An artistic representation of how the northern infrared aurora would have looked in 2006 (marked in red). The darker red locations indicate confirmed aurora locations, with fainter red used to mark possible aurora locations. Credit to NASA, ESA and M. Showalter (SETI Institute) for the background image of Uranus, as was observed by the Hubble Space Telescope (in the visible spectrum) in August 2005. Credit: NASA, ESA and M. Showalter (SETI Institute) for the background image of Uranus, as was observed by the Hubble Space Telescope (in the visible spectrum) in August 2005.
University of Leicester astronomers confirm the existence of an infrared (IR) aurora on UranusUranus is the seventh farthest planet from the sun. It has the third-largest diameter and fourth-highest mass of planets in our solar system. It is classified as an "ice giant" like Neptune. Uranus' name comes from a Latinized version of the Greek god of the sky.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Uranus.
The presence of an infrared aurora on the cold, outer planet of Uranus has been confirmed for the first time by University of Leicester astronomers.
The discovery could shed light on the mysteries behind the magnetic fields of the planets of our solar system, and even on whether distant worlds might support life.
The team of scientists, supported by the Science and Technology Facilities Council (STFC), have obtained the first measurements of the infrared (IR) aurora at Uranus since investigations began in 1992. While the ultraviolet (UV) aurorae of Uranus has been observed since 1986, no confirmation of the IR aurora had been observed until now. The scientists’ conclusions were published on October 23 in the journal Nature Astronomy.
Averaged emission spectrum between 3.4 and 4.0μm, with annotated positions of valuable H3+ emission lines (known as Q lines) found at specific wavelength locations, the brightness of each line is determined by both temperature and density of the H3+ particles in a planet’s atmosphere. Credit: University of Leicester
Magnetic Misalignment and Aurorae
The ice giants Uranus and NeptuneNeptune is the farthest planet from the sun. In our solar system, it is the fourth-largest planet by size, and third densest. It is named after the Roman god of the sea.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Neptune are unusual planets in our solar system as their magnetic fields are misaligned with the axes in which they spin. While scientists have yet to find an explanation for this, clues may lie in Uranus’s aurora.
Aurorae are caused by highly energetic charged particles, which are funneled down and collide with a planet’s atmosphere via the planet’s magnetic field lines. On Earth, the most famous results of this process are the spectacles of the Northern and Southern Lights. At planets such as Uranus, where the atmosphere is predominately a mix of hydrogen and helium, this aurora will emit light outside of the visible spectrum and in wavelengths such as the infrared (IR).
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Condensed movie of the telescope imager (on September 5, 2006) as it focused on Uranus, with moons Titania, Miranda, Umbriel, and Oberon visible. There is a double exposure of all objects in the movie, which is an effect of subtracting images to minimize the effect of Earth’s atmosphere as we look up into the sky. We also see possible galaxies and stars in this movie! Credit: University of Leicester
Methods and Findings
The team used infrared auroral measurements taken by analyzing specific wavelengths of light emitted from the planet, using the Keck II telescope. From this, they can analyze the light (known as emission lines) from these planets, similar to a barcode. In the infrared spectrum, the lines emitted by a charged particle known as H3+ will vary in brightness depending on how hot or cold the particle is and how dense this layer of the atmosphere is. Hence, the lines act like a thermometer into the planet.
Their observations revealed distinct increases in H3+ density in Uranus’s atmosphere with little change in temperature, consistent with ionization caused by the presence of an infrared aurora. Not only does this help us better understand the magnetic fields of the outer planets of our own solar system, but it may also help in identifying other planets that are suitable of supporting life.
Measured infrared brightness from the upper atmosphere of Uranus over a 6-hour period, areas highlighted with a black border and no hash or dots are locations of enhanced emission (aurora). Hashed areas means possible aurora though the signal is too weak to confirm and dotted areas means no aurora in these points. Credit: University of Leicester
Implications and Future Studies
Lead author Emma Thomas, a PhD student in the University of Leicester School of Physics and Astronomy, said: “The temperature of all the gas giant planets, including Uranus, are hundreds of degrees Kelvin/CelsiusThe Celsius scale, also known as the centigrade scale, is a temperature scale named after the Swedish astronomer Anders Celsius. In the Celsius scale, 0 °C is the freezing point of water and 100 °C is the boiling point of water at 1 atm pressure.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Celsius above what models predict if only warmed by the sun, leaving us with the big question of how these planets are so much hotter than expected? One theory suggests the energetic aurora is the cause of this, which generates and pushes heat from the aurora down towards the magnetic equator.
Measured infrared brightness from the upper atmosphere of Uranus combined with rings of magnetic field lines which occur as the planet rotations (which produces the oval shape we see in most aurora). These rings are called shells and we expect the majority of auroral signal to occur between the dashed and dotted lines (as seen in 1986), which a portion of our results do. Credit: University of Leicester
“A majority of exoplanets discovered so far fall in the sub-Neptune category, and hence are physically similar to Neptune and Uranus in size. This may also mean similar magnetic and atmospheric characteristics too. By analyzing Uranus’s aurora which directly connects to both the planet’s magnetic field and atmosphere, we can make predictions about the atmospheres and magnetic fields of these worlds and hence their suitability for life.
“This paper is the culmination of 30 years of auroral study at Uranus, which has finally revealed the infrared aurora and begun a new age of aurora investigations at the planet. Our results will go on to broaden our knowledge of ice giant auroras and strengthen our understanding of planetary magnetic fields in our solar system, at exoplanets, and even our own planet.”
The results may also give scientists an insight into a rare phenomenon on Earth, in which the north and south pole switch hemisphere locations known as geomagnetic reversal.
Emma adds: “We don’t have many studies on this phenomena and hence do not know what effects this will have on systems that rely on Earth’s magnetic field such as satellites, communications, and navigation. However, this process occurs every day at Uranus due to the unique misalignment of the rotational and magnetic axes. Continued study of Uranus’s aurora will provide data on what we can expect when Earth exhibits a future pole reversal and what that will mean for its magnetic field.”
Reference: “Detection of the infrared aurora at Uranus with Keck-NIRSPEC” by Emma M. Thomas, Henrik Melin, Tom S. Stallard, Mohammad N. Chowdhury, Ruoyan Wang, Katie Knowles and Steve Miller, 23 October 2023, Nature Astronomy.
DOI: 10.1038/s41550-023-02096-5
Source: SciTechDaily
