Neoprot. Archean Phanerozoic Paleoproterozoic Mesoprot. Mari- Noan Tonian Sturtian Ediac. Cryogenian Proterozoic Glacial

Neoprot. Archean Phanerozoic Paleoproterozoic Mesoprot. Mari- Noan Tonian Sturtian Ediac. Cryogenian Proterozoic Glacial

SCIENCE ADVANCES | RESEARCH ARTICLE Solar f lux (wrt present) follow the current informal international usage, wherein “Sturtian” 0.9 1.01.1 1.2 1.3 and “Marinoan” identify the cryochron and its immediate aftermath, including the respective postglacial cap-carbonate sequences.] The nonglacial interlude separating the cryochrons was 9 to 19 million years e <10 My d 90° (My) in duration (Fig. 2A). The worldwide distribution of late Precambrian glacial deposits f Present (Fig. 4) became evident in the 1930s (25, 54, 55), but only recently has 60° their synchroneity been demonstrated radiometrically (32, 56–65). a ~2 ky Previously, geologists were divided whether the distribution of gla- 30° cial deposits represents extraordinary climates (29, 66)ordiachronous products of continental drift (67, 68). The recognition that a panglacial state might be self-terminating Ice line latitudeIce Eq b c (69), due to feedback in the geochemical carbon cycle, meant that its >10 My occurrence in the geological past could not be ruled out on grounds of irreversibility. “If a global glaciation were to occur, the rate of silicate 0.1 1 10 100 1000 weathering should fall very nearly to zero (due to the cessation of nor- PCO (wrt present) mal processes of precipitation, erosion, and runoff), and carbon dioxide 2 Downloaded from should accumulate in the atmosphere at whatever rate it is released Fig. 1. Generic bifurcation diagram illustrating the Snowball Earth hysteresis. from volcanoes. Even the present rate of release would yield 1 bar of Ice-line latitude as a function of solar or CO2 radiative forcing in a one-dimensional carbon dioxide in only 20 million years. The resultant large greenhouse (1D) (meridional) energy-balance model of the Budyko-Sellers type (3, 4), showing effect should melt the ice cover in a geologically short period of time” three stable branches (red, green, and blue solid lines) and the unstable regime (dashed line). Yellow dots are stable climates possible with present-day forcing. Black [(69), p. 9781]. Because Snowball Earth surface temperatures are below arrows indicate nonequilibrium transitions. In response to lower forcing, ice line mi- the freezing point of water everywhere, due to high planetary albedo, http://advances.sciencemag.org/ grates equatorward to the ice-albedo instability threshold (a), whereupon the ice line there is no rain to scrub CO2 (insoluble in snow) from the atmosphere. advances uncontrollably to the equator (Eq) (b). With reduced sinks for carbon, Deposition of CO2 ice at the poles in winter is a potential sink that normal volcanic outgassing drives atmospheric CO2 higher over millions to tens of might render a Snowball Earth irreversible (70). CO2 ice, having a den- millions of years (73)untilitreachesthedeglaciationthreshold (c). Once the tropical sity of 1.5 g cm−3, might sink gravitationally into the polar water ice, ocean begins to open, ice-albedo feedback drives the ice line rapidly poleward (in melting as it penetrates warmer ice at depth (70). On the other hand, ~2 ky) (327) to (d), where high CO combined with low surface albedo creates a 2 CO2 ice clouds warm the poles in winter by scattering outgoing radia- torrid greenhouse climate. Intense silicate weathering and carbon burial lower atmo- 7 tion (71, 72), yet dissipate in summer, allowing sunshine to reach the spheric CO2 (in 10 years) (164)to(e),thethresholdforthereestablishmentofapolar surface and sublimate CO ice particles in the firn (70). As atmospher- ice cap. The hysteresis loop predicts that Snowball glaciations were long-lived (b and 2 c), began synchronously at low latitudes (a and b), and ended synchronously at all ic CO2 accumulates, the stability range for deposition of CO2 ice ini- tially grows because of higher saturation (70). However, an ice-covered latitudes under extreme CO2 radiative forcing (c and d). The ocean is predicted to undergo severe acidification and deacidification in response to the CO2 hysteresis. planet with Earth-like obliquity and distance (1 astronomical unit) from on November 8, 2017 Qualitatively similar hysteresis is found in 3D general circulation models (GCMs). PCO2, a Sun-like star, with or without CO2 ice clouds, remains far below the partial pressure of CO2;wrt,withrespectto. threshold for CO2 ice deposition at any CO2 level relevant to a Cryogenian Snowball Earth Regional ice age No ice sheets A F-LIP Mari- Sturtian noan Tonian Cryogenian Ediac. Ma 740 730 720 710 700 690680 670 660 650 640 630 620 B GOE ? Proterozoic glacial gap Archean Paleoproterozoic Mesoprot. Neoprot. Phanerozoic 3000 2500 2000 1500 1000 500 0 Age (Ma, 106 years before present) Fig. 2. Glacial epochs on Earth since 3.0 Ga. (A) Black bands indicate durations of the Sturtian and Marinoan cryochrons (Table 1). The graded start to the Marinoan cryochron denotes chronometric uncertainty, not gradual onset. Ellipse F-LIP shows the possible age span of the Franklin large igneous province (LIP) (32, 127). (B)Snowball Earth chrons (black), regional-scale ice ages (medium gray), and nonglacial intervals (light gray) since 3.0 Ga. Ellipse GOE is centered on the Great Oxidation Event, as recorded by the disappearance of mass-independent S isotope fractionations ≥0.3 per mil (‰) in sedimentary sulfide and sulfate minerals (484). The dashed gray line indicates questionable glaciation. Hoffman et al., Sci. Adv. 2017; 3 :e1600983 8 November 2017 2 of 43.

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