South African Large Telescope Makes Its Debut

September 1, 2005
South African Large Telescope Makes Its Debut

Exactly five years after groundbreaking, the Southern African Large Telescope (SALT) project has released its first colour images, marking the achievement of 'first light' and the successful debut of full operation for SALTICAM, a $600 000 digital camera designed and built for SALT at the South African Astronomical Observatory (SAAO). SALT is the largest optical telescope in the southern hemisphere, and equal to the largest in the world. Gathering more than 25 times as much light as any existing African telescope, SALT can detect objects as faint as a candle flame on the moon.

Image: The Lagoon Nebula is a region about 3,800 light years away in which stars of high mass and luminosity are being born, emitting enough ultraviolet radiation to stimulate atoms in the surrounding gas clouds to emit light. The light-gathering capability of SALT will allow astronomers to study motions in the gas clouds, perhaps leading them to revise ideas of how stars are born.

The sample images now released for the first time were taken during the camera's first trial period of operation, which also achieved SALT's first significant scientific results.

SALTICAM will be important to research by all the partners involved in building SALT (National Research Foundation of South Africa; Nicolaus Copernicus Astronomical Center of the Polish Academy of Sciences and a consortium of 3 Polish universities, comprising: Jagiellonian University, Nicolaus Copernicus University, and Adam Mickiewicz University; The Hobby-Eberly Telescope Board (representing Georg-August-Universität Göttingen, Ludwig-Maximilians-Universität München, Stanford University, The Pennsylvania State University, and The University of Texas at Austin); Rutgers, the State University of New Jersey (USA); Georg-August-Universität Göttingen (Germany); The University of Wisconsin-Madison (USA); University of Canterbury (New Zealand); University of North Carolina-Chapel Hill (USA); Dartmouth College (USA); Carnegie Mellon University (USA); United Kingdom SALT Consortium (UKSC), comprising: the Armagh Observatory, the University of Keele, the University of Central Lancashire, the University of Nottingham, the Open University and the University of Southampton).

Five years ago, on the first day of southern hemisphere spring, a few hundred people gathered for the SALT ground-breaking ceremony. On a windswept hilltop near the tiny Karoo town of Sutherland, home since the early 1970s to SAAO's research telescopes, dignitaries turned the first soil. Much has happened since that historic day, and SALT is now nearing completion.

A major recent milestone was the installation in May of the last of the 91 hexagonal mirror segments that comprises SALT's mammoth primary mirror array, stretching 11 metres across. Another major milestone, which we are marking today, is attaining "first light" with the telescope's full array of mirrors and its new imaging camera, SALTICAM. The biggest milestone for 2005 will be the official opening of SALT on 10 November 2005 by South African President Thabo Mbeki.

An Icon for SciTech Development and Cooperation – Within Budget

"SALT was an initiative of South African astronomers that won support from the South African government, not simply because it was a leap forward in astronomical technology, but because of the host of spin-off benefits it could bring to the country", said project scientist David Buckley. "Indeed the SALT project has become an iconic symbol for what can be achieved in Science and Technology in the new South Africa." SALT is not simply a South African project, however. It is an international partnership involving 11 different partners from 6 countries on 4 continents – including Germany, Poland, New Zealand, the UK and the USA. A talented team of local engineers and scientists have succeeded in building SALT on a rapid – for big telescope projects at least – 5 year timescale. Not only that, but the cost of construction has been kept to within the original budget of $20 million defined in 1998, even before the final designs were completed. According to Kobus Meiring, project engineer, "This is due in part to the fact much of the original design concept for SALT was modeled on the Hobby-Eberly Telescope in Texas, giving a useful starting point and allowing SALT's engineers to make creative use of the 'lessons learned' with the only previous telescope of this type."

Science Achieved and Progress to Come

Limited scientific observations have already begun with SALT while completion of the telescope's commissioning continues over the coming months. In the next month or so, installation will begin of the major first generation instrument, the Prime Focus Imaging Spectrograph (designed and built for SALT by the University of Wisconsin-Madison and Rutgers University) – which is to be renamed the Robert Stobie Spectrograph in honour of the past SAAO Director and Chairperson of the SALT Board, Dr Robert S. Stobie. It was Bob Stobie's dedication and enthusiasm that helped launch, and later steer, the SALT project to success. His untimely death in May 2002 was felt by all his colleagues, and the renaming of this major instrument in his name is in recognition of his major role in the SALT project.

The declaration of first light signifies that SALT has arrived on the astronomical scene. There is still telescope and instrument commissioning to complete, as well as full optimisation of SALT and its subsystems. This will continue for several months, after which astronomers confidently expect that SALT and its instruments will meet or exceed all the original design goals. This process is already well under way with much achieved, and SALT is now in a very real sense an operational telescope.

Astronomers within the SALT consortium keenly look forward to the scientific fruits of what has been, until now, an extremely successful engineering project. Already proposals for observations have been submitted and approved, and these observations are now beginning with the imaging camera, SALTICAM. The same will be true for the Robert Stobie Spectrograph, once it completes its commissioning tests in October. Like the SALT consortium itself, the science programmes to be conducted on SALT will be many and varied – from studies of the most distant and faint galaxies to observations of solar system objects like asteroids and comets.

The Information Age Telescope

SALT is truly representative of the century in which it has been built, since not only is it a sophisticated computer controlled precision instrument, but it is also an Internet-age telescope. No longer will it be necessary for astronomers in the consortium to travel to SALT to use it. Instead they will submit their observing requests over the Internet and eventually, once the observations have been conducted by the dedicated SALT operations staff, they will also receive their data over the Internet. In many respects this makes SALT far more like a space-based telescope, like the Hubble Space Telescope, than its ground based cousins. The operational model for SALT, with SAAO operating the telescope on behalf of SALT's partners, will also be far closer to the way a telescope in orbit operates.

Bringing the Stars Home to Africa

But the scientific and engineering achievements of the SALT project would have fallen short of the vision that led the South African government (with standing applause from every political party) to approve SALT, unless it did more than provide a spectacular tool for southern African and overseas scientists to explore the universe and extend human knowledge.

Already the benefits have been tangible, with the provision of bursaries and scholarships to deserving South African students to study both in South Africa and abroad. These programmes have been directly sponsored by many of the partners in the SALT Foundation. A number of science education initiatives have also been catalysed by the project, and many more are foreseen. Financially South Africa has benefited by the awarding of ~60% of the contracts and tenders to construct SALT to South African industry, while total South African funding was only ~34% of the total, meaning a net inflow of foreign exchange. Likewise, many of the high tech aspects of the project were undertaken by South African industry, including the precision robotic tracking system. This has meant the acquiring of skills previously not present or fully realized in the country.

Finally, SALT, like the science it will produce, has the gift of inspiring the imagination. Young visitors to SALT, and youth encountering SALT in the media or in the classroom, will know that cutting-edge science can happen in southern Africa as well as in the fully developed world. Sparking interest in science in technology, pulling bright young minds into careers in science and technology, is the real future benefit to South Africa.

The colour images are available at www.salt.ac.za/content/first_light/index.html.

Source: Carnegie Mellon University

Explore further: Giant, jagged 'ice spikes' cover Jupiter's moon Europa, new study suggests

Related Stories

How quinoa plants shed excess salt and thrive in saline soils

September 21, 2018

Barely heard of a couple of years ago, quinoa today is common on European supermarket shelves. The hardy plant thrives even in saline soils. Researchers from the University of Würzburg have now determined how the plant gets ...

Recommended for you

Hawking's final book offers brief answers to big questions

October 15, 2018

Stephen Hawking's final work, which tackles issues from the existence of God to the potential for time travel, was launched on Monday by his children, who helped complete the book after the British astrophysics giant's death.

Oldest evidence for animals found

October 15, 2018

Researchers at the University of California, Riverside, have found the oldest clue yet of animal life, dating back at least 100 million years before the famous Cambrian explosion of animal fossils.

Biomaterials with 'Frankenstein proteins' help heal tissue

October 15, 2018

Biomedical engineers from Duke University and Washington University in St. Louis have demonstrated that, by injecting an artificial protein made from a solution of ordered and disordered segments, a solid scaffold forms in ...

0 comments

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.