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Study finds Jurassic ecosystems were similar to modern: Animals flourish among lush plants

In modern ecosystems, animals flourish amid lush vegetation. An SMU study examines whether that same relationship held true 150 million years ago when dinosaurs roamed the Earth.

“The assumption has been that ancient ecosystems worked just like our modern ecosystems,” says SMU paleontologist Timothy S. Myers. “We wanted to see if this was, in fact, the case.”

CO2 levels in fossil soils from the Late Jurassic confirm that climate, vegetation and animal richness varied across the planet 150 million years ago, suggesting future human changes to global climate will heavily impact plant and animal life.

In modern ecosystems, it’s widely known that animals flourish in regions where the climate and landscape produce lush vegetation.

A new study set out to discover whether that same relationship held true 150 million years ago during the Late Jurassic when dinosaurs roamed the Earth.

“The assumption has been that ancient ecosystems worked just like our modern ecosystems,” said paleontologist and lead author Timothy S. Myers, Southern Methodist University, Dallas. “We wanted to see if this was, in fact, the case.”

To test the theory, Myers analyzed fossil soils from the Late Jurassic by measuring the ratios of carbon isotopes. His analysis indicated that the Jurassic soils contained high levels of CO2 from vegetation.

Nodules of ancient soil are fairly common in present day rock, forming as a result of seasonally dry conditions. They harden into mineralized clods, making them easy to spot and sample as they weather out of ancient soil profiles. (Image: Myers)

From that, Myers was able to infer the presence of lush plant life in certain regions during the Jurassic. The soils came from locales where scientists previously have gathered animal fossils — North America, Europe and Africa. Combining the data with the known fossil sampling allowed Myers to confirm that the modern relationship between animals and vegetation held true even millions of years ago.

“Our analysis represents the first time that anyone has tried to apply ecological modeling to this relationship in the fossil record,” Myers said.

Relatively few places in the world are well-sampled for terrestrial fossils, so Myers’ discovery of a new use for an already existing method represents a useful tool, he said. The new use allows scientists to tap the geochemical data of soils from anywhere in the world and from other geologic time periods to infer the relative abundance of plants and animals, particularly for areas where fossils are lacking.

“This not only provides a more complete picture of the ancient landscape and climate in which ancient animals lived,” Myers said. “It also illustrates that climate and biota have been ecologically connected for many millions of years and that future human-caused changes to global climate will have profound impacts on plant and animal life around the world.”

Myers and his co-researchers reported the findings in Paleobiology, “Estimating Soil pCO2 Using Paleosol Carbonates: Implications for the Relationship Between Primary Productivity and Faunal Richness in Ancient Terrestrial Ecosystems.”

Co-authors were SMU sedimentary geochemist Neil J. Tabor and paleontologists Louis L. Jacobs, SMU, and Octávio Mateus, New University of Lisbon, Portugal.

“Devising new and creative methods to understand how Earth and life have functioned together in the past is the foundation for predicting the future of life on our planet,” said Jacobs, a vertebrate paleontologist and professor in SMU’s Roy M. Huffington Department of Earth Sciences. “It is the only approach that provides a long enough perspective of what is possible.”

New method applied to old hypothesis confirms regional variability
Typically researchers count the number of animal species discovered in a region to determine how many different types of animals once lived there. Scientists call that a measure of faunal richness.

Myers took a different approach. Using a traditional method typically used to estimate carbon dioxide in the ancient atmosphere, Myers instead applied it to estimate the amount of CO2 in ancient soils.

Measurements were taken from nodules of calcite that form in soil as a result of wet and dry seasons. These nodules take on the isotopic signature of the CO2 gas around them, which is a mixture derived from two sources: the atmosphere, which leaves a more positive isotopic signature, and plants decaying in the soil, which leave a more negative isotopic signature.

A higher volume of CO2 from plants indicates a lusher, wetter environment.

“There’s a lot more litter fall in an environment with a lot of plants, and that produces a lot of organic material in the soil, creating CO2. So we see more soil-produced CO2, displacing the atmospheric CO2. These are established relationships,” Myers said.

“Our method can be used to infer relative levels of richness for areas where soils have been preserved, but where fossils are lacking because conditions were unsuitable for their preservation,” he said.

The research demonstrates creative use of existing geological data, said co-author Tabor, an expert in ancient soil in SMU’s Roy M. Huffington Department of Earth Sciences.

“Vertebrate paleontologists have been accumulating information about vertebrate fossils in the Jurassic for well over 100 years. In addition, geochemists have been systematically sampling the composition of ancient soils for several decades,” Tabor said. “In these respects, the data that are the foundation of this study are not extraordinary. What is remarkable, though, is combining the paleontology and geochemistry data to answer large-scale questions that extend beyond the data points — specifically, to answer questions about ancient ecosystems.”

Data from Morrison Formation, Central Africa and Portugal
Myers tested Upper Jurassic soil nodules collected from the Morrison Formation in the western United States. The formation extends from Montana to New Mexico and has been the source of many dinosaur fossil discoveries.

He also analyzed Upper Jurassic soil nodules from Portugal, another location well-sampled for dinosaur fossils. The region’s paleoclimate was broadly similar to that of the Morrison Formation.

In addition, Myers tested a small Upper Jurassic core sample from Central Africa, where there’s no evidence of any major terrestrial life. Unique minerals in the rocks indicate that the region had an arid environment during the Late Jurassic.

Based on their hypothesis, the researchers expected to see regional variations in plant productivity — the amount of new growth produced in an area over time, which is an indirect measure of the amount of plant life in an environment. Forests, savannas and deserts all have different amounts of plant productivity, although those specific ecosystems can’t be identified on the basis of plant productivity alone.

The researchers expected to see higher plant productivity for Portugal than for the Morrison Formation, with the lowest productivity in Central Africa.

“Essentially that’s what we found,” Myers said. “We understand it’s tenuous and not a trend, but few places in the world are well-sampled. However, it’s still a useful tool for places where all we have are the soil nodules, without well-preserved fauna.”

Soil nodules are fairly common, Myers said. They form as a result of seasonally dry conditions and may be preserved in all but the wettest environments. Since they harden into mineralized clods, they are easy to spot and sample as they weather out of ancient soil profiles.

CO2 in ancient calcite nodules offers key to ancient climate
From the analysis scientists can draw a more complete picture of the ancient landscape and climate in which prehistoric animals lived.

“The Jurassic is thought of as very warm, very wet, with lots of dinosaurs,” said Myers, research curator for SMU’s Shuler Museum of Paleontology. “But we see from our analysis that there was regional variability during the Late Jurassic in the climate and in the abundance of animals across the planet.”

The Late Jurassic extended from 160 million years ago to 145 million years ago. — Margaret Allen

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