UC Riverside is leading one of the NASA Astrobiology Program's eight new research teams tackling questions about the evolution and origins of life on Earth and the possibility of life beyond our solar system.

The teams comprise the inaugural class of NASA's Interdisciplinary Consortia for Astrobiology Research program. The UCR-led team is motivated by the fundamental question of how to detect planets that could host life and remain habitable despite tremendous change over time, which requires hunting for biological gases in the atmospheres of planets light years beyond our solar system.

"To achieve this goal, our research focuses on the many diverse chapters of Earth's history - or alternative Earths - that span billions of years and offer critical templates for examining exoplanets far beyond our solar system," said UCR biogeochemist Timothy Lyons, the project leader.

Earth has undergone dramatic changes over the last 4.5 billion years, with major transitions occurring in plate tectonics, climate, ocean chemistry, the structure of our ecosystems, and composition of our atmosphere.

"These changes represent an opportunity," Lyons said. "The different periods of Earth's evolutionary history provide glimpses of many, largely alien worlds, some of which may be analogs for habitable planetary states that are very different from conditions on modern Earth."

Exciting new research frontiers for Lyons' team include studies of Earth's first 500 million years, as well as predictions about our planet and its life billions of years in the future.

Studying biosignature gases in Earth's past will allow the team to design telescopes and refine interpretative models for potential traces of life in distant exoplanet atmospheres, noted Georgia Tech biogeochemist Christopher Reinhard.

Once the researchers understand how Earth and its star - the sun - changed together to maintain liquid oceans teeming with life over billions of years, the team can predict how other planetary systems might also have developed and maintained life and better understand how to search for it.

"Such a 'mission to early Earth' must include broad interdisciplinarity, impactful synergy within and across the Research Coordination Networks, or RCNs, of the NASA Astrobiology Program, and a commitment to deliverables that will help steer NASA science for decades to come," said UCR astrobiologist Edward Schwieterman.

The team will collect ancient rock samples and modern sediments from around the world spanning billions of years and use the data they generate to drive wide-ranging computational models for Earth's ancient and future oceans and atmospheres.

This work requires a multipronged view of the Earth as a complex system that has varied dramatically over time. Yet despite all the change, Earth has remained persistently habitable, with liquid water oceans teeming with life.

How Earth became and remained habitable and whether its life would have been detectable to a distant observer are the questions that will ultimately define and refine the search for life on exoplanets.

"In short," said Lyons, "the exciting goal of our team is to provide a new and more holistic view of Earth's evolutionary history in order to help guide NASA's mission-specific search for life on distant worlds."

The $4.6 million new award from NASA will span five years and includes team members from Georgia Tech, Yale University, Purdue University, UCLA, NASA Ames Research Center and collaborators from around the world.

Research paper

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