More amazing Webb images<\/strong><\/h3>From nebulae and dying stars to amazing spiral galaxies, star-forming regions, deep views of the cosmos and the planets of our Solar System, see the latest and newest James Webb Space Telescope images<\/a>.<\/p><\/div>Now, the James Webb Space Telescope<\/a> is ushering in a new era of astronomy, granting an unprecedented view of the cosmos, observing infrared<\/a> wavelengths that are invisible to our eyes.<\/p>This can cut through dust clouds to see regions where new stars are being born, and travel vast distances allowing us to look back to the Universe\u2019s earliest days.<\/p>
The James Webb Space Telescope has been snapping phenomenal pictures of our breathtaking Universe for over two years now.<\/p>
Here are 10 of my favourites taken so far.<\/p>
Pillars of creation<\/strong><\/h2>![\"Composite](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/webb-pillars-of-creation.jpg\")
Composite image of the Pillars of Creation using James Webb Space Telescope’s MIRI and NIRCam. Credit: Science – NASA, ESA, CSA, STScI. Image Processing – Joseph DePasquale (STScI), Alyssa Pagan (STScI), Anton M. Koekemoer (STScI)<\/figcaption><\/figure>Nebulae<\/a> are giant swirls of interstellar gas and dust. Some types of nebulae are called \u2018stellar nurseries\u2019 because eddies of gas and dust begin to coalesce, their gravity attracting more matter.<\/p>Eventually these clumps collapse in on themselves and stars are born.<\/p>
One such stellar nursery, the Pillars of Creation, was first brought to the public\u2019s attention when it was photographed by the Hubble Space Telescope in 1995<\/a>.<\/p>To give some idea of scale, the longest pillar on the left projects some four lightyears<\/a> into space and the small projections on the end are about the size of our whole Solar System.\u00a0<\/p>While Hubble\u2019s view was blocked by the nebula\u2019s dust, JWST\u2019s infrared vision is able to peek through, so we can develop a better understanding of how star formation occurs within these stellar nurseries.<\/p>
Deep view around SMACS 0723<\/strong><\/h2>![\"James](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2022\/07\/james-webb-first-image-SMACS-0723-fb416af-e1657608530907.jpeg\")
James Webb Space Telescope’s first full colour image: a deep view of space centred around galaxy cluster SMACS 0723. Credit: NASA, ESA, CSA, and STScI<\/figcaption><\/figure>A number of <\/strong>years ago, I met Robert Williams, who was the director of the Space Telescope Science Institute in Baltimore.<\/p>He commissioned the first deep-field observation using Hubble \u2013 the Hubble Deep Field (HDF).<\/p>
In these surveys, the telescope was directed to look at a particular part of the sky for days, rather than the usual minutes.\u00a0<\/p>
Many people were shocked when Robert first suggested this idea.<\/p>
Telescopes like JWST and Hubble are in high demand, yet here was Robert proposing to do a 10-day exposure.<\/p>
Worse, he and his team were choosing an area of the sky with no known bright objects \u2013 a field of view that seemed to be empty space.<\/p>
The observation went ahead during December 1995 and 342 separate exposures were taken.<\/p>
The HDF exposures revealed the distance, age and composition of the galaxies imaged.<\/p>
It was such a success, that JWST recreated the feat, taking this image of galaxy cluster SMACS 0723.<\/p>
SMACS 0723 zoomed in<\/strong><\/h2>![\"A](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/Webb-SMACS-0723-zoomed-in.jpg\")
A zoom-in on Webb’s image of SMACS 0723. Credit: NASA, ESA, CSA, and STScI<\/figcaption><\/figure>There is so <\/strong>much to look at in JWST\u2019s image of SMACS 0723 (Webb\u2019s First Deep Field) that it warrants a closer look.<\/p>The galaxies<\/a> are bound together by gravity<\/a>, concentrating them in a cluster. Their combined mass can manipulate and bend the light from the galaxies behind them.<\/p>This natural phenomenon is called gravitational lensing<\/a>. The giant object magnifies, distorts and sometimes even creates mirror images of the objects behind it.\u00a0<\/p>There are several mirrored galaxies in this deep-field image \u2013 you can see them in the orange stripes that flank the brightest cluster galaxy.<\/p>
Each galaxy, with its bright, star-filled centre, appears twice in each stripe.<\/p>
You can see their edges sparkling with stars, like sunlight catching the rim of a wave.<\/p>
Uranus<\/strong><\/h2>![\"A](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2023\/12\/webb-uranus.jpg\")
A view of Uranus, its rings and moons captured by the NIRCam (Near-Infrared Camera) on the James Webb Space Telescope. Credit: NASA, ESA, CSA, STScI<\/figcaption><\/figure>Uranus, a massive ice giant, was the first planet to be discovered with a telescope.<\/p>
It was identified in 1781 by German-British astronomer William Herschel<\/a>, who initially thought it was a comet<\/a> or a star<\/a>.\u00a0<\/p>Uranus takes an incredibly long time to orbit the Sun \u2013 84 years!<\/p>
That means it will be another 10 years before Uranus completes its third rotation around the Sun since it was discovered.<\/p>
Its orbit is something that sets it apart from its fellow planets in the Solar System: it appears to rotate on
This means each pole gets 42 years of continuous sunshine, followed by 42 years of darkness.<\/p>
JWST\u2019s NIRCam image of Uranus<\/a> puts the planet\u2019s north polar cap on display, along with its glowing outer rings.<\/p>Exoplanet LHS 475 b<\/strong><\/h2>![\"Webb's](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/LHS-475-b-webb.jpg\")
Webb’s transmission spectrum of exoplanet LHS 475 b<\/figcaption><\/figure>LHS 475 b was the first exoplanet<\/a> confirmed by JWST. Initially found by NASA\u2019s TESS exoplanet hunter<\/a>, JWST\u2019s observations go one step further.<\/p>It can measure the exoplanet\u2019s transmission \u2013 the light that passes through its atmosphere.<\/p>
In the case of LHS 475 b, astronomers could not detect any gases such as hydrogen or methane.<\/p>
This led them to deduce that the rocky exoplanet doesn\u2019t have an atmosphere<\/p>
In the diagram above, the flat yellow line represents the transmission spectrum of an exoplanet with no atmosphere, while the purple line shows what it would look like if it had a carbon-heavy atmosphere, while the green line models a methane-rich atmosphere.<\/p>
The grey data points of LHS 475 b show that it aligns most closely with the featureless model.<\/p>
The Ring Nebula<\/strong><\/h2>![\"M57,](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2023\/09\/01.weic2320b.jpg\")
M57, the Ring NebulaJames Webb Space Telescope, 21 August 2023Credit: ESA\/Webb, NASA, CSA, M. Barlow, N. Cox, R. Wesson<\/figcaption><\/figure>The Ring Nebula<\/a> is an example of a planetary nebula<\/a> \u2013 which, despite the name, have nothing to do with planets.<\/p>A few thousand years ago, a star was dying and turning into a red giant; as it did so its outer layers puffed up to many times their original size.<\/p>
As a star like this expands, its surface temperature drops from around 5,600\u00b0C (10,000\u00b0F) to 2,000\u20133,000\u00b0C (3,600\u20135,500\u00b0F).<\/p>
These cooler temperatures cause stars to produce light in the redder part of the spectrum.<\/p>
Over time, the loosely held gas layers get blown away from the star, creating a spherical cloud of gas, which past astronomers mistook for a planet.<\/p>
Orion Nebula<\/strong><\/h2>![\"James](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/webb-orion-nebula.jpg\")
James Webb Space Telescope wide-angled view of the Orion Nebula. Credit: NASA, ESA, CSA \/ Science leads and image processing: M. McCaughrean, S. Pearson<\/figcaption><\/figure>The Orion Nebula<\/a> is a stellar nursery about 2,000 times the mass of our Sun and incredibly bright.<\/p>It\u2019s part of the much larger Orion molecular cloud complex.<\/p>
Stars are forming throughout the complex but tend to concentrate in the Orion Nebula.<\/p>
JWST\u2019s instruments give us a new perspective on this well-studied object, and not always in ways originally intended.<\/p>
For instance, it\u2019s easy to see the brightest stars in this image because they have eight prongs due to JWST\u2019s famous diffraction spikes<\/a>.\u00a0<\/p>Collection of PHANGS galaxies<\/strong><\/h2>![\"19](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/webb-phangs-galaxies.jpg\")
19 face-on spiral galaxies imaged by the James Webb Space Telescope as part of the PHANGS study. Credit: NASA, ESA, CSA, STScI, Janice Lee (STScI), Thomas Williams (Oxford), and the PHANGS team<\/figcaption><\/figure>Galaxies are giant systems made up of stars, interstellar gas, dust and dark matter<\/a>, all held together by gravity.<\/p>They\u2019re divided into three main categories: elliptical, spiral and irregular. Elliptical galaxies account for around a third of known galaxies.<\/p>
They contain little gas and dust, and tend to no longer have active star-forming regions.<\/p>
Spiral galaxies, such as our own Milky Way, look like the classic flat discs with a bulge in their centres.<\/p>
These contain actively forming stars and are very common.<\/p>
Irregular galaxies fall into neither category, and are more common when observing the early Universe.<\/p>
As part of the Physics at High Angular Resolution in Nearby Galaxies (PHANGS) programme, JWST observed 19 nearby face-on spiral galaxies.<\/p>
Direct image of exoplanet HIP 65426 b<\/strong><\/h2>![\"Webb](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/webb-HIP65426.jpg\")
Webb image of HIP 65426 b. Credit: NASA, ESA, CSA, Alyssa Pagan (STScI)<\/figcaption><\/figure>For a planet, HIP 65426 b is unfathomably large.<\/p>
It\u2019s known as a \u2018super-Jupiter exoplanet\u2019 because it\u2019s between six and 12 times the mass of Jupiter, and it was the first exoplanet JWST observed directly.<\/p>
In 2022, it was given the official name Najsakopajk, which means \u2018Mother Earth\u2019 in the indigenous Mexican language Zoque.<\/p>
Najsakopajk is of great interest to planetary scientists, because it doesn\u2019t fit our current understanding of planet formation.<\/p>
It sits very far from its parent star, Matza \u2013 just under 100 times further away than Earth is from the Sun.\u00a0<\/p>
This separation meant JWST was able to capture the exoplanet\u2019s dim light (Najsakopajk is more than 10,000 times fainter than its host star in the near-infrared and a few thousand times fainter in the mid-infrared) without it being overwhelmed by its parent star.<\/p>
To do this, JWST used a coronagraph, which effectively blocks out a star\u2019s light so the telescope\u2019s instrument can snap a picture of the planet.<\/p>
Imaging at a variety of wavelengths reveals different characteristics of the exoplanet \u2013 a great showcase of the trailblazing techniques JWST can deploy.<\/p>
Wolf-Rayet star WR 140<\/strong><\/h2>![\"James](\"https:\/\/c02.purpledshub.com\/uploads\/sites\/48\/2024\/09\/webb-wolf-rayet-140.jpg\")
James Webb Space Telescope image of Wolf-Rayet 140. Credit: NASA, ESA, CSA, STScI, NASA-JPL, Caltech<\/figcaption><\/figure>
Now, the James Webb Space Telescope<\/a> is ushering in a new era of astronomy, granting an unprecedented view of the cosmos, observing infrared<\/a> wavelengths that are invisible to our eyes.<\/p> This can cut through dust clouds to see regions where new stars are being born, and travel vast distances allowing us to look back to the Universe\u2019s earliest days.<\/p> The James Webb Space Telescope has been snapping phenomenal pictures of our breathtaking Universe for over two years now.<\/p> Here are 10 of my favourites taken so far.<\/p> Nebulae<\/a> are giant swirls of interstellar gas and dust. Some types of nebulae are called \u2018stellar nurseries\u2019 because eddies of gas and dust begin to coalesce, their gravity attracting more matter.<\/p> Eventually these clumps collapse in on themselves and stars are born.<\/p> One such stellar nursery, the Pillars of Creation, was first brought to the public\u2019s attention when it was photographed by the Hubble Space Telescope in 1995<\/a>.<\/p> To give some idea of scale, the longest pillar on the left projects some four lightyears<\/a> into space and the small projections on the end are about the size of our whole Solar System.\u00a0<\/p> While Hubble\u2019s view was blocked by the nebula\u2019s dust, JWST\u2019s infrared vision is able to peek through, so we can develop a better understanding of how star formation occurs within these stellar nurseries.<\/p> A number of <\/strong>years ago, I met Robert Williams, who was the director of the Space Telescope Science Institute in Baltimore.<\/p> He commissioned the first deep-field observation using Hubble \u2013 the Hubble Deep Field (HDF).<\/p> In these surveys, the telescope was directed to look at a particular part of the sky for days, rather than the usual minutes.\u00a0<\/p> Many people were shocked when Robert first suggested this idea.<\/p> Telescopes like JWST and Hubble are in high demand, yet here was Robert proposing to do a 10-day exposure.<\/p> Worse, he and his team were choosing an area of the sky with no known bright objects \u2013 a field of view that seemed to be empty space.<\/p> The observation went ahead during December 1995 and 342 separate exposures were taken.<\/p> The HDF exposures revealed the distance, age and composition of the galaxies imaged.<\/p> It was such a success, that JWST recreated the feat, taking this image of galaxy cluster SMACS 0723.<\/p> There is so <\/strong>much to look at in JWST\u2019s image of SMACS 0723 (Webb\u2019s First Deep Field) that it warrants a closer look.<\/p> The galaxies<\/a> are bound together by gravity<\/a>, concentrating them in a cluster. Their combined mass can manipulate and bend the light from the galaxies behind them.<\/p> This natural phenomenon is called gravitational lensing<\/a>. The giant object magnifies, distorts and sometimes even creates mirror images of the objects behind it.\u00a0<\/p> There are several mirrored galaxies in this deep-field image \u2013 you can see them in the orange stripes that flank the brightest cluster galaxy.<\/p> Each galaxy, with its bright, star-filled centre, appears twice in each stripe.<\/p> You can see their edges sparkling with stars, like sunlight catching the rim of a wave.<\/p> Uranus, a massive ice giant, was the first planet to be discovered with a telescope.<\/p> It was identified in 1781 by German-British astronomer William Herschel<\/a>, who initially thought it was a comet<\/a> or a star<\/a>.\u00a0<\/p> Uranus takes an incredibly long time to orbit the Sun \u2013 84 years!<\/p> That means it will be another 10 years before Uranus completes its third rotation around the Sun since it was discovered.<\/p> Its orbit is something that sets it apart from its fellow planets in the Solar System: it appears to rotate on This means each pole gets 42 years of continuous sunshine, followed by 42 years of darkness.<\/p> JWST\u2019s NIRCam image of Uranus<\/a> puts the planet\u2019s north polar cap on display, along with its glowing outer rings.<\/p> LHS 475 b was the first exoplanet<\/a> confirmed by JWST. Initially found by NASA\u2019s TESS exoplanet hunter<\/a>, JWST\u2019s observations go one step further.<\/p> It can measure the exoplanet\u2019s transmission \u2013 the light that passes through its atmosphere.<\/p> In the case of LHS 475 b, astronomers could not detect any gases such as hydrogen or methane.<\/p> This led them to deduce that the rocky exoplanet doesn\u2019t have an atmosphere<\/p> In the diagram above, the flat yellow line represents the transmission spectrum of an exoplanet with no atmosphere, while the purple line shows what it would look like if it had a carbon-heavy atmosphere, while the green line models a methane-rich atmosphere.<\/p> The grey data points of LHS 475 b show that it aligns most closely with the featureless model.<\/p> The Ring Nebula<\/a> is an example of a planetary nebula<\/a> \u2013 which, despite the name, have nothing to do with planets.<\/p> A few thousand years ago, a star was dying and turning into a red giant; as it did so its outer layers puffed up to many times their original size.<\/p> As a star like this expands, its surface temperature drops from around 5,600\u00b0C (10,000\u00b0F) to 2,000\u20133,000\u00b0C (3,600\u20135,500\u00b0F).<\/p> These cooler temperatures cause stars to produce light in the redder part of the spectrum.<\/p> Over time, the loosely held gas layers get blown away from the star, creating a spherical cloud of gas, which past astronomers mistook for a planet.<\/p> The Orion Nebula<\/a> is a stellar nursery about 2,000 times the mass of our Sun and incredibly bright.<\/p> It\u2019s part of the much larger Orion molecular cloud complex.<\/p> Stars are forming throughout the complex but tend to concentrate in the Orion Nebula.<\/p> JWST\u2019s instruments give us a new perspective on this well-studied object, and not always in ways originally intended.<\/p> For instance, it\u2019s easy to see the brightest stars in this image because they have eight prongs due to JWST\u2019s famous diffraction spikes<\/a>.\u00a0<\/p> Galaxies are giant systems made up of stars, interstellar gas, dust and dark matter<\/a>, all held together by gravity.<\/p> They\u2019re divided into three main categories: elliptical, spiral and irregular. Elliptical galaxies account for around a third of known galaxies.<\/p> They contain little gas and dust, and tend to no longer have active star-forming regions.<\/p> Spiral galaxies, such as our own Milky Way, look like the classic flat discs with a bulge in their centres.<\/p> These contain actively forming stars and are very common.<\/p> Irregular galaxies fall into neither category, and are more common when observing the early Universe.<\/p> As part of the Physics at High Angular Resolution in Nearby Galaxies (PHANGS) programme, JWST observed 19 nearby face-on spiral galaxies.<\/p> For a planet, HIP 65426 b is unfathomably large.<\/p> It\u2019s known as a \u2018super-Jupiter exoplanet\u2019 because it\u2019s between six and 12 times the mass of Jupiter, and it was the first exoplanet JWST observed directly.<\/p> In 2022, it was given the official name Najsakopajk, which means \u2018Mother Earth\u2019 in the indigenous Mexican language Zoque.<\/p> Najsakopajk is of great interest to planetary scientists, because it doesn\u2019t fit our current understanding of planet formation.<\/p> It sits very far from its parent star, Matza \u2013 just under 100 times further away than Earth is from the Sun.\u00a0<\/p> This separation meant JWST was able to capture the exoplanet\u2019s dim light (Najsakopajk is more than 10,000 times fainter than its host star in the near-infrared and a few thousand times fainter in the mid-infrared) without it being overwhelmed by its parent star.<\/p> To do this, JWST used a coronagraph, which effectively blocks out a star\u2019s light so the telescope\u2019s instrument can snap a picture of the planet.<\/p> Imaging at a variety of wavelengths reveals different characteristics of the exoplanet \u2013 a great showcase of the trailblazing techniques JWST can deploy.<\/p>Pillars of creation<\/strong><\/h2>
Deep view around SMACS 0723<\/strong><\/h2>
SMACS 0723 zoomed in<\/strong><\/h2>
Uranus<\/strong><\/h2>
Exoplanet LHS 475 b<\/strong><\/h2>
The Ring Nebula<\/strong><\/h2>
Orion Nebula<\/strong><\/h2>
Collection of PHANGS galaxies<\/strong><\/h2>
Direct image of exoplanet HIP 65426 b<\/strong><\/h2>
Wolf-Rayet star WR 140<\/strong><\/h2>