Файл:NASA’s Webb Captures Dying Star’s Final ‘Performance’ in Fine Detail.png

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Описание	This side-by-side comparison shows observations of the Southern Ring Nebula in near-infrared light (L) and mid-infrared light (R), from NASA’s Webb Telescope. The central star has a white dwarf orbiting it to the lower left. In the Near-Infrared Camera (NIRCam) image, the white dwarf is partially hidden by a diffraction spike. The same star appears – but brighter, larger, and redder – in the Mid-Infrared Instrument (MIRI) image. The images look very different because NIRCam and MIRI collect different wavelengths of light. NIRCam delivers higher-resolution images, while MIRI goes farther into the infrared and can see gleaming dust around the stars. The white dwarf is cloaked in thick layers of dust, which make it appear larger. The brighter star in both images hasn’t yet shed its layers. It closely orbits the dimmer white dwarf, helping to distribute what it’s ejected. Over thousands of years and before it became a white dwarf, the star periodically ejected mass – the visible shells of material. Stellar material was sent in all directions – like a rotating sprinkler – and provided the ingredients for this asymmetrical landscape. Today, the white dwarf is heating up the gas in the inner regions – which appear blue at left and red at right. Both stars are lighting up the outer regions, shown in orange and blue, respectively. In the circular region at the center of both images is a wobbly, asymmetrical belt of material. This is where two “bowls” that make up the nebula meet. (In this view, the nebula is at a 40-degree angle.) This belt is easier to spot in the MIRI image, as a yellowish circle, but is also visible in the NIRCam image. The light that travels through the orange dust in the NIRCam image – which look like spotlights – disappear at longer infrared wavelengths in the MIRI image. In near-infrared light, stars have more prominent diffraction spikes because they are so bright at these wavelengths. In mid-infrared light, diffraction spikes also appear around stars, but they are fainter and smaller (zoom in to spot them).
Источник	https://www.flickr.com/photos/nasawebbtelescope/albums/72177720300469752/with/52211582643/
Время создания	2022-07-12
Автор или правообладатель	Image: National Aeronautics and Space Administration (a U.S. federal government agency; https://www.nasa.gov/) European space agency (https://www.esa.int/), Canadian Space Agency (https://www.asc-csa.gc.ca/eng/) Space Telescope Science Institute (https://www.stsci.edu/, science operations center for the Hubble Space Telescope) — Лицензия: Public domain (в общественном достоянии)
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текущий	09:52, 16 августа 2023		9284 × 4310 (29,11 Мб)	Я, робот (обсуждение \| вклад)	== Описание == {{Изображение \| описание = This side-by-side comparison shows observations of the Southern Ring Nebula in near-infrared light (L) and mid-infrared light (R), from NASA’s Webb Telescope. The central star has a white dwarf orbiting it to the lower left. <p>In the Near-Infrared Camera (NIRCam) image, the white dwarf is partially hidden by a diffraction spike. The same star appears – but brighter, larger, and redder – in the Mid-Infrared Instrument (MIRI) image. The images look ve...

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Файл:Southern Ring Nebula (NIRCam and MIRI Images Side by Side).png
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Источник	STScI
Поставщик, кто предоставил изображение	NASA, ESA, CSA, STScI, Webb ERO Production Team
Владелец авторского права	Public
Автор	Space Telescope Science Institute Office of Public Outreach
Краткое название	Southern Ring Nebula (NIRCam and MIRI Images Side by Side)
Название изображения	This side-by-side comparison shows observations of the Southern Ring Nebula in near-infrared light, at left, and mid-infrared light, at right, from NASA’s Webb Telescope.This scene was created by a white dwarf star– the remains of a star like our Sun after it shed its outer layers and stopped burning fuel though nuclear fusion. Those outer layers now form the ejected shells all along this view.In the Near-Infrared Camera (NIRCam) image, the white dwarf appears to the lower left of the bright, central star, partially hidden by a diffraction spike. The same star appears– but brighter, larger, and redder – in the Mid-Infrared Instrument (MIRI) image. This white dwarf star is cloaked in thick layers of dust, which make it appear larger.The brighter star in both images hasn’t yet shed its layers. It closely orbits the dimmer white dwarf, helping to distribute what it’s ejected.Over thousands of years and before it became a white dwarf, the star periodically ejected mass– the visible shells of material. As if on repeat, it contracted, heated up – and then, unable to push out more material, pulsated. Stellar material was sent in all directions – like a rotating sprinkler – and provided the ingredients for this asymmetrical landscape.Today, the white dwarf is heating up the gas in the inner regions– which appear blue at left and red at right. Both stars are lighting up the outer regions, shown in orange and blue, respectively.The images look very different because NIRCam and MIRI collect different wavelengths of light. NIRCam observes near-infrared light, which is closer to the visible wavelengths our eyes detect. MIRI goes farther into the infrared, picking up mid-infrared wavelengths. The second star more clearly appears in the MIRI image, because this instrument can see the gleaming dust around it, bringing it more clearly into view.The stars– and their layers of light – steal more attention in the NIRCam image, while dust plays the lead in the MIRI image, specifically dust that is illuminated.Peer at the circular region at the center of both images. Each contains a wobbly, asymmetrical belt of material. This is where two“bowls” that make up the nebula meet. (In this view, the nebula is at a 40-degree angle.) This belt is easier to spot in the MIRI image – look for the yellowish circle – but is also visible in the NIRCam image.The light that travels through the orange dust in the NIRCam image– which look like spotlights – disappear at longer infrared wavelengths in the MIRI image.In near-infrared light, stars have more prominent diffraction spikes because they are so bright at these wavelengths. In mid-infrared light, diffraction spikes also appear around stars, but they are fainter and smaller (zoom in to spot them).Physics is the reason for the difference in the resolution of these images. NIRCam delivers high-resolution imaging because these wavelengths of light are shorter. MIRI supplies medium-resolution imagery because its wavelengths are longer– the longer the wavelength, the coarser the images are. But both deliver an incredible amount of detail about every object they observe – providing never-before-seen vistas of the universe.For a full array of Webb’s first images and spectra, including downloadable files, please visit: https://webbtelescope.org/news/first-imagesNIRCam was built by a team at the University of Arizona and Lockheed Martin’s Advanced Technology Center.MIRI was contributed by ESA and NASA, with the instrument designed and built by a consortium of nationally funded European Institutes (The MIRI European Consortium) in partnership with JPL and the University of Arizona.
Условия использования	http://hubblesite.org/copyright/
Оригинальные дата и время	11:00, 12 июля 2022
Ширина	9284 пикс.
Высота	4310 пикс.
Цветовая модель	RGB
Количество цветовых компонентов	3
Горизонтальное разрешение	300 точек на дюйм
Вертикальное разрешение	300 точек на дюйм
Версия Exif	2.31
Цветовое пространство	sRGB
Ширина изображения	9284 пикс.
Высота изображения	4310 пикс.
Глубина цвета	8 8 8
Программное обеспечение	Adobe Photoshop 23.3 (Macintosh)
Дата и время оцифровки	05:26, 6 декабря 2021
Дата последнего изменения метаданных	12:21, 2 июля 2022
Дата и время изменения файла	11:10, 2 июля 2022
Уникальный идентификатор исходного документа	xmp.did:ac8b8199-a5b9-4669-a311-a24c750d0882
Авторско-правовой статус:	Авторско-правовой статус не задан
Ключевые слова	NGC 3132 Southern Ring Nebula Eight-Burst Nebula
Контактная информация	outreach@stsci.edu http://hubblesite.org 3700 San Martin Drive Baltimore, MD, 21218 USA 410-338-4444