Neutron-star merger yields new puzzle for Astrophysicists

by Sidhi.S.L.Nair(2016-2019)

Sidnair017@gmail.com

*Afterglow from cosmic smash-up continues to brighten, confounding expectations*

January 18, 2018

McGill University

The afterglow from the distant neutron-star merger detected last August has continued to brighten – much to the surprise of astrophysicists studying the aftermath of the massive collision that took place about 138 million light years away and sent gravitational waves rippling through the universe. New observations indicate that the gamma ray burst unleashed by the collision is more complex than scientists initially imagined.

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[[This graphic shows the X-ray counterpart to the gravitational wave source GW170817, produced by the merger of two neutron stars. The left image is the sum of observations with NASA’s Chandra X-ray Observatory taken in late August and early Sept. 2017, and the right image is the sum of Chandra observations taken in early Dec. 2017. The X-ray counterpart to GW170817 is shown to the upper left of its host galaxy, NGC 4993, located about 130 million light years from Earth. The counterpart has become about four times brighter over three months. GW170817 was first observed on Aug. 17, 2017.

Credit: NASA/CXC/McGill/J.Ruan et al.]]

The afterglow from the distant neutron-star merger detected last August has continued to brighten — much to the surprise of astrophysicists studying the aftermath of the massive collision that took place about 138 million light years away and sent gravitational waves rippling through the universe.

New observations from NASA’s orbiting Chandra X-ray Observatory, reported in Astrophysical Journal Letters, indicate that the gamma ray burst unleashed by the collision is more complex than scientists initially imagined.

“Usually when we see a short gamma-ray burst, the jet emission generated gets bright for a short time as it smashes into the surrounding medium — then fades as the system stops injecting energy into the outflow,” says McGill University astrophysicist Daryl Haggard, whose research group led the new study. “This one is different; it’s definitely not a simple, plain-Jane narrow jet.”

{ Chandra X-ray Observatory}

Cocoon theory

The new data could be explained using more complicated models for the remnants of the neutron star merger. One possibility: the merger launched a jet that shock-heated the surrounding gaseous debris, creating a hot ‘cocoon’ around the jet that has glowed in X-rays and radio light for many months.

The X-ray observations jibe with radio-wave data reported last month by another team of scientists, which found that those emissions from the collision also continued to brighten over time.

While radio telescopes were able to monitor the afterglow throughout the fall, X-ray and optical observatories were unable to watch it for around three months, because that point in the sky was too close to the Sun during that period.

“When the source emerged from that blind spot in the sky in early December, our Chandra team jumped at the chance to see what was going on,” says John Ruan, a postdoctoral researcher at the McGill Space Institute and lead author of the new paper. “Sure enough, the afterglow turned out to be brighter in the X-ray wavelengths, just as it was in the radio.”

Physics puzzle

That unexpected pattern has set off a scramble among astronomers to understand what physics is driving the emission. “This neutron-star merger is unlike anything we’ve seen before,” says Melania Nynka, another McGill postdoctoral researcher. “For astrophysicists, it’s a gift that seems to keep on giving.” Nynka also co-authored the new paper, along with astronomers from Northwestern University and the University of Leicester.

The neutron-star merger was first detected on Aug. 17 by the U.S.-based Laser Interferometer Gravitational-Wave Observatory (LIGO). The European Virgo detector and some 70 ground- and space-based observatories helped confirm the discovery.

The discovery opened a new era in astronomy. It marked the first time that scientists have been able to observe a cosmic event with both light waves — the basis of traditional astronomy — and gravitational waves, the ripples in space-time predicted a century ago by Albert Einstein’s general theory of relativity. Mergers of neutron stars, among the densest objects in the universe, are thought to be responsible for producing heavy elements such as gold, platinum, and silver.

 

Mitra;India’s Proud indigenous Robot

by Abhijith.A.D(2016-2019)

https://www.facebook.com/abhijith.vjmd 

Name of the Company: Invento Robotics
Name of Founder (s): Balaji Vishwanathan, Mahalakshmi Radhakrushnan, Bharath Kumar
City: Bengaluru
Revenues: NA
Headcount: 14
Industry: Robotics
Investors Details & Amount raised: Bootstrapped, Secured Loan

Invento Robotics wants to ‘Make in India’ for the world and getting Ivanka Trump and Narendra Modi to start your marketing campaign counts as a good first step towards that objective.

At the Global Entrepreneurship Summit being held in Hyderabad, the Indian Prime Minister and the US President’s daughter will come face-to-face with Mitra – a humanoid. A humanoid made in India, for the world.

Practice, not preach
Invento Robotics came into existence last year in October 2016 after the founders pivoted from their educational startup named Invento Makerspaces. “We wanted to change education with a maker-centric approach, but it turned out to be harder than we had anticipated,” shares Balaji Vishwanathan.

It was in 2015 when a robot made by a team of Invento garnered much appreciation during a maker fair that made the founders realise that a proof of concept may work better to inspire.

The proof of concept can now be found walking in the corridors of Canara Bank and PVR Cinemas in Bengaluru, greeting consumers and telling them what they like best. Capable of face detection, face recognition, speech recognition, contextual support, and autonomous navigation; Mitra is a 5 ft tall humanoid.The 5-foot-tall is also serving humans in a few Canara Bank branches as well as PVR Cinema outlets in Bengaluru. Through http://www.mitrarobot.com, Invento Robotics allows Mitra robot for rent for interactive sessions at offices, hotels, and even private birthday parties.

“What Google does for the online world, we do for the offline world. The robot speaks to the customers, gets to know them and their preferences, and on subsequent visits makes contextual suggestions. Mitra can help businesses do better customer targeting. For instance, in supermarkets, Mitra is capable of collecting relevant data on your first visit and not only make suggestions on your corresponding visits, but also take you to that particular aisle,” explains Vishwanathan.

Mitra, adds Vishwanathan, can be used as a customer service agent in multiple domains like banks, hospitals, airports, hotels . The startup is currently focussing on two sectors – BFSI and retail sectors.

Six months after getting their first Mitra, Vishwanathan claims Canara Bank is already in the process of getting the robot working for them in 500 of their branches. “The bank has also extended a loan of Rs 80 lakh to us which would enable us to further expand and upgrade our services,” adds Vishwanathan.

The founders decided to go for a conventional route to fund their growth aspirations after the VC market in India failed to show much interest.

“Hardware ecosystem in India is very nascent and thus will take time in supporting high-end tech-savvy hardware products. Naturally, the guidance we were seeking in running a hardware startup was not easily available. The investor ecosystem also was not primarily looking for hardware products – hence funding was hard,” shares Vishwanathan.

It’s programmed to greet customers and interacts using facial and speech recognition, contextual help, and autonomous navigation.

 

 

[Ivanka Trump and Prime Minister Narendra Modi were welcomed to the event in Hyderabad by Mitra, a robot built by Bengaluru-based Invento Robotics. Mitra was one of two of the company’s humanoid bots present at the event.]

 

 

Black hole research could aid understanding of how small galaxies evolve

by Sidhi.S.L.Nair(2016-2019)

Sidnair017@gmail.com

January 9, 2018

University of Portsmouth

Summary:

Scientists have solved a cosmic mystery by finding evidence that supermassive black holes prevent stars forming in some smaller galaxies.

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Size comparison of a dwarf galaxy (right inset, bottom) with a larger galaxy in the centre. Top inset: Dwarf galaxy overlain with some of the MaNGA data, revealing the winds from the supermassive black hole.

Credit: Samantha Penny (Institute of Cosmology and Gravitation, University of Portsmouth) and the SDSS collaboration

Scientists have solved a cosmic mystery by finding evidence that supermassive black holes prevent stars forming in some smaller galaxies.

These giant black holes are over a million times more massive than the sun and sit in the centre of galaxies sending out powerful winds that quench the star-making process. Astronomers previously thought they had no influence on the formation of stars in dwarf galaxies but a new study from the University of Portsmouth has proved their role in the process.

The results, presented today at a meeting of the American Astronomical Society, are particularly important because dwarf galaxies (those composed of up to 100 million to several billion stars) are far more numerous than bigger systems and what happens in these is likely to give a more typical picture of the evolution of galaxies.

“Dwarf galaxies  outnumber larger galaxies like the Milky Way 50 to one,” says lead researcher Dr Samantha Penny, of the University’s Institute of Cosmology and Gravitation. “So if we want to tell the full story of galaxies, we need to understand how dwarf systems work.”

In any galaxy stars are born when clouds of gas collapse under the force of their own gravity. But stars don’t keep being born forever — at some point star formation in a galaxy shuts off. The reason for this differs in different galaxies but sometimes a supermassive black hole is the culprit.

Supermassive black holes can regulate their host galaxy’s ability to form new stars through a heating process. The black hole drives energy through powerful winds. When this wind hits the giant molecular clouds in which stars would form, it heats the gas, preventing its collapse into new stars.

Previous research has shown that this process can prevent star formation in larger galaxies containing hundreds of billions of stars — but it was believed a different process could be responsible for dwarf galaxies ceasing to produce stars. Scientists previously thought that the larger galaxies could have been interacting gravitationally with the dwarf systems and pulling the star-making gas away.

Data, however, showed the researchers that the dwarf galaxies under observation were still accumulating gas which should re-start star formation in a red, dead galaxy but wasn’t. This led the team to the supermassive black hole discovery.

Dr Penny said: “Our results are important for astronomy because they potentially impact how we understand galaxy evolution. Supermassive black holes weren’t thought to influence dwarf systems but we’ve shown that isn’t the case. This may well have a big influence on future research as simulations of galaxy formation don’t usually include the heating effect of supermassive black holes in low-mass galaxies, including the dwarf systems we have examined in this work.”

The team of international scientists used data from the Sloan Digital Sky Survey (SDSS), which has a telescope based in New Mexico, to make their observations. Using SDSS’s Mapping Nearby Galaxies at Apache Point Observatory (MaNGA) survey, they were able to map the processes acting on the dwarf galaxies through the star systems’ heated gas, which could be detected. The heated gas revealed the presence of a central supermassive black hole, or active galactic nucleus (AGN), and through MaNGA the team were able to observe the effect that the AG

Black hole spin cranks-up radio volume

by Sidhi.S.L.Nair(2016-2019)

Sidnair017@gmail.com

January 12, 2018

National Institutes of Natural Sciences

Summary:

Statistical analysis of supermassive black holes suggests that the spin of the black hole may play a role in the generation of powerful high-speed jets blasting radio waves. By analyzing nearly 8000 quasars from the Sloan Digital Sky Survey, research team found that the oxygen emissions are 1.5 times stronger in radio loud quasars than in radio quiet quasars. This implies that spin is an important factor in the generation of jets.

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[The rotation of the black hole may cause the high-speed jet which makes the object radio-loud.

Credit: NAOJ

Statistical analysis of supermassive black holes suggests that the spin of the black hole may play a role in the generation of powerful high-speed jets blasting radio waves and other radiation across the Universe.

Black holes absorb light and all other forms of radiation, making them impossible to detect directly. But the effects of black holes, in particular accretion disks where matter is shredded and superheated as it spirals down into the black hole, can release enormous amounts of energy. The accretion disks around supermassive black holes (black holes with masses millions of times that of the Sun) are some of the brightest objects in the Universe. These objects are called “quasi-stellar radio sources” or “quasars,” but actually this is a misnomer; only about 10% of quasars emit strong radio waves. We now know that “radio loud” quasars occur when a fraction of the matter in the accretion disk avoids the final fate of falling into the black hole and comes blasting back out into space in high-speed jets emitted from the poles of the black hole. But we still don’t understand why jets form some times and not other times.

A team led by Dr. Andreas Schulze at the National Astronomical Observatory of Japan investigated the possibility that the spin of the supermassive black hole might play a role in determining if the high-speed jets form. Because black holes cannot be observed directly, Schulze’s team instead measured emissions from oxygen ions [O III] around the black hole and accretion disk to determine the radiative efficiency; i.e. how much energy matter releases as it falls into the black hole. From the radiative efficiency they were able to calculate the spin of the black hole at the center.

By analyzing nearly 8000 quasars from the Sloan Digital Sky Survey, Schulze’s team found that on average the O III oxygen emissions are 1.5 times stronger in radio loud quasars than in radio quiet quasars. This implies that spin is an important factor in the generation of jets.

Schulze cautions, “Our approach, like others, relies on a number of key assumptions. Our results certainly don’t mean that spin must be the only factor for differentiation between radio-loud and radio-quiet quasars. The results do suggest, however, that we shouldn’t count spin out of the game. It might be determining the loudness of these distant accreting monsters.”

Story Source:

Materials provided by National Institutes of Natural Sciences. [Note: Content may be edited for style and length].

Journal Reference:

Andreas Schulze, Chris Done, Youjun Lu, Fupeng Zhang, Yoshiyuki Inoue. Evidence for Higher Black Hole Spin in Radio-loud Quasars. The Astrophysical Journal, 2017; 849 (1): 4 DOI: 10.3847/1538-4357/aa9181

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National Institutes of Natural Sciences. “Black hole spin cranks-up radio volume.” ScienceDaily. ScienceDaily, 12 January 2018. <www.sciencedaily.com/releases/2018/01/180112095929.htm>.

3D Printing

by Anaswara.J.S.(2016-2019)

anaswarajs@gmail.com

3 D Printing  is an additive manufacturing process that creates a physical object from a digital design.

Principle:

a digital model is turned into a solid three-dimensional physical object by adding material layer by layer.

How does 3D printing work?

Every 3D print starts as a digital 3D design file – like a blueprint – for a physical object. Trying to print without a design file is like trying to print a document on a sheet of paper without a text file. This design file is sliced into thin layers which is then sent to the 3D printer.
From here on the printing process varies by technology , starting from desktop printers that melt a plastic material and lay it down onto a print platform to large industrial machines that use a laser to selectively melt metal powder at high temperatures. The printing can take hours to complete depending on the size, and the printed objects are often post-processed to reach the desired finish.
Available materials also vary by printer type, ranging from plastics to rubber, sandstone, metals and alloys – with more and more materials appearing on the market every year.

History of 3D Printing

Although 3D printing is commonly thought of as a new ‘futuristic’ concept, it has actually been around for more than 30 years.

SLA-1 is the first 3D printer invented by Chuck Hull in 1983

Chuck Hull invented the first 3D printing process called ‘stereolithography’ in 1983. In a patent, he defined stereolithography as ‘a method and apparatus for making solid objects by successively “printing” thin layers of the ultraviolet curable material one on top of the other’. This patent only focuses on ‘printing’ with a light curable liquid, but after Hull founded the company ‘3D Systems’, he soon realized his technique was not limited to only liquids, expanding the definition to ‘any material capable of solidification or capable of altering its physical state’. With this, he built the foundation of what we now know today as additive manufacturing (AM) – or 3D printing.

3D printing  -today

Until 2009 3D printing was mostly limited to industrial uses, but then the patent for fused deposition modeling (FDM) – one of the most common 3D printing technologies – expired.
Through the RepRap project’s mission to build a self-replicating machine, the first desktop 3D printer was born. As more and more manufacturers followed, what once cost $200,000 suddenly became available for below $2000, and the consumer 3D printing market took off in 2009.

3D printer sales have been growing ever since, and as additive manufacturing patents continue to expire. More innovations can be expected in the years to come. There are now roughly 300,000 consumer 3D printers in the world – and this figure is doubling every year.
Carbon 3D , one of the fastest 3D printing technologies is currently under development

                                                             

• Traditional manufacturing works by taking a material such as metal, glass or plastic and reducing and manipulating it into a solid object. This requires expensive tools and can be a very wasteful process, as often much of the original raw material is thrown away during the manufacture of the product.
• Additive manufacturing. Three dimensional objects are created from a digital file, so there is no waste.
• Ability to produce customised goods quickly and relatively cheaply. Customisation is increasingly important, as consumers and businesses want to personalise and set their products and goods apart. In an industrial environment, components may need to be marked with instructions, or codes to differentiate parts.
• 3D printing puts the power in the hands of the creator and that means that it is easier to generate customised products. The same build chamber can be used to produce multiple products that are identical apart from their customised components without adding the processing costs associated with more traditional techniques.
• Because the product is created direct from the printer, both labour time and therefore costs can be dramatically reduced. This is important in a competitive environment where products have to be delivered to tight time schedules and budgets.
• Traditional mass production techniques involve stockpiling components and parts, which can be expensive to produce, ship and house.
• Employing people to manage these processes can be expensive and finding warehouse space to hold goods and transporting them is costly, not to mention damaging to the environment.
• With 3D printing, manufacturers can follow the principals of lean manufacturing by cutting out waste generated by transportation, inventory, motion, waiting, over-processing, over-production and defects
• ECO FRIENDLY

• The first and most obvious one is the fact that as a technology it is still very much in its infancy. In time, it may well address limitations such as the type of material that can be produced in a 3D environment, or it may be that it sits alongside other manufacturing techniques.
• Print speed is another potential limitation and one that could be improved over time, but means that the process is not as timely as it might be. Other computer-based manufacturing techniques may sometimes be preferable if time is a vital factor.
•  They are not always easy to master, and in-depth training is often required to manage these complex machines.
• This can of course be costly to manufacturers and these costs may end up being absorbed by the consumer.

Because objects can be produced without tools, there is also the possibility that operators will produce too many components without considering the waste.

 The Future of 3-D Printing

3-D printing is moving in several directions at this time and all indications are that it will continue to expand in many areas in the future. Some of the most promising areas include medical applications, custom parts replacement, and customized consumer products. As materials improve and costs go down, other applications we can barely imagine today will become possible.

 

 

 

SOPHIA ; THE FIRST ROBOT CITIZEN

by Abhijith.A.D(2016-2019)

https://www.facebook.com/abhijith.vjmd

In October 2017, Sophia became a Saudi Arabian citizen, the first robot to receive citizenship of any country. In November 2017, Sophia was named the united nations development programme’s first ever Innovation Champion, and the first non-human to be given any United Nations title.

Sophia is a social humanoid robot developed by Hongkong-based company Hanson Robotics. Sophia was activated on April 19, 2015 and made her first public appearance at  SXSW in mid-March 2016 in Austin, Texas, United States. She is able to display more than 62 facial expressions.

Sophia has been covered by media around the globe and has participated in many high-profile interviews. While interviewers around the world have been impressed by the sophistication of many of Sophia’s responses to their questions, the bulk of Sophia’s meaningful statements are believed by experts to be somewhat scripted.

Features

*Cameras within her eyes combined with computer algorithms allow Sophia to see. She can follow faces, sustain eye contact, and recognize individuals.

*She is able to process speech and have conversations using Alphabet’s Google Chrome voice recognition technology and other tools.

*Sophia is conceptually similar to the computer program ELIZA which was one of the first attempts at simulating a human conversation. The software has been programmed to give pre-written responses to specific questions or phrases, like a  chatbot . These responses are used to create the illusion that the robot is able to understand conversation, including stock answers to questions like “Is the door open or shut?”

*The information is shared in a cloud network which allows input and responses to be analysed with blockchain technology.

*Sophia runs on artificially intelligent software that is constantly being trained in the lab, so her conversations are likely to get faster, Sophia’s expressions are likely to have fewer errors, and she should answer increasingly complex questions with more accuracy.

Sophia ,the wonder child of robotics,also visits india to attend Tech fest conducted at IIT BOMBAY last year.

Sophia addressing the students at IIT BOMBAY

SHOCKING FACT

*Before being known for receiving a one-of-a-kind citizenship, Sophia achieved minor notoriety when an alleged technical glitch led her to say that SHE WOULD DESTROY HUMANS.

YouTube Video of SOPHIA

by JithinRaj R.S(2016-2019)

https://www.facebook.com/jrnair.rs