LIFE on other planets could be detected as a result of pioneering research by a team of Scottish and American scientists.

The study into how the Earth’s atmosphere evolved over time could hold the key to detecting life on exoplanets – planets outwith our solar system that orbit a star.

The new research is published today by a team from the universities of St Andrews and Cornell.

It details how Earth’s atmosphere evolved over time and how this corresponds to the appearance of different forms of life.

The team, led by Dr Sarah Rugheimer, astronomer and astrobiologist from the School of Earth and Environmental Sciences at the University of St Andrews, studied different geological epochs from Earth’s history, modelling the atmospheres around different stars, bigger and smaller than our Sun.

The researchers found that a planet’s star type is an important factor in how an exoplanet’s atmosphere develops and in how detectable signs of life, aka biosignatures, will be.

The study focused on Earth’s atmosphere at four distinct points in history: before microbes (3.9 billion years ago), after microbes and the first rise of oxygen (two billion years ago), during the second rise of oxygen (800 million years ago), and Earth as it is today. At each of these points, oxygen methane and carbon dioxide were in drastically different abundances.

The new findings in to how life evolves in different atmospheres could lay the foundation for scientists to interpret early biosignatures and signs of life on Earth-size exoplanets, according to the team.

Dr Rugheimer said that as technology improves it was expected that astronomers would find “a myriad of exoplanets beyond even our wildest imagination.”

She added that the team’s research could help shed light on the discoveries. “Even looking back at our own planet, the atmosphere has changed dramatically many times,” she pointed out.

“By looking at the history of Earth and how different host star light would interact with a planet’s atmosphere, we can start to create a grid of models to help us understand future observations. In particular, in this paper we wanted to find out how detectable biosignature gases have been both in Earth’s history and if these planets were orbiting a different star.”

Varied cloud cover and surface features such as oceans and continents were also factored in during the study to see how these affected the models.

However in order to accurately reflect the findings on distant exoplanets larger telescopes are required, according to the team.

Dr Rugheimer said: “The 2019 launch of the James Webb Space Telescope should allow us to study a handful of habitable, Earth-size exoplanets transiting red dwarf stars. The European Extremely Large Telescope, which should be online in the mid-2020s, may also be able to directly image a handful of exoplanets.”

The paper Spectra of Earth-like planets through geological evolution around FGKM stars by Dr Sarah Rugheimer and Professor Lisa Kaltenegger is published in The Astrophysical Journal.