Biggest Cosmic Nuclear Bombs -- See the First Supernovae in Cutting-edge Supercomputer Simulations

A 2-D snapshot of a pair-instability supernovae as the explosion waves is about to break through the star's surface. The tiny disturbs represent fluid instability - in a region where different elements interact and mix. Image Credit: ASIAA/Ken Chen

A 3-D profile of a pair-instability supernovae. The blue cube shows the entire simulated space. Orange region is where nickel 56 decays. Image Credit: ASIAA/Ken Chen

A hypernova is a type of supernovae that are 100 times more energetic. Astronomers think these biggest cosmic bombs hold the key to peek into genesis moment of first supernovae birth. However, hypernovae are extremely rare in observation. Therefore, the ASIAA team led by Ke-Jung (Ken) Chen, using the NAOJ’s CfCA supercomputer, has completed high-resolution simulations to tackle this issue. By exploring deeply into the core, they discovered what hypernovae would look like after 300 days of their explosion. The highly innovative work offers an unprecedented conclusion: the effect which gas movement has on the luminosity estimation, has long been overlooked in previous theoretical models. This result boosts our understanding of hypernova formation and may prove to be instrumental in the future hypernova observations.

Right after the big bang, the only elements produced in the universe were hydrogen and helium, all the other natural elements did not come about until after the first stars born and evolved. To understand how the first stars and the elements formed in the first place necessitates the research on supernova. Nearly 50 years of supernova research has simply proven to us: it is not an easy task, many mysteries still open. Thinking that hypernova plays a key role in the breaking-through, the ASIAA Ken Chen team took a deep look into the heart of hypernova by numerical simulations. Because, despite hypernova ejects 100 times more energy than supernovae, observationally, it is in fact extremely rare. And that’s where astronomers start looking for help from good theoretical models and supercomputer simulations.

There are currently two theoretical models of how hypernovae formed, and Chen's team chose to build their simulations on the pair-instability supernovae model -- the one that is highly anticipated and relatively more robust (the other is called the core-collapse supernovae model, or, “the black hole model”). The difference between them is that one (the later) leaves a black hole, and the other (the former) doesn't even leave a black hole when it completely blows itself up. Usually when massive stars explode, they leave something behind – either a dense core called a neutron star or a black hole. But for the massive stars - the first stars in the universe - there was only hydrogen and helium, no traces of other elements yet. These very massive first stars can begin making pairs of electron-positrons in the end of their evolution, causing a runaway effect where the pressure drops in the star’s core, triggering a collapse, leading to an enormous explosion that completely disrupts the star, leaving nothing behind, not even a black hole.

"A star must be 140-260 times the mass of the Sun to die in such a manner" Chen said. Astronomers call stars that explode in this way the “pair-instability supernovae” (where the “pair” means the electron – positron pair.)

Such an explosion produces a large amount of radioactive isotope Ni 56, which according to Chen, is “the most important element in a supernova, because its decay energy accounted for most of the visible light of a supernova, and without it, many supernovae would have been too dark to observe".

The international team led by Ken Chen has used the NAOJ's CfCA supercomputer to run their high resolution hydrodynamical simulation for hypernova. Describing the code and the running “extremely challenging”, Chen explains, “larger the simulation scale, to keep the resolution high, the entire calculation will become very difficult and demand much more computational power, not to mention that the physics involved is also complicated.” To combat these, Chen said, their best advantage is their “well-craft code and a robust program structure.”

While previous simulations run for pair-instability supernovae model have only done 30 days after the explosion, Chen's team has run the simulation up to 300 days -- which allow them to study the entire decay process of Ni 56 (which has a half-life of 70 days, so the simulation had to be long enough). They are the first team who has done this. With extensive experience in simulating large scale supernovae, the team probed the relationship between the gas movement and energy radiation inside the supernova. What they found is that during the initial decay of Nickel 56, the heated gas expanded and formed thin-shell structures.

Chen said, "the temperature inside the gas shell is extremely high, from calculation we understand that there should be ~ 30% energy used in gas movement, then the remaining ~ 70% energy can likely become the supernova luminosity. Earlier models have ignored the gas dynamic effects, so the supernova luminosity results were all overestimated.”

Therefore, in the field of pair instability supernovae study, these results will certainly contribute to the further understanding of its radiation mechanism and observational characteristics.Several studies showed that the mass of first stars in the universe would be 100 to 300 solar masses, somewhat hint that the chances for first supernovae to be pair-instability supernovae could really be high. On the other hand, the first stars may be detectable by the James Webb Space Telescope (JWST) - the successor to the Hubble Space Telescope - making the observation and theoretical work of pair-instability supernovae an important subject in the near future.

Source: Academia Sinica Institute of Astronomy and Astrophysics (ASIAA)

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Terminology explained:

Hypernova: A hypernova is a type of stellar explosion which ejects material with an unusually high kinetic energy, an order of magnitude higher than most supernovae.

Massive Star: A massive star is a star that is larger than eight solar masses during its regular main sequence lifetime.

Pair-instability supernovae model: Massive stars, between about 130 and 250 solar masses, are thought to lead to a pair-instability supernovae (PISN). In these stars, electron-positron pairs are created in the core. This leads the star to become dynamically unstable and leads to the collapse then explosion of these stars.

Core-collapse supernovae model: Core-collapse supernovae are dramatic explosions of giant stars at the end of their thermonuclear evolution giving birth to neutron stars and black holes.

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More Information:

Paper: Gas Dynamics of the Nickel-56 Decay Heating in Pair-Instability Supernovae published on July 14th. by The Astrophysical Journal

Authors are: KE-JUNG CHEN,S. E. WOOSLEY, AND DANIEL J. WHALEN

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Media Contact:

Assistant Research Fellow Ken Chen
Email: kjchen@asiaa.sinica.edu.tw
Tel: (02)2366-5457

Article written by: Ken Chen & Lauren Huang

Webpage Editor: Lauren Huang

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Detection of the relativistic cocoon structure around the ultra-relativistic Jet

Imaginary picture of GRB jet

Credit: Yuji Urata

Using the combined power of the Submillimeter Array (SMA) and NASA’s and JAXA’s satellite missions, a team led by Mr. Wei Ju Chen, Prof. Urata and Dr. Asada (ASIAA) in Taiwan has confirmed the shocked jet cocoon afterglow of a Gamma-Ray Burst (1) through the observation of an energetic GRB, GRB160623A. The team utilizes multi-frequency observations including long-term monitoring in a submillimeter range to characterize the two components of jets. For both the two populations of the GRBs, short and long GRBs, understanding of the jet and its structure is essential. Although the structured jet of short GRB has not yet observationally confirmed, numerous theoretical models are trying to use the off-axis viewing of the short GRB jet including its structures to explain the unusual weak short GRB170817 associated with the gravitational wave transient GW170817 caused by binary neutron star merger. Therefore, this result would be feedback to the multi-messenger (2) astrophysics.

GRB is believed to be stellar explosions accompanied with relativistic outflows and narrowly-collimated jets. Since direct imaging of GRB jets is impossible unlike AGN jets, studying the GRB jet collimation and its structure have been made by the multi-frequency monitoring observations. Based on the past observations, the typical value of GRB jet opening-angles is 3.5 deg, which is in the same order with that of AGN jets (1.5 deg). In this time, the team made use of the submillimeter-observations using SMA, which has been playing an essential role in revealing new insights of the GRB afterglows (3) and relativistic transients (4). Their observations revealed that the temporal and spectral evolutions of the radio afterglow agree with those expected from a synchrotron radiation modelling with typical physical parameters except for the fact that the observed wide jet opening angle (~30 deg) for the submillimeter emission is significantly larger than the theoretical maximum opening angle. By contrast, the opening angle ( less  then 4.5 deg) of the X-ray afterglow is consistent with the typical value of GRB jets. Since the theory of the relativistic cocoon afterglow emission is similar to that of the regular afterglow with the jet opening angle wider than that of regular afterglow, the observed radio emission can be interpreted as the shocked jet cocoon emission. This result therefore indicates that the two components of the jets observed in the GRB 160623A afterglow is caused by the jet and the shocked jet cocoon afterglows.

Prof. Urata emphasizes that “the jet structure and unification of various relativistic transients with viewing angle are crucial for multi-messenger astrophysics and submillimeter observations become the critical part of the transient sciences. On the other hand, the unification could be also revealed with the wide-field optical surveys such as ongoing Subaru/Hyper-Suprime-Cam.”

Dr. Asada (ASIAA) also mentions that “The Greenland Telescope (ASIAA has been preparing for the further black hole imaging as the EHT collaboration) would also enrich the astrophysical jet sciences like this result on GRBs.”.

Finally, the research team deeply thanks for the staffs of SMA for various supports for this observing project.  

Source: Academia Sinica Institute of Astronomy and Astrophysics (ASIAA)

Copyright (2020) ASIAA/Lauren Huang

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Notes:

(1) Gamma-Ray Bursts (GRBs):

Gamma-Ray Bursts (GRBs) are highly energetic explosions in the universe, and are currently being exploited as probes of first-generation stars and gravitational wave transients. In fact, the distant events at the cosmic reionization epoch and short GRB coincident with a gravitational wave transient have both already been observed, respectively.

(2) Multi-messenger astronomy:

Multi-messenger astronomy is astronomy based on the coordinated observation and interpretation of disparate “messenger” signals, which are electromagnetic radiation, gravitational waves, neutrinos, and cosmic rays.

(3) Astronomers Study Mysterious New Type of Cosmic Blast (Press Release of ALMA)

(4) ALMA Reveals Origin of Mysterious Blast: AT2018cow originated from supernova in a strongly-magnetized, dense environmentPaper and Research Team (Press Release of ALMA-Japan)

These observation results were published as Chen, W. J, Urata, Y. et al. “Two Component Jets of GRB160623A as Shocked Jet cocoon afterglow” in Astrophysical Journal Letters 891: L 15.

The research team members are: Wei Ju Chen (NCU), Yuji Urata (NCU), Kuiyun Huang (CYCU), Satoko Takahashi(JAO/NAOJ/SOKENDAI), Glen Petitpas (Harvard-Smithsonian Center for Astrophysics), and Keiichi Asada (ASIAA)

This work is supported by the Ministry of Science and Technology of Taiwan grants MOST 105-2112-M-008-013-MY3 and 106-2119-M-001-027.

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