Water column overlying the sediment of a unit area settled onto the seafloor within its residence time Nd in the ocean22, the Nd-precipitation flux from the overlying seawater FSW can be estimated byFSW = DSW CNd , SW Nd . (10) (11)The requisite condition for the formation of REY-rich mud with a bulk total REY content CREY isF F SW .By substituting equations (8) and (10), equation (11) can be solved asR Nd sed (0.177C REY – 0.346) D SW C Nd , SW , (12)which indicates that the requirement for the formation of REY-rich mud is a sedimentation rate smaller than a particular value. Supplementary Fig. S19 shows the relationship between the Nd precipitation flux and the sedimentation rate. We assumed D = 5,000 m, sed = 0.5 g/cm3 (Supplementary Table S4), SW = 1.03 g/cm3, and Nd = 380?50 years55. In the present ocean, the AZD3759 web concentrations of REY in the seawater are generally low in the surface and high in the deep ocean56?8. Here, we used the following averaged concentration of dissolved Nd through the water column based on ref. 56: CNd,SW = 3.54 ?10-6 ppm. Supplementary Fig. S19 shows that the condition for feeding REY-rich mud of relatively high total REY concentration (>1,000 ppm, including Ce) is R 0.5 m/Myr. Indeed, the sedimentation rates of typical REY-rich mud with high-IC1 or high-IC4 scores are generally less than 0.5 m/Myr (Supplementary Table S4). However, their values contain large uncertainty owing to the paucity of age-diagnostic fossils in the pelagic clay.
www.nature.com/scientificreportsOPENreceived: 17 March 2016 accepted: 20 June 2016 Published: 13 JulyDisentangling adaptive evolutionary GW0742 dose radiations and the role of diet in promoting diversification on islandsDaniel DeMiguelAlthough the initial formulation of modern concepts of adaptive radiation arose from consideration of the fossil data, rigorous attempts to identify this phenomenon in the fossil record are largely uncommon. Here I focus on direct evidence of the diet (through tooth-wear patterns) and ecologicallyrelevant traits of one of the most renowned fossil vertebrates-the Miocene ruminant Hoplitomeryx from the island of Gargano-to deepen our understanding of the most likely causal forces under which adaptive radiations emerge on islands. Results show how accelerated accumulation of species and earlybursts of ecological diversification occur after invading an island, and provide insights on the interplay between diet and demographic (population-density), ecological (competition/food requirements) and abiotic (climate-instability) factors, identified as drivers of adaptive diversification. A pronounced event of overpopulation and a phase of aridity determined most of the rate and magnitude of radiation, and pushed species to expand diets from soft-leafy foods to tougher-harder items. Unexpectedly, results show that herbivorous mammals are restricted to browsing habits on small-islands, even if bursts of ecological diversification and dietary divergence occur. This study deepens our understanding of the mechanisms promoting adaptive radiations, and forces us to reevaluate the role of diet in the origins and evolution of islands mammals. Islands have long been recognised as nature’s test tubes of great value in studying macroevolutionary processes even since Darwin’s early proposal of natural selection1. This lies in the fact that islands involve the emergence of novel and unexplored ecological opportunities for immigrant lineages to appear and proliferate2. The in.Water column overlying the sediment of a unit area settled onto the seafloor within its residence time Nd in the ocean22, the Nd-precipitation flux from the overlying seawater FSW can be estimated byFSW = DSW CNd , SW Nd . (10) (11)The requisite condition for the formation of REY-rich mud with a bulk total REY content CREY isF F SW .By substituting equations (8) and (10), equation (11) can be solved asR Nd sed (0.177C REY – 0.346) D SW C Nd , SW , (12)which indicates that the requirement for the formation of REY-rich mud is a sedimentation rate smaller than a particular value. Supplementary Fig. S19 shows the relationship between the Nd precipitation flux and the sedimentation rate. We assumed D = 5,000 m, sed = 0.5 g/cm3 (Supplementary Table S4), SW = 1.03 g/cm3, and Nd = 380?50 years55. In the present ocean, the concentrations of REY in the seawater are generally low in the surface and high in the deep ocean56?8. Here, we used the following averaged concentration of dissolved Nd through the water column based on ref. 56: CNd,SW = 3.54 ?10-6 ppm. Supplementary Fig. S19 shows that the condition for feeding REY-rich mud of relatively high total REY concentration (>1,000 ppm, including Ce) is R 0.5 m/Myr. Indeed, the sedimentation rates of typical REY-rich mud with high-IC1 or high-IC4 scores are generally less than 0.5 m/Myr (Supplementary Table S4). However, their values contain large uncertainty owing to the paucity of age-diagnostic fossils in the pelagic clay.
www.nature.com/scientificreportsOPENreceived: 17 March 2016 accepted: 20 June 2016 Published: 13 JulyDisentangling adaptive evolutionary radiations and the role of diet in promoting diversification on islandsDaniel DeMiguelAlthough the initial formulation of modern concepts of adaptive radiation arose from consideration of the fossil data, rigorous attempts to identify this phenomenon in the fossil record are largely uncommon. Here I focus on direct evidence of the diet (through tooth-wear patterns) and ecologicallyrelevant traits of one of the most renowned fossil vertebrates-the Miocene ruminant Hoplitomeryx from the island of Gargano-to deepen our understanding of the most likely causal forces under which adaptive radiations emerge on islands. Results show how accelerated accumulation of species and earlybursts of ecological diversification occur after invading an island, and provide insights on the interplay between diet and demographic (population-density), ecological (competition/food requirements) and abiotic (climate-instability) factors, identified as drivers of adaptive diversification. A pronounced event of overpopulation and a phase of aridity determined most of the rate and magnitude of radiation, and pushed species to expand diets from soft-leafy foods to tougher-harder items. Unexpectedly, results show that herbivorous mammals are restricted to browsing habits on small-islands, even if bursts of ecological diversification and dietary divergence occur. This study deepens our understanding of the mechanisms promoting adaptive radiations, and forces us to reevaluate the role of diet in the origins and evolution of islands mammals. Islands have long been recognised as nature’s test tubes of great value in studying macroevolutionary processes even since Darwin’s early proposal of natural selection1. This lies in the fact that islands involve the emergence of novel and unexplored ecological opportunities for immigrant lineages to appear and proliferate2. The in.