Square kilometre (U.S. spelling: square kilometer), symbol km2, is a decimal multiple of the SI unit of surface area, the square metre, one of the SI derived units. 1 km2 is equal to:
Conversely:
Note: "km2" means (km)2, square kilometre or kilometre squared, and not k(m2), kilo–square metre. For example, 3 km2 is equal to = 3,000,000 m2, not 3,000 m2.
The 106 m2 orders of magnitude page gives comparisons with geographic areas.
A hectare (104 m2) is less than a square kilometre which is less than a square megametre (1012 m2). This is
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Artist's Impression of the central core of dish antennas The Square Kilometre Array (SKA) is a radio telescope in development which will have a total collecting area of approximately one square kilometre.[1] It will operate over a wide range of frequencies and its size will make it 50 times more sensitive than any other radio instrument. By utilising advanced processing technology it will be able to survey the sky more than ten thousand times faster than ever before. With receiving stations extending out to distance of 3,000 km from a concentrated central core, it will continue radio astronomy's tradition of providing the highest resolution images in all astronomy. The SKA will be built either in South Africa or Australia, both in the southern hemisphere, where the view of our own galaxy, the Milky Way, is best and radio interference least. With a budget of €1.5 billion, construction of the SKA is scheduled to begin in 2013 for initial observations by 2017 and full operation by 2022.
The SKA is a global collaboration of 19 countries which will revolutionise our understanding of the Universe by providing answers to fundamental questions about its origin and evolution.
The SKA will combine the signals received from thousands of small antennae spread over a distance of more than 3000 km to simulate a giant radio telescope capable of extremely high sensitivity and angular resolution. The SKA will also have a very large field-of-view (FOV) with a goal at frequencies below 1 GHz of 200 square degrees and of more than 1 square degree (about 5 full Moons) at higher frequencies. One innovative development is the use of phased-array technology to provide multiple FOVs. This will greatly increase the survey speed of the SKA and enable multiple users to observe different pieces of the sky simultaneously. The combination of a very large FOV with high sensitivity means that the SKA will transform the exploration of the Universe.
The SKA will provide continuous frequency coverage from 70 MHz to 10 GHz in the first two phases of its construction. A third phase will then extend the frequency range up to 30 GHz.
Phase 1: Providing ~20% of the total collecting area at low and mid frequencies by 2017.
Phase 2: Completion of the full array at low and mid frequencies by 2022.
Phase 3: Building of the high frequency array from 2022.
The frequency range from 70 MHz to 10 GHz, spanning more than two decades, cannot be realized using one design of antenna and so the SKA will comprise arrays of three types of antenna elements that will make up the SKA-low, SKA-mid and dish arrays:
Artist's Impression of the SKA Low-Band core Artist's Impression of a Mid Band Aperture Array Station Artist's Impression of the Offset Gregorian dish antennas
Schematic of the SKA Central Region The area covered by the SKA - extending out to ~3000 km - will comprise three regions:
The SKA will be a highly flexible instrument designed to address a wide range of questions in astrophysics, fundamental physics, cosmology and particle astrophysics. It will be able to probe previously unexplored parts of the distant Universe. A number of key science projects have been selected:
For almost ninety years, Einstein’s theory of general relativity has precisely predicted the outcome of every experiment made to test it. Most of these tests, including the most stringent ones, have been carried out using radio astronomical measurements. By using pulsars as cosmic gravitational wave detectors, or timing pulsars found orbiting black holes, astronomers will be able to examine the limits of general relativity such as the behaviour of space and time in regions of extremely curved space. It will then be known whether Einstein was right in his description of space, time and gravity, or if new physics is needed.
The sensitivity of the SKA in the 21-cm hydrogen line will map a billion galaxies out to the edge of the Universe. The large-scale structure revealed will determine the processes by which galaxies formed and grew. Imaging hydrogen through the Universe will provide a three-dimensional picture of the first ripples of structure which will then form individual galaxies and clusters. This will probe the effects of the mysterious “dark energy” that is pushing the Universe apart.
The SKA will be able to fill in the gap — the so called dark ages — between 300,000 years after the Big Bang when the Universe became transparent, and a billion years later when young galaxies are seen. By observing the primordial distribution of gas, the SKA will see how the Universe gradually lit up as its stars and galaxies formed and then evolved.
It is still not possible to answer basic questions about the origin and evolution of cosmic magnetic fields but it is clear that they are an important component of interstellar and intergalactic space. By mapping the effects of magnetism on the radiation from very distant galaxies, the SKA will reveal the form of cosmic magnetism and the role it has played in the evolving Universe.
History has shown that many of the greatest historical discoveries have happened unexpectedly. The unique sensitivity and versatility of the SKA will make it a discovery machine.
Australia: The core site is located at Boolardy in Western Australia 315 km north-east of Geraldton[2] on a flat desert-like plain at an elevation of about 460 metres. The most distant stations will be located in New Zealand. [3] [4]
South Africa: The core site is located at S30.72113° - E21.41113° at an elevation of about 1000 metres in the Karoo area of the arid Northern Cape Province, about 75 km north-west of Carnarvon, with distant stations in Ghana, Kenya, Madagascar, and Mauritius.
The final decision on the site will be made between 2011 and 2012.
Many groups are working globally to develop the technology and techniques required for the SKA. Some of these are described briefly below:
MeerKAT is a 860 million Rand project to build an array of 50 or more 12m diameter dishes to enable technology required for the SKA to be developed. KAT-7, a seven-dish engineering testbed and science instrument near Carnarvon in the Northern Cape Province of South Africa, will be commissioned towards the end of 2009 with the full array ready to do science by 2012. The dishes will be equipped with wide band single feeds to cover frequencies from 800 MHz up to 8 GHz[5].
The Australian SKA Pathfinder, or ASKAP, is a AU$100 million project to build an array of 36, 12m dishes employing advanced phased array feeds to give a wide field of view (30 square degrees). ASKAP will be built on the Australian Boolardy site. Completion of the array which covers the frequency range 700 to 1,700 MHz is scheduled for 2012[6].
LOFAR is a €120 million Dutch project building a novel low frequency phased aperture arrays spread over northern Europe. An all-electronic telescope covering low frequencies from 40 to 240 MHz completion is scheduled for 2009. LOFAR will demonstrate crucial processing techniques vital to the SKA[7].
The Allen Telescope Array (ATA) uses innovative 6.1m offset Gregorian dishes equipped with wide band single feeds covering frequencies from 500 MHz to 11 GHz. A 42 element array is currently in operation to be extended to 350. The dish design has explored methods of low cost manufacture.
The Square Kilometre Array Design Study, or SKADS, is a €38 million European funded project to develop a range of technologies and science studies for the SKA. The focus of the technical developments are high frequency aperture arrays operating from 300 MHz to 1 GHz. As an all electronic telescope, aperture arrays can provide a very large number of simultaneous beams to provide the highest survey speeds. SKADS completes mid 2009[8].
The Technology Development Programme, or TDP, is a $12 million US programme to specifically develop dish and feed technology for the SKA. It is operated by a consortium of universities led by Cornell University and completes in 2012.
The SKA was originally conceived in the early 1990s with an international working group set up in 1994. This led to the signing of the first Memorandum of Agreement in 2000. Considerable early development work then followed. This culminated in the commencement of PrepSKA in 2008 leading to a full SKA design in 2012. Construction of Phase 1 will take place from 2013 to 2017 providing an operational array capable of carrying out the first science. Phase 2 will then follow for completion in 2022 providing full sensitivity for frequencies up to 10 GHz.
The SKA is projected to cost €1.5bn for phases 1 and 2 completing in 2022, this includes €300m for phase 1 completing 2017. The funding will come from many international funding agencies. Preliminary expectations are that Europe, the United States and the rest of the world will each contribute a third of the project's funding.
fr:Square Kilometre Array id:Square Kilometre Array pt:Square Kilometre Array vi:Kính thiên văn SKA zh:平方千米阵