Multiple sulfur-isotope signatures in Archean sulfates and their implications for the chemistry and dynamics of the early atmosphere

Abstract: Sulfur isotopic anomalies (Δ 33 S and Δ 36 S) have been used to trace the redox evolution of the Precambrian atmosphere and to document the photochemistry and transport properties of the modern atmosphere. Recently, it was shown that modern sulfate aerosols formed in an oxidizing atmosphere can display important isotopic anomalies, thus questioning the significance of Archean sulfate deposits. Here, we performed in situ 4S-isotope measurements of 3.2-and 3.5-billion-year (Ga)-old sulfates. This in situ approac… Show more

“…[117,118] Given the potential warming effect of COS,t his hypothesis is with significant implications for explaining the remarkable presence of liquid water (a necessity for life) on the early Earth despite a3 0% weaker sun than at present (also known as the faint young sun paradox). [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life. [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life.…”

“…[170] Given that biomass burning contributed to COS emissions,i tw as proposed that widespread wildfire during the 1997-1998 ENSO provided an additional in situ source of SO 2 in the higher stratosphere to form stratospheric sulfates. [117] This indirect pathway for producing sulfur isotopic anomalies is not considered in modern and Archean models.A sC OS was proposed as am ajor greenhouse gas in the Archean, [116][117][118] its role in the early Earth should be further investigated. [117] This indirect pathway for producing sulfur isotopic anomalies is not considered in modern and Archean models.A sC OS was proposed as am ajor greenhouse gas in the Archean, [116][117][118] its role in the early Earth should be further investigated.…”

“…Thep ilot photochemistry experiments by Farquhar et al, [76,97] which revealed wavelength-dependent sulfur isotope effects,allow the reconstruction of the past atmospheric composition (apart from oxygen) and solar actinic flux spectrum based on sulfur isotopic anomalous signatures in Archean rocks.Itwas suggested that carbonyl sulfide (COS or OCS) from volcanic activities might be an important component in the Archean atmosphere to reproduce the observed Archean d 34 S-D 33 Sr elationship because it prevents SO 2 photolysis at l > 202 nm by shielding UV, [116] and particularly since it also converts to SO 2 through photolytic reactions. [117,118] Given the potential warming effect of COS,t his hypothesis is with significant implications for explaining the remarkable presence of liquid water (a necessity for life) on the early Earth despite a3 0% weaker sun than at present (also known as the faint young sun paradox). Unique d 34 S-D 33 Sp atterns in some 3.5-3.2 Ga samples (different from other Archean samples) was also interpreted as deriving from complex changes in atmospheric composition as ac onsequence of intense burst of subaerial volcanic activity during that period, which might be linked to significant crustal growth and mantle plume events.…”

“…Unique d 34 S-D 33 Sp atterns in some 3.5-3.2 Ga samples (different from other Archean samples) was also interpreted as deriving from complex changes in atmospheric composition as ac onsequence of intense burst of subaerial volcanic activity during that period, which might be linked to significant crustal growth and mantle plume events. [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life. [120] This hypothesis has been tested by carbon and sulfur isotope measurements and relevant photochemistry models,w hich showed that observed changes in Archean D 36 S/D 33 Ss lopes (from À0.9 to À1.5) could be explained, in part, by aC H 4derived organic haze,a nd the CH 4 production is likely of abiological origin.…”

Use of Isotope Effects To Understand the Present and Past of the Atmosphere and Climate and Track the Origin of Life

“…[117,118] Given the potential warming effect of COS,t his hypothesis is with significant implications for explaining the remarkable presence of liquid water (a necessity for life) on the early Earth despite a3 0% weaker sun than at present (also known as the faint young sun paradox). [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life. [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life.…”

“…[170] Given that biomass burning contributed to COS emissions,i tw as proposed that widespread wildfire during the 1997-1998 ENSO provided an additional in situ source of SO 2 in the higher stratosphere to form stratospheric sulfates. [117] This indirect pathway for producing sulfur isotopic anomalies is not considered in modern and Archean models.A sC OS was proposed as am ajor greenhouse gas in the Archean, [116][117][118] its role in the early Earth should be further investigated. [117] This indirect pathway for producing sulfur isotopic anomalies is not considered in modern and Archean models.A sC OS was proposed as am ajor greenhouse gas in the Archean, [116][117][118] its role in the early Earth should be further investigated.…”

“…Thep ilot photochemistry experiments by Farquhar et al, [76,97] which revealed wavelength-dependent sulfur isotope effects,allow the reconstruction of the past atmospheric composition (apart from oxygen) and solar actinic flux spectrum based on sulfur isotopic anomalous signatures in Archean rocks.Itwas suggested that carbonyl sulfide (COS or OCS) from volcanic activities might be an important component in the Archean atmosphere to reproduce the observed Archean d 34 S-D 33 Sr elationship because it prevents SO 2 photolysis at l > 202 nm by shielding UV, [116] and particularly since it also converts to SO 2 through photolytic reactions. [117,118] Given the potential warming effect of COS,t his hypothesis is with significant implications for explaining the remarkable presence of liquid water (a necessity for life) on the early Earth despite a3 0% weaker sun than at present (also known as the faint young sun paradox). Unique d 34 S-D 33 Sp atterns in some 3.5-3.2 Ga samples (different from other Archean samples) was also interpreted as deriving from complex changes in atmospheric composition as ac onsequence of intense burst of subaerial volcanic activity during that period, which might be linked to significant crustal growth and mantle plume events.…”

“…Unique d 34 S-D 33 Sp atterns in some 3.5-3.2 Ga samples (different from other Archean samples) was also interpreted as deriving from complex changes in atmospheric composition as ac onsequence of intense burst of subaerial volcanic activity during that period, which might be linked to significant crustal growth and mantle plume events. [118,119] Another relevant greenhouse gas in the Archean atmosphere to solve the faint young sun paradox is CH 4 .O rganic haze formed from CH 4 photochemistry might exist in the early Earthsa tmosphere and serve as am ajor source of organics to the early Earths ocean, which could have been the birthplace of life. [120] This hypothesis has been tested by carbon and sulfur isotope measurements and relevant photochemistry models,w hich showed that observed changes in Archean D 36 S/D 33 Ss lopes (from À0.9 to À1.5) could be explained, in part, by aC H 4derived organic haze,a nd the CH 4 production is likely of abiological origin.…”

Use of Isotope Effects To Understand the Present and Past of the Atmosphere and Climate and Track the Origin of Life

“…Roerdink et al (2016) measured the multi S isotopes of pyrites associated with barite and explained the large isotopic variations using a model that combined biological and abiotic processes, including hydrothermal leaching, juvenile sulfur mixing and photochemical processes. Muller et al (2016) measured the in situ multi S isotope composition of barites from the Dresser (3.5 Ga, Australia) and the Mapepe (3.2 Ga, South Africa) deposits, with a precision of 0.2‰ for d 34 S and D 33 S and 0.5‰ for D 36 S, and proposed that this sulfate represents an exceptional period of volcanic and non-volcanic sulfate aerosol production and preservation. The same group also investigated the sulfur and the sulfate present in the Sargur Formation (3.2 Ga, India), which revealed similar pristine sulfur isotope composition and trends observed in Mapepe and Dresser at a micrometre scale, despite intense metamorphic re-equilibration (Muller et al 2017).…”

GGR Biennial Critical Review: Analytical Developments Since 2014

Use of Isotope Effects To Understand the Present and Past of the Atmosphere and Climate and Track the Origin of Life