29 August 2012

Sweet building blocks of life found around young star

Life is made up of a series of complex organic molecules, including sugars. A team of astronomers led by researchers from the Niels Bohr Institute, have now observed a simple sugar molecule in the gas surrounding a young star and this discovery proves that the building blocks of life were already present during planet formation. The results have been published in the scientific journal Astrophysical Journal Letters.

Infrared image of the Rho Ophiuchi star forming region observed

by NASA's WISE satellite. The cloud in this image measures 14

light years across. The astronomers used ALMA to observe a

very young star located in the left part of image (yellow box).

The ALMA observations resolve details at a scale of 0.0005

light years corresponding to the orbit of Uranus in our own solar

system. The observed glycolaldehyde emission is present on

those scales around the young star. (NASA/JPL-Caltech/UCLA)

The star was observed with the new large international telescope, Atacama Large Millimeter Array (ALMA) in northern Chile. The ALMA telescopes are able to zoom in and study the details of newly formed stars and their rotating discs of dust and gas, which subsequently clumps together and forms planets. Among other things, the astronomers would like to investigate the gas for the presence of water vapour and examine the chemical composition for complex molecules.

Sugar around new stars

“In the protoplanetary disc of gas and dust surrounding the young, newly formed star, we found glycolaldehyde molecules, which are a simple form of sugar. It is one of the building blocks in the process that leads to the formation of RNA and the first step in the direction of biology,” explains astrophysicist Jes Jørgensen, Associate Professor at the Niels Bohr Institute and the Centre for Star and Planet Formation at the University of Copenhagen.

The ALMA telescopes on the Chajnantor plateau in the

Atacama desert in Northern Chile. ALMA consists now

of 44 telescopen, and when it finishes construction in

late 2013 it will consist of 66 telescopes, that will

measure radiation with (sub)millimeter wavelengths

from young stars and distant galaxies with so-far

unprecedented resolution and sensitivity.

He explains that at first the gas and dust cloud is extremely cold (only around 10 degrees above absolute zero at minus 273 degrees C) and simple gases such as carbon monoxide and methane settle on particles of dust and solidify as ice. Here on the particles of dust, the otherwise volatile gases come close to each other and can bond together and form more complex molecules. When the star has been formed in the middle of the gas and dust cloud, it emits heat, and the inner parts of the rotating cloud surrounding the star is heated to around room temperature, after which the chemically complex molecules on the particles of dust evaporate as gas. This gas emits radiation as radio waves at low frequencies and it is this radiation that researchers can observe with the ALMA telescopes.

Precursors for biology before planets

The star is located only 400 light years from us – so, seen in an astronomical context, it is right in our own neighbourhood. With the very high resolution of the new telescopes, researchers now have the opportunity to study the details of the dust and gas clouds, and in addition to the sugar molecules the researchers also saw signs of a number of other complex organic molecules, including ethylene-glycol, methyl-formate and ethanol.

Observed spectrum from the young protostar IRAS16293B.

Each peak in the spectrum corresponds to radiation from a

specific molecule. With the high sensitivity of the ALMA

data one of the biggest challenges for the astronomers is to

disentangle which of the many lines correspond to which

molecules.

“The complex molecules in the cloud surrounding the newly formed star tell us that the building blocks of life may be among the first formed. One of the big questions is whether it is common that these organic molecules are formed so early in the star and planet formation process – and how complex they can become before they are incorporated into new planets. This could potentially tell us something about the possibility that life might arise elsewhere and whether precursors to biology are already present before the planets have been formed,” explains Jes Jørgensen.

Astrophysical Journal Letters >>