Found Images: 2023 March

[starsurfer]

M44
http://www.astrosurf.com/ilizaso/orriak ... Q_U16m.htm
Copyright: Iñaki Lizaso

[bystander]

A Legendary Nebula
NOIRLab Image of the Week | 2023 Mar 15

Image Credit: KPNO/NOIRLab/NSF/AURA

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The nebula that keeps on giving, Messier 1 (Crab Nebula) is captured here by the Nicholas U. Mayall 4-meter Telescope from Kitt Peak National Observatory (KPNO), a Program of NSF’s NOIRLab. The storied history of this supernova remnant in modern astronomy begins when it was recorded in 1731 by British astronomer John Bevis, who believed it was nothing more than a cloudy blob. It was more than three decades later that French comet hunter Charles Messier clarified that the object was in fact something, and it became the first entry in his catalog of nebulae and star clusters. Then in the early 20th century astronomers connected Messier 1 to a supernova explosion observed by Chinese astronomers in 1054. This made the Crab Nebula the first astronomical object to be connected to a previously observed supernova.

A pulsar — the ultra-dense, rapidly spinning remnant of a star — inside the Crab Nebula was discovered in 1968 at radio wavelengths. Its presence in the optical part of the spectrum was confirmed a year later by Americans John Cocke and Donald Taylor and British astronomer Michael Disney using the UArizona 0.9-meter Spacewatch Telescope at KPNO. The Crab Pulsar then became integral in advancing scientific understanding of supernova remnants: it was the first of its kind to link a historical supernova to a pulsar whose precise age is known.

This image was the last taken with the Mayall telescope before the Dark Energy Spectroscopic Instrument (DESI) was installed. The Crab Nebula was also the first target for the telescope’s first light in 1973.

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Almost Touching
ESO Picture of the Week | SEST | 2023 Mar 20

Image Credit: ESO/A. Ghizzi Panizza (albertoghizzipanizza.com)

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This Picture of the Week shows a beautiful meeting between the Swedish–ESO Submillimetre Telescope (SEST) and the Milky Way, apparently almost touching each other. This shot was taken at ESO’s La Silla Observatory, located on the outskirts of the Chilean Atacama Desert, at an altitude of 2400 metres.

Light and darkness shape the Milky Way as it stretches across the night sky. The dark patches are dust clouds blocking the light behind them, coming from millions of stars in the central region of our galaxy.

SEST was built on behalf of the Swedish Natural Science Research Council (NFR) and ESO in 1987. It is a 15-m radio telescope, and it was the only large sub-millimetre telescope in the southern hemisphere at the time of first light. In 2003, the telescope was decommissioned as it was superseded by the Atacama Pathfinder EXperiment telescope (APEX) and the Atacama Large Millimeter / submillimeter Array (ALMA) further north in Chile. Over the years SEST has observed a wide range of astronomical objects, from comets to stellar nurseries and galaxies.

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Portrait of a Galactic Jellyfish
ESA Hubble Picture of the Week | 2023 Mar 20

A thin spiral galaxy is seen edge-on in the lower right. Its bulge and arms are very bright, mixing reddish and bluish light. Patchy blue trails extend below it, resembling tentacles, made from star-forming regions. Six small, reddish elliptical galaxies are scattered. A very large elliptical galaxy with two cores sits by the top of the frame.

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Image Credit: ESA/Hubble & NASA, M. Gullieuszik and the GASP team

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The galaxy JW100 features prominently in this image from the NASA/ESA Hubble Space Telescope, with streams of star-forming gas dripping from the disc of the galaxy like streaks of fresh paint. These tendrils of bright gas are formed by a process called ram pressure stripping, and their resemblance to dangling tentacles has led astronomers to refer to JW100 as a ‘jellyfish’ galaxy. It is located in the constellation Pegasus, over 800 million light-years away.

Ram pressure stripping occurs when galaxies encounter the diffuse gas that pervades galaxy clusters. As galaxies plough through this tenuous gas it acts like a headwind, stripping gas and dust from the galaxy and creating the trailing streamers that prominently adorn JW100. The bright elliptical patches in the image are other galaxies in the cluster that hosts JW100.

As well as JW100’s bright tendrils, this image also contains a remarkably bright area of diffuse light towards the top of this image which contains two bright blotches at its core. This is the core of IC 5338, the brightest galaxy in the galaxy cluster, known as a cD galaxy. It’s not unusual for cD galaxies to exhibit multiple nuclei, as they are thought to grow by consuming smaller galaxies, the nuclei of which can take a long time to be absorbed. The bright points of light studding its outer fringes are a rich population of globular clusters.

This observation took advantage of the capabilities of Hubble’s Wide Field Camera 3 (WFC3), and is part of a sequence of observations designed to explore star formation in the tendrils of jellyfish galaxies. These tendrils represent star formation under extreme conditions, and could help astronomers understand the process of star formation elsewhere in the universe.

UV and Hα HST Observations of Six GASP Jellyfish Galaxies ~ Marco Gullieuszik et al

• Astrophysical Journal 945(1):54 (2023 Mar 01) DOI: 10.3847/1538-4357/acb59b
• arXiv > astro-ph > arXiv:2301.08279 > 19 Jan 2023

HST Imaging of Star-Forming Clumps in Six Gasp Ram-Pressure Stripped Galaxies ~ Eric Giunchi et al

• arXiv > astro-ph > arXiv:2302.10615 > 21 Feb 2023

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Everything, in One Place, All at Once
ESA Hubble Picture of the Week | 2023 Mar 27

A spiral galaxy. It has two almost-straight arms coming from the left and right of the core that meet a starry ring around the galaxy’s edge. The ring is bluish in colour, and the core is golden and shining. A faint halo of light also surrounds the galaxy. There is one bright star with many diffraction spikes, and a few small stars all around on a black background.

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Credit: ESA/Hubble & NASA, A. Barth, R. Mushotzky

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This luminous Picture of the Week shows Z 229-15 — imaged here in beautiful detail by the NASA/ESA Hubble Space Telescope — a celestial object that lies about 390 million light-years from Earth in the constellation Lyra. Z 229-15 is one of those interesting celestial objects that, should you choose to research it, you will find defined as several different things: sometimes as an active galactic nucleus (an AGN); sometimes as a quasar; and sometimes as a Seyfert galaxy. Which of these is Z 229-15 really? The answer is that it is all of these things all at once, because these three definitions have significant overlap.

AGNs and quasars are both described in detail in the Hubble Word Bank, but in essence an AGN is a small region at the heart of certain galaxies (called active galaxies) that is far brighter than just the galaxy’s stars would be. The extra luminosity is due to the presence of a supermassive black hole at the galaxy’s core. Material sucked into a black hole actually doesn’t fall directly into it, but instead is drawn into a swirling disc, from where it is inexorably tugged towards the black hole. This disc of matter gets so hot that it releases a large amount of energy across the electromagnetic spectrum, and that’s what makes AGNs appear so bright.

Quasars are a particular type of AGN; they are typically both extremely bright and extremely distant from Earth — several hundred million light-years is considered nearby for a quasar, making Z 229-15 positively local. Often an AGN is so bright that the rest of the galaxy cannot be seen, but Seyfert galaxies are active galaxies that host very bright AGNs (quasars) while the rest of the galaxy is still observable. So Z 229-15 is a Seyfert galaxy that contains a quasar, and that, by definition, hosts an AGN. Classification in astronomy can be a challenge!

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Cosmic Seahorse
ESA Webb Picture of the Month | 2023 Mar 28

Many small galaxies are scattered on a black background: mainly, white, oval-shaped and red, spiral galaxies. To the lower right is a galaxy cluster, with a very large and bright elliptical galaxy at its centre. Thin, reddish, stretched-out arcs surround it. One arc is thick and much brighter. Another red galaxy is large and warped, just next to the cluster core.

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Credit: ESA/Webb, NASA & CSA, J. Rigby

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Streaks of light and bright arcs betray the presence of a vast gravitational lens in this image from the NASA/ESA/CSA James Webb Space Telescope. A galaxy cluster in the foreground has magnified distant galaxies, warping their shapes and creating the bright smears of light spread throughout this image. This effect, referred to by astronomers as gravitational lensing, occurs when a massive celestial object such as a galaxy cluster causes a sufficient curvature of spacetime for light to be visibly bent around it, as if by a gargantuan lens.

One of the consequential effects of gravitational lensing is that it can magnify distant astronomical objects, letting astronomers study objects that would otherwise be too faint or far away. This useful quirk of gravitational lensing has also been used to reveal some of the most distant galaxies humanity has ever encountered. The long, bright, and distorted arc spreading out near the core is one such example. A distant galaxy known as the Cosmic Seahorse, its brightness is greatly magnified by the gravitational lens, which has enabled astronomers to study star formation there.

This image was captured by NIRCam, Webb’s primary near-infrared camera, and contains the lensing galaxy cluster SDSS J1226+2149. It lies at a distance of around 6.3 billion light-years from Earth, in the constellation Coma Berenices. By combining Webb’s sensitivity with the magnifying effect of gravitational lensing, astronomers were able to use this gravitational lens to explore the earliest stages of star formation in distant galaxies. To do so, they relied on earlier studies by the NASA/ESA Hubble Space Telescope, which provided the ‘prescription’ for this gravitational lens.

This image shows only one observation from a programme designed to probe star formation in distant galaxies. As well as revealing how quickly stars form and characterising the environments in these galaxies that gave rise to new stars, these observations will demonstrate the capabilities of Webb and provide richly detailed datasets to the astronomical community. Astronomers expect Webb’s crystal-clear vision and cutting-edge instruments to provide new insights into star formation in distant, gravitationally lensed galaxies.

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NEWFIRM Imager Captures Globular Cluster Omega Centauri
NOIRLab NEWFIRM Announcement | 2023 Mar 28

Powerful near-infrared imager will support multi-messenger astronomy research

Globular Cluster Omega Centauri ~ Credit: CTIO/NOIRLab/DOE/NSF/AURA, T.A.
Rector (Univ of Alaska Anchorage/NOIRLab), M. Zamani & D. de Martin (NOIRLab)

NEWFIRM, a high-resolution, near-infrared imager with a wide field of view, has completed its commissioning run on the Víctor M. Blanco 4-meter Telescope at Cerro Tololo Inter-American Observatory (CTIO) in Chile, a Program of NSF's NOIRLab. During its commissioning and capabilities testing, astronomers used NEWFIRM to capture a detailed image of the Omega Centauri globular cluster.

At about 17,000 light-years from Earth in the direction of the constellation Centaurus, Omega Centauri is the largest globular cluster in the Milky Way, containing approximately 10 million stars, making it a popular target for observations.

This observing run marks NEWFIRM’s second tenure at CTIO. Prior to returning to Chile, NEWFIRM was installed on the Nicholas U. Mayall Telescope at Kitt Peak National Observatory (KPNO) in Arizona, also a Program of NOIRLab, for observing runs in 2006–2010 and 2012–2016. It was previously installed on the Blanco telescope in 2010–2011.

Prior to re-installation, NEWFIRM was upgraded with new software, control hardware, guiders, computers, and interfaces, thanks to a competitive NSF grant in support of projects promoting multi-messenger astronomy. ...

[bystander]

Multiple Green Flashes
NOIRLab Image of the Week | 2023 Mar 28

CTIO/NOIRLab/NSF/AURA/T. Slovinský & P. Horálek (IoP Opava)

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From the high altitude of Cerro Tololo Inter-American Observatory (CTIO) in Chile, two astrophotographers captured the elusive sunset phenomenon known as the green flash. This stunning trick of light occurs at sunset and sunrise when light from the Sun travels through the thickest part of Earth’s atmosphere. Acting like a prism, Earth's atmosphere bends, or refracts, the light and separates it into its component wavelengths. Blue and violet light are scattered by the atmosphere, while red, orange and yellow are refracted below the solar disk below the horizon, leaving the green light the most visible during the few seconds that the Sun disappears below the horizon.

Here, though, is another uncommon phenomenon. Distinct thermal layers above the Pacific Ocean led to a Fata Morgana mirage displaying several green flashes. Two photographers from the recent NOIRLab 2022 Photo Expedition jointly worked the controls of the camera to quickly capture the elusive phenomenon.

This image was the NASA Astronomy Picture of the Day on 28 March 2023.

APOD: A Multiple Green Flash Sunset (2023 Mar 28)

[barretosmed]

COMET C/2022 E3 (ZTF)


MORE DETAILS
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EQUIPMENT:
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DATE: 02/19/2023

Location: Munhoz - MG - Brazil
PROCESSING AND CAPTURE:
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Author: Fernando Oliveira de Menezes
Email: Barretosmed@hotmail.com
(Organizing author of the book Astrofotografia Amadora no Brasil)
[https://clubedeautores.com.br/livro/ast ... -no-brasil]

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A Record-Breaking Burst
ESO Picture of the Week | 2023 Mar 29

Image Ctredit: ESO/Malesani et al., The Stargate Collaboration

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The circled spot in this Picture of the Week has almost disappeared. What happened? This sequence of images, taken in optical light with ESO’s Very Large Telescope (VLT), shows the gamma-ray burst GRB 221009A fading away. Gamma-ray bursts (GRBs) are the most luminous phenomena that we know of in the universe, and GRB 221009A is the brightest one yet as seen from Earth.

The burst was detected in October 2022 by several gamma-ray space telescopes, such as NASA's Swift and Fermi and ESA’s INTEGRAL. Then, a few hours after the initial detection, ESO’s X-shooter instrument at the VLT took a spectrum, which provided the first distance measurement to the explosion of approximately 2400 million light years. Thanks to this distance measurement, a team of astronomers led by Daniele Bjørn Malesani ... ruled out an origin in the Milky Way, although the burst is still much closer to us than typical GRBs.

The distance also allowed the team to compute the intrinsic luminosity of the explosion. Despite being in our cosmic backyard, the burst is still intrinsically very luminous. It is in fact the most intense GRB for which we could measure its luminosity, and the brightest ever as seen from Earth in the 55 years since the first gamma-ray satellites were put in orbit. According to Malesani’s team, a burst so energetic and so close as this one should probably be observable once every 1000 years.

A team led by Andrew Levan ... observed this unique explosion with JWST at longer wavelengths. Combining the X-shooter spectrum with the JWST data allows for an in-depth investigation of the nature of this unique event. ...

The brightest GRB ever detected: GRB 221009A as a highly luminous event at z = 0.151 ~ D. B. Malesani et al

• arXiv > astro-ph > arXiv:2302.07891 > 15 Feb 2023

The first JWST spectrum of a GRB afterglow: No bright supernova
in observations of the brightest GRB of all time, GRB 221009A ~ A. J. Levan et al

• arXiv > astro-ph > arXiv:2302.07761 > 15 Feb 2023 (v1), 22 Mar 2023 (v2)