Add to ORKGAnoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere that occurred through most of the Archean Eon. While euxinic conditions (i.e. anoxic and hydrogen sulfide-rich waters) became more common in the Proterozoic, ferruginous conditions persisted in deep waters. Ferruginous ocean regions would have been a major biosphere and Earth surface reservoir through which elements passed through as part of their global biogeochemical cycles. Understanding key biological events, such as the rise of oxygen in the atmosphere, or even the transitions from ferruginous to euxinic or oxic conditions, requires understanding the biogeochemical processes occurring within ferruginous oceans, and their indicators in t...
Eukaryotic life expanded during the Proterozoic eon1, 2.5 to 0.542 billion years ago, against a back...
Ferruginous lakes provide a window through which geologists can study the geochemistry and biogeoche...
Detailed iron, sulfur and carbon chemistry through the > 742 million year old ChuarGroup reveals a m...
Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed dramatically with the oxidation of the Earth's surface...
The chemical composition of the ocean changed dramatically with the oxidation of the Earth's surface...
With early life presumed to have evolved in ancient oceans and lakes, identifying the availability o...
With early life presumed to have evolved in ancient oceans and lakes, identifying the availability o...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
Terrestrial environments have been suggested as an oxic haven for eukaryotic life and diversificatio...
Eukaryotic life expanded during the Proterozoic eon1, 2.5 to 0.542 billion years ago, against a back...
Ferruginous lakes provide a window through which geologists can study the geochemistry and biogeoche...
Detailed iron, sulfur and carbon chemistry through the > 742 million year old ChuarGroup reveals a m...
Anoxic and iron-rich (ferruginous) conditions prevailed in the ocean under the low-oxygen atmosphere...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed markedly with the oxidation of the Earth’s surface1, a...
The chemical composition of the ocean changed dramatically with the oxidation of the Earth's surface...
The chemical composition of the ocean changed dramatically with the oxidation of the Earth's surface...
With early life presumed to have evolved in ancient oceans and lakes, identifying the availability o...
With early life presumed to have evolved in ancient oceans and lakes, identifying the availability o...
To elucidate the role of (bio)geochemical processes that fueled iron and carbon cycling in early Ear...
Terrestrial environments have been suggested as an oxic haven for eukaryotic life and diversificatio...
Eukaryotic life expanded during the Proterozoic eon1, 2.5 to 0.542 billion years ago, against a back...
Ferruginous lakes provide a window through which geologists can study the geochemistry and biogeoche...
Detailed iron, sulfur and carbon chemistry through the > 742 million year old ChuarGroup reveals a m...