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Earth is just one planet in a solar system that wanders around a galaxy. Each galaxy is unique in its own right, each composed of its special ration of dust, gas, and endless stars. What unites them all is the mysterious dark sky that they float in: the Universe.

A constantly growing expanse of space and time, the Universe’s attractive gravitational force is currently decreasing while its repulsive force is increasing. This repulsive force is referred to as dark energy. It is pushing galaxies apart at an increasing rate, bringing up a flurry of questions. Why is this happening? How does dark energy work? What is the role of magnetism?

To answer these questions and more requires the right tools. Improvements in instrumentation up until now have enabled astronomers to unveil many mysteries, not only in the visible region of our Universe where human eyes are sensitive to electromagnetic waves, but also beyond. This is done through various means. Optical telescopes, such as the famous Hubble Space Telescope, detect the intensity of incoming radiation in the optical band of the spectrum. Fundamentally, all celestial objects emit electromagnetic radiation, among them radio waves.

The observation of cosmic objects in these radio frequencies is defined as radio astronomy. Because radio waves penetrate dust, scientists utilise radio astronomy techniques to explore undetectable areas of space which cannot be seen using visible light by optical telescopes.

The project is an international effort to build the world’s largest multi radio telescope that will have a total collecting area of approximately one million square metres.

The Square Kilometre Array (SKA) project is the largest project planned for the 21st century. It will see thousands of radio telescopes built in South Africa and Australia. It will enable unparalleled insights into the Universe. The project is an international effort to build the world’s largest multi radio telescope that will have a total collecting area of approximately one million square metres. SKA’s developers are building a system that would operate over a wide range of frequencies, and its size would make it 50 times more sensitive than any other radio instrument. It is set to be able to take images of the sky at up to 10,000 times the speed of current survey radio telescopes.

The University of Malta’s (UoM) contribution to the SKA project is being spearheaded by the Institute of Space Sciences and Astronomy (ISSA). ISSA Founder Prof. Kristian Zarb Adami, Faculty of Science Dean Prof. Charles Sammut, and Iman Farhat are developing an antenna which can be printed like a newspaper and can be rolled out like a carpet.

Unlike conventional antennas which are designed to work optimally at one frequency, the engineering prototype developed at the UoM can sense a large range of frequencies and is capable of running applications such as TV, wireless, Bluetooth, and near-field communications. This was also important because ISSA researchers are trying to detect the first atoms and molecules that were formed at the earliest stages of the Universe. This antenna is also intended to serve as a cost-effective element to cover remote locations for SKA.

The SKA project is scheduled to be built in phases, starting in 2018 and finishing in 2024. Even before the SKA is online, several thousand combined radio telescopes will be collecting and processing data equivalent to 100 times today’s global internet traffic per [unit of time].

The first small scale prototype antenna ISSA built had 256 elements and met SKA’s application and requirements. This was immensely motivating, especially when considering the high standards of this world-wide consortium. The initial success drove home the possibility of further in-depth studies.

ISSA has now embarked on building a large-scale version of the array (funded by the Technology Development Programme of the Malta Council for Science and Technology and Malta Communications Authority). The Malta array demonstrator is an implementation of two antenna arrays. Each array consists of 5,000 elements covering an area of 100 m2. The main aim of this is to test the array in an environment close to its real world conditions. The characterisation of the antenna array radiation pattern is being investigated using a far-field flying source. The system makes use of drones equipped with a transmitter and a dipole antenna that communicates with the array on test. The team is now working on this antenna to ensure a seamless performance.

SKA is a behemoth of a project, involving about 100 organisations across 20 countries. With it, scientists and researchers all over the world will be able to conduct transformational science in astronomical observation, breaking new ground with every step and redefining our understanding of space as we know it.

Key goals include challenging Albert Einstein’s theory of relativity to have a closer look at how the very first stars and galaxies formed moments after the Big Bang. It could also potentially provide an answer to one of the greatest mysteries known to humankind—are we alone in the Universe? SKA-night

Space: the final frontier for Malta

Think meets up with Dr Kris Zarb Adami to have a chat about Malta’s space opportunities. His research covers subjects from searching for extraterrestrial life to new theories of gravity.

How can a small country like Malta have a role in Space?

As an EU member Malta can continue strengthening our existing cooperation agreement with the European Space Agency to full membership. This will automatically give us access to all its projects. By participating in these projects, we will be able to leverage so that research and development for future space missions is carried out in Malta. In Malta we are already contributing to a European Space project, namely EUCLID. This satellite is due to be launched in 2017 and will be the successor to the Hubble Space Telescope. Researchers at the Department of Physics are developing image-processing algorithms that can accurately measure the shapes of the Universe’s furthest galaxies and its expansion.
Moreover, they also collaborate with the University of Bologna to monitor ‘space debris’ and near earth-objects. This is important to ensure the successful navigation of satellites to prevent accidental collisions, which cost millions of euros. Collisions are not as rare as we might think.

space

What are the benefits of Space research for Malta?

From the invention of disposable diapers to the development of laptops and satellite TV, space research has traditionally been a very strong contributor to everyday technology. For Malta space research can help us monitor our climate and atmospheric pollution, while providing an early warning system for tidal waves.
Conducting space research locally would bring us to the forefront of technology: ranging from biotechnology and long-lasting foods for space journeys, to the development of faster and more sensitive communication systems capable of receiving signals from deep space. Malta has just been awarded ERDF funding for new laboratory facilities at University and will contribute significantly to the future of the European Space Programme. In return, Malta will be able to leverage significant funds from this programme and also funds designated to commercialising the technologies. We need more support to get involved in more projects and attract funds to Malta.

What is the future of Space Research?

The next step lies in the development of space vehicles capable of running commercially feasible missions, such as turning the space shuttle into a commercial ‘airliner’ business. Such programmes are beginning to emerge in the US, but Europe lags far behind. Commercial spaceflights will certainly play an important role in future space research. Apart from research into transportation, researchers are trying to figure out how to live on a planet besides our own. How can future generations be able to create food products and live in space?
In Malta I would like University and the whole country to become more involved in space technology and biotech. We could also contribute to landing and docking systems for satellites and shuttles, plus space-traffic control through the University’s expertise in the Engineering Faculty.

Is there anything to lose?

The danger with taking on some new research area is that funding from other streams is spread too thinly. However, if we can manage to leverage extra funding from large Europe-wide space programmes we will be able to launch Malta’s name into space!