“…Thus far, the only convincing case for impact as the trigger of a mass extinction and severe, global-scale pa-leoenvironmental effects remains the giant Chicxulub impact on the Yucatán Peninsula in Mexico, which has been stratigraphically, (micro-)paleontologically, geochemically, and in terms of precise U-Pb and Ar-Ar ages linked with the Cretaceous/Paleogene boundary at *66.05 Ma (e.g., Hildebrand et al, 1991;Kring and Boynton, 1991;Toon et al, 1997;Smit, 1999;Kring, 2007;Schulte et al, 2010;Renne et al, 2013Renne et al, , 2018DePalma et al, 2019). Some of the hazardous paleoenvironmental effects caused by the Chicxulub impact (see Kring, 2007 for a summary) include a roughly Richter magnitude 10.5 earthquake that, in turn, triggered a large-scale tsunami and, in paleolakes and lagoons, forceful seiches (e.g., Smit and Romein, 1985;Bourgeois et al 1988;DePalma et al, 2019); the global distribution of airborne distal impact ejecta (e.g., Smit, 1999;Claeys et al, 2002); shock-heating of the atmosphere and widespread wildfires caused by the fallout of hot ejecta (e.g., Wolbach et al, 1985;Melosh et al, 1990;Kring and Durda, 2002;Durda and Kring, 2004;Robertson et al, 2013;Belcher et al, 2015); an almost instantaneous phase of ''impact winter'' caused by atmospheric dust blocking the sunlight (e.g., Vellekoop et al, 2014Vellekoop et al, , 2016Brugger et al, 2017), followed by a superimposed, slower greenhouse effect in response to the voluminous release of atmospherically active gases (e.g., water vapor, CO 2 , and SO x ) from the carbonate-and sulfate-dominated target rock (Kring et al, 1996;Pope et al, 1997;Pierazzo et al, 1998;Kring, 2007); and the acidification of ocean water and leaching of soil due to acid rain (e.g., Prinn and Fegley, ...…”