The science behind Physics Nobel Prize
- This year’s Nobel Prize for Physics recognises research that helps us understand our place in the universe.
- It was awarded to,Canadian-American cosmologist James Peebles.
- He won one-half of the Prize for his theoretical work to understand how the universe evolved after the Big Bang.
- The other half went to Swiss astronomers Michel Mayor and Didier Queloz.
- It is for their discovery of an exoplanet that challenged preconceived ideas about planets.
James Peebles Work on Evolution of Universe
- Modern cosmology assumes that the universe formed as a result of the Big Bang.
- Peebles used theoretical physics and calculations to interpret what happened after.
- His work is focused largely on ‘Cosmic Microwave Background’ (CMB) radiation.
- CMB is electromagnetic radiation left over from the early universe once it had cooled sufficiently following the Big Bang.
- Peebles has correlated the temperature of this radiation with the amount of matter created in Big Bang.
- This was a key step towards understanding how this matter would later form the galaxies and galaxy clusters.
- From his work derives our knowledge of how mysterious the universe is,
- just 5% known matter and
- the rest unknown, as Dark matter (26%) and
- Dark energy (69%).
Michel Mayor and Didier Queloz Work on Exoplanets
- The two scientists detected the first planet orbiting an alien star.
- Exoplanets are being discovered very frequently, today over 4,000 are known.
- The planet discovered by Mayor and Queloz in 1995 is 50 light years away.
- It is orbiting the star ‘51 Pegasus’ that is similar to our Sun.
- ELODIE a spectrograph, built by Mayor, predicted the planet.
- It was, by observing the “Doppler effect” when the star wobbles as an effect of a planet’s gravity on its observed light.
- It is a gas giant comparable to Jupiter, yet it is very hot, unlike icy cold Jupiter;
- 51 Pegagsus b is even closer to its star than Mercury to our Sun.
- Until then, gas giants were presumed to be cold, formed a great distance from their stars.
- Today, it is accepted that these hot gas giants represent what Jupiter would look like if it were suddenly transported closer to the Sun.
- The discovery of the planet started a revolution in astronomy and since then many exoplanets have been found in our galaxy.
Geotail and its impact on Chandrayaan-2
- Recently, ISRO tweeted that an instrument on Chandrayaan-2, CLASS, had detected charged particles during the mission.
- This happened during the orbiter’s passage through the ‘Geotail’.
- The Geotail is a region in space that allows the best observations.
- The region exists as a result of the interactions between the Sun and Earth.
- The Sun emits the solar wind, which is a continuous stream of charged particles.
- These particles are embedded in the extended magnetic field of the Sun.
- Since the Earth has a magnetic field, it obstructs the solar wind plasma.
- This interaction results in the formation of a magnetic envelope around Earth.
- On the Earth side facing the Sun, the envelope is compressed into a region that is approximately 3 to 4 times the Earth radius.
- On the opposite side, the envelope is stretched into a long tail, which extends beyond the orbit of the Moon.
- It is this tail that is called the Geotail.
- Once every 29 days, the Moon traverses the geotail for about six days.
- When Chandrayaan-2, which is orbiting the Moon, crosses the geotail, its instruments can study the properties of the geotail.
- It can helps to detect the presence of key elements like Na, Ca, Al, Si, Ti and Fe the lunar soil.
Source: PIB, The Indian Express
