Tag Archives: Aditya

Indian prediction on solar corona proves right

Dr T V Venkateswaran

New Delhi: The predictions made by Indian scientists about the shape of solar corona during the solar eclipse of August 21 have been largely right.

This is a significant development as it was for the first time that physicists attempted to predict the shape of solar corona as it would be visible during an eclipse, using computer simulation and solar models. The development means that in future, scientists will be able to make more complex predictions about space weather which is influenced greatly by solar flares.

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Dibyendu Nandi, scientist and head of the MHRD Center of Excellence in Space Sciences India (CESSI) at IISER Kolkata and his team of students along with a British physicist, had predicted two broad lotus petal-like structures (known as helmet streamers) on the southeast (lower-left as viewed from Earth) and southwest (lower-right) edge of the Sun, and a third, narrow elongated streamer structure on the northwest (upper-right) edge of the Sun for the solar eclipse on August 21. The team also rightly predicted that the southeast (upper-left) edge of the Sun will be the least active.

Dr Nandi and the team of researchers

“These predictions have all been largely verified”, said Niruj Mohan, Chair of the Astronomy Society of India’s Committee on Public Outreach and Education. Preliminary inspection shows the team also rightly predicted location for all the streamers except the one on the southeast (lower-right) edge which is observed to be closer to the Sun’s equator than predicted.

The close correspondence between the prediction and observations is an impressive feat for a first attempt which utilized only modest and limited computing powers without recourse to supercomputers. “We got it right on all counts except notable few features, that too with modest facilities we have,” pointed out Nandi. However, he said, “we were not able to reproduce some fine details since out model is not complex enough. We were working on the model and this opportunity arose and we thought why not test our model to see if we are in the right path.”

Scientists will be performing a more detailed analysis as more data comes in. “We are very satisfied with the overall success of their prediction,” noted Somak Raychaudhury, Director of Inter-University Centre for Astronomy and Astrophysics (IUCAA), Pune.

It was a sleepless night for Nandi’s team. “I told my students not to be disappointed if we had got it wrong. After all, this was the first time we were testing our model with live a cosmic event,” said says Nandi. “None of us even winked. We were all awake all through the night and remained glued to the live broadcast on NASA TV. Only when the first clear sharp images of the corona came in late night that we could relax”.

The magnetic lines protruding out of the sun make up the solar sunspots, but the team realised that the overall structure of the solar corona is dependent more on the memory of slow changes and accumulated history in the magnetic field distribution on the Sun’s surface. “By incorporating all the sunspots that have emerged on the Sun’s surface over the past century, we were able to make computer simulation for possible surface magnetic field on August 21, the day of the total solar eclipse, even with comparatively less powerful computers than the US team,” explained Nandi.

The structure of solar corona basically mirrors the invisible magnetic fields, just as the iron filings align along the butterfly shaped magnetic lines around a bar magnet in our high school physics experiments. However, in the blazing sunlight the corona is invisible, and can be seen only during the total solar eclipse. The magnetic structure of sun impacts the space weather, which in turn has implication for satellite communication, electric grids etc. on the earth.

The relative success of the model has implications the solar observatory, Aditya-L1, to be launched by the Indian Space Research Organisation (ISRO). It will include Visible Emission Line Coronagraph (VELC) instrument designed and developed by Dipankar Banerjee of Indian Institute of Astrophysics. It artificially creates a total solar eclipse in space by blocking emissions coming from the solar disk, revealing otherwise invisible corona. “The work by Nandi’s team will let us directly compare observed images with these models and help us understand the corona better” said Banerjee.

“This work demonstrates success of IISER mandate, which is to integrate world class research with graduate and under-graduate education, and produce high class manpower for research,” said Prasanta K. Panigrahi, director, IISER Kolkata.

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The team included Dibyendu Nandi, Prantika Bhowmik, Suman Panda, Rajashik Tarafder, and Soumyaranjan Dash from CESSI, IISER Kolkata; and Anthony R. Yeates from Durham University, UK. (India Science Wire)


Twitter handle: @TVVen

 

Mega science projects: India poised to join league of global scientific leaders

Dr T V Venkateswaran

New Delhi: Shedding its hesitant and cautious approach of the past with regard to participating in global mega science projects, India has taken bold steps in recent years to join international scientific quests.

The Science Technology and Innovation policy of 2013 envisages positioning India among the top five global scientific powers by 2020. In addition to home-grown science and engineering projects, the policy advocated participation in global science projects arguing that as a civilised country we must also participate in global mega science projects aiming to find out for example the ultimate structure of matter or the origin of the universe.

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Here are some of India’s Big Science initiatives:

Feeling the fabric of space-time: The detection of gravitational waves for the first time in February 2016 after a century of speculation and decades of tenacious attempts to improve sensitivity of instruments to detect these elusive waves, was hailed as the ‘discovery of the century’. Of over 1000 scientists from 15 countries who jointly made this discovery, 39 were from India. Indian scientists made direct contributions – ranging from designing algorithms used to analyse signals registered by detectors to ascertain those from a gravitational wave to working out parameters like estimating energy and power radiated during merger, orbital eccentricity and estimating the mass and spin of the final black hole and so on. Currently there are only two detectors in operation, both in America. Building on their strength, Indian astronomers are proposing to build the third detector somewhere in Maharashtra. Called Indian LIGO (IndiGO), the instrument matching the two LIGO observatories in the US would enable scientists to pinpoint the source of gravitational waves.

Big Bang: India became a full Associate Member of “God particle” fame CERN on January 16, 2017, thereby getting full access to data generated at the world’s largest particle physics laboratory. Currently, CERN has 22 member states. Indian scientists have helped build the Large Hadron Collider (LHC), the most powerful particle collider in the world as well as construction of two significant CERN experiments, CMS and ALICE. Incidentally CMS is one of the two experiments that discovered the Higgs Boson, popularly called as ‘God particle’ and ALICE creates conditions that existed at the time of big bang.

Digging deep: Shivajisagar lake was impounded in the Koyna region in Maharashtra to create an artificial reservoir in 1962. The massive earthquake of magnitude 6.3 that occurred in 1967 brought to light dangers of Reservoir Triggered Seismicity (RTS). Since its construction, the region has witnessed 22 earthquakes exceeding magnitude 5, 200 exceeding magnitude 4 and several thousand smaller earthquakes. Indian geophysicists have drilled a seven-km deep borehole in this earthquake zone and have established an on-the-spot observatory to study earthquakes. The observatory is studying physical and mechanical properties of rocks before, during and after a quake; physical and chemical changes in the earth’s crust that occur during an earthquake; and temperature change that impels melting of rocks. Geologists are hopeful that the knowledge garnered from the web of 15 earthquake sensors and the on-spot data collection, has potential for making earthquake forecasts possible in future.

Making of atoms: India is part of the international Facility for Antiproton and Ion Research (FAIR) coming up at Darmstadt, Germany for studying the building blocks of matter and the evolution of the Universe. This sophisticated accelerator complex will use high-energy, precisely-tailored ion beams to mimic the conditions inside the core of stars and early phase of the universe.

The 1.2-billion euro facility will study the structure of matter and the evolution of the universe since the Big Bang. While the Helium and hydrogen was formed in the early universe, rest of the elements it is postulated were cooked inside the stars. The facility would also shed light on the creation of heavy elements in stars and also the interiors of planets. Indian institutions will be engaged in building NUSTAR (Nuclear Structure, Astrophysics and Reactions), CBM (Compressed Baryonic Matter) and PANDA (Antiproton Annihilation at Darmstadt) in addition to building equipment to be used at the heart of the FAIR accelerator.

Looking back in time: India has joined nine other nations to build the world’s largest and most sensitive radio telescope – Square Kilometre Array (SKA). It will combine signals received from thousands of small parabolic and dipole antennas spread over a distance of several thousand kilometres across Africa and Australia. Karoo desert in South Africa will host the core of the 350 megahertz to 14 gigahertz mid-frequency dish array while the Australian telescope will observe lower-frequency scale, from 50 to 350 megahertz and the total detection area of the receiver dishes would exceed 1 square kilometre. A large number of dipole antennas are capable of receiving very low frequencies while the 3000 odd parabolic antennas operate at higher frequencies. Combining signals from all these thousands of antennas would simulate a single giant radio telescope with extremely high sensitivity. The sensitivity of this radio telescope would be fifty times more than any other radio telescope and it will be able to survey the sky 10,000 times faster enabling astronomers to even capture faint radio signals emitted by cosmic sources billions of light years away from Earth. With such a powerful telescope, astronomers could peer deep into the universe, way back in time when the first stars were emerging.

Shining like Sun: The International-Thermonuclear-Experimental-Reactor (ITER) has embarked upon an ambitious project to build a little bit of Sun in laboratory conduction. While the conventional nuclear reactor breaks a heavy atom like plutonium to gather the binding energy, the fusion reactor will fuse two light elements like say hydrogen into helium to harness the energy. As fusion reactors will not use any radioactive materials, yet generate immense energy, it is considered as a clean-green source of energy. The high temperature in the core of the stars results in light elements becoming highly ionised and attain plasma state. It is in this plasma state that two or more light elements could fuse. If we have to re-create such a condition on Earth, then we need to make a small amount of hydrogen into plasma before we can achieve fusion. One of the challenges is to contain high temperature plasma in a confinement to achieve the fusion. The experimental nuclear fusion reactor being built at Cadarache in south of France hopes to harness fusion reaction to generate energy. European Union, United States, Japan, China, Russia, South Korea and India are jointly building and operating this test facility. Institute for Plasma Research, Ahmedabad is contributing crucial parts of the tokamak reactor’s gigantic cryostat.

Predicting rain: The India Meteorological Department (IMD) is developing a dynamic weather prediction model involving 3D mathematical simulation of the atmosphere on computer and to test variations of dynamic models to ferret out the best ones for operational forecast of rainfall. While the ultimate goal is to get operational weather forecasts at a horizontal resolution of 12 km, by 2019 National Monsoon Mission will provide block level weather forecast. With the improvements in forecast, 24-hour track and intensity forecast error of the tropical cyclones reduced from 141 km to 97 km and ‘landfall error’ from 99 km to 56 km during 2006 to 2015. The accurate forecast of the recent cyclones, Phailin, HudHud and Vardah saved thousands of human lives.

Churning the sea: Using research vessel, Gaveshani, Indian researchers had collected samples of poly metallic nodules from Arabian Sea in 1981 and India was given a pioneer area for exploration of deep sea minerals in the Central Indian Ocean Basin in 1987. Subsequently extensive surveys were carried out leading to allocation of an area of 150,000 sq km with exclusive rights under the UN Law of the sea. India has access to an area of 75,000 sq km with an estimated resource of about 100 million tons of strategic metals such copper, nickel, cobalt besides manganese and iron. As various national institutions have developed technologies for extraction of metals from the minerals, soon India would establish First Generation Mine-site (FGM) with an area of 18,000 sq km and harvest natural resources from the sea-bed. The multi-purpose deep ocean mission would also try to harness deep ocean energy, deep sea fishing along with deep sea mining. Further technologies for sea water desalination to obtain potable water would also be undertaken.

Looking deep: The Thirty Meter Telescope (TMT), world’s advanced ground based telescope, is expected to outsmart all ground-based telescopes once it is operational. Made of 492 individual segments, the telescope mirror would have a reflective diameter of 30 meters and would be 81 times more powerful than any other telescope. It a partnership project involving CalTech, Universities of California, Canada, Japan, China and India. While initial location chosen was Hawaii, Hanle in Ladakh was also considered as an alternative. However, it may perhaps be finally located in Chile. Building of such a massive telescope is a technological challenge. The mirror segments have to be aligned precisely with each other and the adoptive optics proposed would eliminate the twinkling effect caused by atmospheric thermal disturbances. India will develop and manufacture 15% of the mirror segments and assembly.

Reaching for stars: India had dazzled the world by reaching Mars in very first attempt. Indian spacecraft reached the moon before that. Currently AstroSAT a multi wavelength space telescope is operational. ISRO in coming years would add many more deep space missions to its credit. Chandrayan 2- with a lander and rover is proposed to be launched some time inn 2018-19. A mission to study the Sun – Aditya, is in the offing. Building upon the success of the Mars Orbiter Mission, ISRO is planning to send yet another spacecraft to study Mars. Indian space programme in addition to providing telecom, weather, navigational services, would also take a pride of place among the spacefaring nations of the world.

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Technological spinoffs of mega projects such as LHC or FAIR are immense. Technology developed in CERN went into making mammograms used for breast cancer detection, while the positron used in particle physics experiments gave us PET (Positron Emission Tomography). The study of fundamental particles is sure to yield newer imaging technologies. That’s why it is important to invest in mega science projects. (India Science Wire)


Dr T V Venkateswaran, Twitter handle: @TVVen