel, Michael A. Anderson, and Christopher Amrhein. "Hydrogen sulfide production and volatilization in a polymictic eutrophic saline lake, Salton Sea, California." Science of the total environment 406.1-2 (2008): 205-218.Fig. 4 data was adapted from Ma, Jinge, et al. "Spatiotemporal pattern of gypsum blooms in the Salton Sea, California, during 2000-2018." International Journal of Applied Earth Observation and Geoinformation 89 (2020): 102090.