The existence of life on another planet could be proved as early as 2026 thanks to a new telescope that could detect signatures made by living creatures.
Research by Ohio State University shows that the NASA James Webb space telescope could detect a signature of life on other planets in as little as 60 hours.
Graduate student Caprice Phillips said the results of her study show that we may ‘realistically find signs of life on another planet in the next 5 to 10 years.’
Phillips calculated that when the James Webb Space Telescope launches in October, it could feasibly detect ammonia around gas dwarf planets after just a few orbits.
The existence of life on another planet could be proved as early as 2026 thanks to a new telescope that could detect signatures made by living creatures
Research by Ohio State University shows that the NASA James Webb space telescope could detect a signature of life on other planets in as little as 60 hours
None of these super-Earths or mini-Neptunes exist within our solar system, so scientists struggle to determine whether their atmospheres contain ammonia and other potential signs of living things.
Phillips and her team modelled how James Webb instruments would respond to varying clouds and atmospheric conditions on a gas Dwarf planet.
They then produced a ranked list of where the telescope should search for life – creating a potential set of targets for first observations.
‘Humankind has contemplated the questions, ‘Are we alone? What is life? Is life elsewhere similar to us?” said Phillips.
‘My research suggests that for the first time, we have the scientific knowledge and technological capabilities to realistically begin to find the answers to these questions.’
There are a few different types of planets not found in the solar system, including super Earths, hot Jupiters, puffy planet and mini-Neptune worlds.
This last type, also known as a gas dwarf or transitional planet are less massive than Neptune but resemble the frozen world in terms of its atmosphere and temperature.
It is a gas planet that has a rocky core surrounded by a thick envelope of hydrogen, helium and other chemicals, with a radius up to about four times the Earth’s.
Because of stronger gravity than Earth, this class of exoplanet can retain a sizeable hydrogen-dominated atmosphere which may support alien life.
The James Webb Space Telescope, going online late this year, will offer unprecedented insight into the atmospheric composition of gas dwarf planets.
The atmospheres of the target worlds have entirely different chemistry from an inhabited Earth-like planet with an oxidising atmosphere.
Graduate student Caprice Phillips said the results of her study show that we may ‘realistically find signs of life on another planet in the next 5 to 10 years’
A mini-Neptune planet has an extended hydrogen atmosphere with a rocky core
For her study, Phillips investigated the detectability of ammonia, a potential biosignature, in the atmospheres of seven potentially habitable gas dwarf planets.
This was based on using various instruments that will operate on the James Webb space telescope when it comes online.
‘We use open-source package petitRADTRANS and PandExo to model planet atmospheres and simulate JWST observations,’ she said.
They considered different scenarios by varying cloud conditions, mean molecular weights and ammonia mixing ratios.
This allowed them to define a metric to quantify detection significance and provide a ranked list for observations in search of biosignature in gas dwarf planets.
Generally, it is challenging to search for the tiny ammonia molecules in the thick hydrogen atmosphere due to the background ‘noise’, explained Phillips.
‘The study shows that searching for biosignature is now feasible with a reasonable investment of JWST time,’ she said.
With about ten orbits of the sun scientists will have enough data from James Webb to say whether a gas dwarf is harbouring alien life.
The James Webb Space Telescope will not be in orbit around the Earth, like the Hubble Space Telescope- it will actually orbit the Sun, 1 million miles from the Earth.
‘What is special about this orbit is that it lets the telescope stay in line with the Earth as it moves around the Sun,’ said NASA.
‘This allows the satellite’s large sunshield to protect the telescope from the light and heat of the Sun and Earth.’
The findings was presented at American Physical Society April meeting.