The Trifid Nebula (M20), with its pink (left) and blue (right) colours, is at the center. The Lagoon Nebula (M 8) is at its left. Very close to M20 is the open cluster M21, almost in the very center of the image. The faint nebula IC 4685 is also seen over M 8. The open cluster M23 is located at the bottom right corner (this cluster has a similar size to the full moon in the sky). The diffuse nebula IC 1283 is located at the top right, in the middle of a dark cloud.
CANON EOS 5D Mark III with a Tamrom 200mm lens, 15 x 5 minutes exposure at f/2.8 and ISO 800.
Piggyback using my old mount, battery powered but very well polar-aligned, no autoguiding.
Full processed with Photoshop.
Siding Spring Observatory, Coonabarabran (NSW, Australia), 19 September 2017.
Since the beginning of 2016 I collaborate with SBS Radio Australia en español (SBS Radio Australia in Spanish) with a section about Astronomy. The idea came from the journalist Anna Sagristà who, after interviewing me for the section “Latinos in Australia” (*), invited me to have an informal conversation of ten minutes about some Astronomy facts of interesting news.
That was the birth of “Astronomía para Principiantes” (Astronomy for Beginners), a monthly section on SBS Radio Australia in Spanish, that I also upload as a podcast in iVoox.
It is redundant to say that this podcast is in Spanish, but it is conducted in Australia, and that is why I think it is convenient I talk about it in this blog, as one of the many science communication activities I do in this country.
With the return of Anna to Spain in mid-2016, it is my friend the journalist Rocío Otoya who has been conducting the section.
Full AAO Media Release, published at 01:00am Sydney time, 17 October 2017, that I coordinated.
For the first time, astronomers have observed the afterglow of an event that was also detected in gravitational waves. The object, dubbed AT2017gfo, was a pair of in-spiralling neutron stars in a galaxy 130 million light years away. The death spiral was detected in gravitational waves, and the resulting explosion was followed by over 50 observatories world wide, including the AAO and other observatories here in Australia.
On August 17, the Advanced Laser Interferometer Gravitational-Wave Observatory (LIGO), based in the United States, detected a new gravitational wave event, called GW170817.
GW170817 is the fifth source of gravitational waves ever recorded. The first one was discovered in September 2015, for which three founding members of the LIGO collaboration were awarded the 2017 Nobel Prize in Physics.
The GW170817 data are consistent with the merging of two neutron stars and are unlike the four previous events, which were merging black holes.
Artist’s illustration of two merging neutron stars. The narrow beams represent the gamma-ray burst while the rippling space-time grid indicates the gravitational waves that characterize the merger. Swirling clouds of material ejected from the merging stars are a possible source of the light that was seen at lower energies. Credit: National Science Foundation/LIGO/Sonoma State University/A. Simonnet.
The Advanced-Virgo interferometer, based in Italy, was online at the time of the discovery and contributed to the localization of the new gravitational wave burst.
Based on information from LIGO and VIRGO, numerous telescopes immediately sprang into action to determine if an electromagnetic counterpart to the gravitational waves could be detected.
Meanwhile, NASA’s Fermi satellite independently reported a short burst of gamma-rays within 2 seconds of the merger event associated with GW170817, consistent with the area of sky from which LIGO and VIRGO detected their gravitational waves.
This gamma-ray detection at the same time and place triggered even greater interest from the astronomical community and resulted in more intense follow up observations in optical, infrared and radio wavelengths.
A team of scientists within the Dark Energy Survey (DES) collaboration, which includes researchers from the Australian Astronomical Observatory and other Australian institutions, working with astronomers at the Harvard-Smithsonian Center for Astrophysics (CfA) in the U.S., were among the first astronomers to observe the electromagnetic counterpart of GW170817 in optical wavelengths.
Using the 570-megapixel Dark Energy Camera (DECam) mounted at the 4m Blanco Telescope at Cerro Tololo Inter-American Observatory in Chile, DES identified the kilonova AT2017gfo in the nearby galaxy NGC 4993, located only 130 million light years from us, as the optical counterpart of GW170817.
Composite of detection images, including the discovery z image taken on August 18th and the g and r images taken 1 day later. Right: The same area two weeks later. Credit: Soares-Santos et al. and DES Collaboration.
“Because of its large field of view, the Dark Energy Camera was able to search almost the entire region where LIGO/VIRGO expected the gravitational wave source to be, and its exquisite sensitivity allowed us to make detailed measurements of the kilonova – the extremely energetic outburst created by the merging neutron stars,” AAO Instrument Scientist and DES Collaboration member Dr Kyler Kuehn stated.
A kilonova is similar to a supernova in some aspects, but it is different in others. It occurs when two neutron stars crash into each other. These events are thought to be the mechanism by which many of the elements heavier than iron, such as gold, are formed.
“But as impressive as it is, the Dark Energy Camera is only one of many instruments with a front row seat to this celestial spectacle. A lot of effort has gone into preparing dozens of telescopes around the world to search for electromagnetic counterparts to gravitational waves”, Dr Kuehn added.
Simultaneously to the DES study, a large group of Australian astronomers obtained follow up observations of the kilonova AT2017gfo at optical, infrared and radio wavelengths, using 14 Australian telescopes as part of the ARC Centre of Excellence for Gravitational Wave Discovery (OzGrav) and other Australian programs.
Their data are consistent with the expected outburst and subsequent merger of two neutron stars, in agreement with the results derived for GW170817 by the LIGO/Virgo collaboration.
“Before this event, it was like we were sitting in an IMAX theatre with blindfolds on. The gravitational wave detectors let us ‘hear’ the movies of black hole collisions, but we couldn’t see anything. This event lifted the blindfolds and, wow, what an amazing show!!”, A/Professor Jeff Cooke, astronomer at Swinburne University who led many of the observations said.
The Australia team also conducted observations at the 3.9m Anglo-Australian Telescope (AAT), that is managed by the Australian Astronomical Observatory (AAO). Additional archive data from the 6dF survey obtained at the AAO’s 1.2m UK Schmidt Telescope were also used.
“The observations undertaken at the AAT place important constraints on the nature of the environment in which the kilonova occurred”, AAO astronomer Dr Chris Lidman said.
The follow up observations were not scheduled, but the excitement that this event generated in the astronomical community was so large that regular programs were placed on hold.
“Many astronomers dropped any other planned observation and used all the available resources to study this rare event”, said PhD candidate Igor Andreoni (Swinburne University and Australian Astronomical Observatory), first author of the scientific paper that will be published in the science journal “Publications of the Astronomical Society of Australia” (PASA).
The study also reveals that the host galaxy has not experienced significant star-formation during the last billion years. However, there is some evidence that indicates that NGC 4993 experienced a collision with a smaller galaxy not long time ago.
The position of the kilonova AT2017gfo, found in the external parts of NGC 4993, may suggest that the binary neutron star could have been part of the smaller galaxy.
Australian astronomers were thrilled to contribute to both the detection and the ongoing observations of the kilonova AT2017gfo, the electromagnetic counterpart to the gravitational wave event GW170817.
“We have been waiting and preparing for an event like this, but didn’t think it would happen so soon and in a galaxy that is so near to us. Once we were alerted of the gravitational wave detection, we immediately contacted a dozen telescopes and joined the worldwide effort to study this historic event. It didn’t let us down!”, A/Professor Jeff Cooke said.
“It was crucial to have telescopes placed in every continent, including Australia, to keep this rare event continuously monitored”, PhD candidate Igor Andreoni said.
“To me, this gravitational + electromagnetic wave combined detection is even more important than the initial detection that resulted in the Nobel Prize. This has changed the way the entire astronomical community operates”, AAO Instrument Scientist Dr Kyler Kuehn stated.
The first identification of the electromagnetic counterpart to a gravitational wave event is a milestone in the history of modern Astronomy, and opens a new era of multi-messenger astronomy.
The AAO organized and/or participated in 7 events during Australia’s National Science Week in August 2017, including the very successful and sold-out events “Star Tales of Winter Nights” and “Stargazing in the Park”.
Astronomers at the AAO’s “Star Tales of Winter Nights” event at the Powerhouse Museum during National Science Week 2017. From left to right: Adam Schaefer, Dr Devika Kotachery, Dr. Ángel López-Sánchez (MC), Carlos Bacigalupo and Rebecca Brown. Credit: Ángel López-Sánchez.
The event “Star Tales of Winter Nights”, hosted at Sydney’s Powerhouse Museum had a very similar structure than our ViVID Sydney Ideas events: 5 astronomers talking about science and later answering questions from the audience. The speakers were Rebecca Brown, Adam Schaefer, Dr Devika Kotachery, Carlos Bacigalupo and myself. This event was another big success for the AAO.
Setting up the telescopes for AAO’s “Stargazing in the Park” in Sydney’s Centennial Park. Credit: Ángel R. López-Sánchez.
AAO’s Ángel López-Sánchez, Stuart Ryder and Duncan Wright (from left to right) ready for “Stargazing in the Park” in Sydney’s Centennial Park. Credit: Ángel R. López-Sánchez.
On the other hand, the “Stargazing in the Park” in Sydney’s Centennial Park was another sold-out event, with more than 120 people enjoying first a short lecture about the AAO and introduction to stargazing and later looking at the sky through the telescopes.
AAO’s Stuart Ryder attending visitors at the AAO desk during the “Science and Tech” expo at Chatswood Library on Saturday 12th August. Credit: Ángel López-Sánchez.
During National Science Week 20017 the AAO also participated in two of the events organized by the recently created “North Sydney Science Hub” . First on Saturday 12th August in the “Science and Tech” expo at Chatswood Library, and later in the Public Discussion “Big Data And Visual Analytics – What is it good for?”, on Thursday 17th August, also at Chatswood Library, being myself one of the panelists of the discussion.
Panel for the Public Discussion “Big Data And Visual Analytics – What is it good for?”, on Thursday 17th August, also at Chatswood Library. From left to right: Mark Ballico (NMI), Tomasz Bednarz (Data61 and UNSW Art & Design), Angela (CSIRO) and Ángel R. López-Sánchez (AAO.MQU). Credit: Ángel R. López-Sánchez.
This is BIG. Australian astronomers have tried for almost 2 decades to be part of the European Southern Observatory (ESO). Yesterday, 11th July 2017, at a ceremony happening during the Annual Meeting of the Astronomical Society of Australia (ASA) in Canberra, Australia, ESO’s Director General, Tim de Zeeuw, and the Australian Minister for Industry, Innovation and Science, Arthur Sinodinos, signed a 10yearsStrategic Partnershipbetween Australia and ESO.
Image composition showing all the ESO observatories and the Headquarters. Credit: ESO/M. Kornmesser.
Following the ESO-Australia Strategic Agreement, Australian astronomers (including me!) will have access to telescope time at La Silla and Paranal Observatories in Chile. The ESO-Australia Strategic Agreement also provides crucial opportunities for Australian influence and technical and scientific input, stimulating international research and industry collaborations.
This is particularly important for the Australian Astronomical Observatory (AAO), as we are developing key instrumentation for ESO (as the ESOP positioner for the VISTA telescope), and that was a key part of the deal, with new opportunities to develop further telescope instrumentation in the nearby future. That also means an important re-arrangement within the AAO, which details are still unknown, but in which we’ll give our best.
At a ceremony in Canberra, Australia, on 11 July 2017, an arrangement was signed to begin a ten-year strategic partnership between ESO and Australia. The partnership will further strengthen ESO’s programme, both scientifically and technically, and will give Australian astronomers and industry access to the La Silla Paranal Observatory. It may also be the first step towards Australia becoming an ESO Member State. This picture shows all the signatories of the arrangement. From left to right: Virginia Kilborn, President of the Astronomical Society of Australia, Warrick Couch, Director of the Australian Astronomical Observatory, Sue Weston, Deputy Secretary, Department of Industry, Innovation and Science, Senator the Hon Arthur Sinodinos, Minister for Industry, Innovation and Science, Tim de Zeeuw, ESO Director General, Brian Schmidt, Vice Chancellor of the Australian National University, Laura Comendador, Head of the ESO Cabinet and Patrick Geeraert, ESO Director of Administration. Credit: Australian Government.
The Australian Government will invest $129 million over 10 years in the partnership, including the $26.1 million already announced for 2017-2018 Australian Budget. This may also be the first step towards Australia becoming an ESO Member State.
Dr Ángel R. López-Sánchez 