? Discovering the Cosmic Treasures of Chameleon I with STYX AI and JWST ?
Prepare to embark on a journey of cosmic exploration as we unveil the fascinating discoveries made by an international team of astronomers using the NASA/ESA/CSA James Webb Space Telescope. In December 2020, the team revealed a groundbreaking result - the detection of diverse ices in the darkest and coldest regions of the molecular cloud Chameleon I.
These ices, found approximately 631 light-years away in the constellation Sculptor, play a crucial role in the formation of future exoplanets and hold the key to understanding the origin of complex molecules - the building blocks of life. By examining these simple icy molecules, astronomers gain insights into the processes that lead to the creation of planetary atmospheres, as well as molecules like sugars, alcohols, and simple amino acids.
Through Webb's state-of-the-art Near-Infrared Camera (NIRCam) and Mid-Infrared Instrument (MIRI), the team meticulously studied the molecular cloud and identified frozen forms of various molecules, including carbonyl sulfide, ammonia, methane, and even the simplest complex organic molecule, methanol. This comprehensive census offers a glimpse into the vast array of icy ingredients available to shape the future generations of stars and planets.
The Chameleon I molecular cloud, in the process of forming dozens of young stars, presents a unique opportunity to trace the journey of these ices from their formation to the assemblage of icy comets. The icy grains, which grow in size as they funnel into protoplanetary discs around young stars, enable astronomers to study the potential icy molecules that will eventually become part of future exoplanets.
STYX AI's advanced image processing technology adds a new dimension to this captivating discovery. By processing the image data in 3D, we reveal intricate details and depths, elevating your cosmic exploration to unprecedented levels. Our meticulous process unlocks the mysteries hidden within the cosmic wonders, providing greater understanding of the structural morphology and nature of the universe.
Join us on this cosmic voyage, as we continue to explore the universe's secrets, opening new windows of knowledge and expanding our understanding of the cosmos. Subscribe to our channel to stay informed about the latest astronomical breakthroughs, captivating discoveries, and cutting-edge image processing by STYX AI. Be part of the quest for cosmic enlightenment and witness the beauty and complexity of our universe like never before. ?✨
Credit:
NASA, ESA, CSA, and M. Zamani (ESA/Webb); Science: F. Sun (Steward Observatory), Z. Smith (Open University), and the Ice Age ERS Team.
3D image processing Styx AI
#astronomy #science #space #new #nasa #nature #styxai #cosmicjourney #spaceexploration #eso
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https://www.youtube.com/watch?v=Yqi-lSi8sgI
A Poem to Music.
The arrow of time, both ruthless and kind, I stroll through the park, a peaceful mind. As raindrops fall and thunderstorms break, Life's beauty unfolds, a sweet, gentle ache. Every breath is a gift, each step, a tale, Time's arrow propelling, a relentless trail. The past stands behind, yet resides in our core, The future unknown, forever more. With each step, chase your dreams and delight, March on with courage, even in the night. Let rain wash away all your darkest doubts, The arrow of time cares not what life's about. Peace and love in each stride do dwell, Share your hope, let compassion swell. Take heed of my words, both cruel and nice, The arrow of time, in its ceaseless device.
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https://www.youtube.com/watch?v=PkfiWmgtG8M
"Thousands of galaxies flood this near-infrared image of galaxy cluster SMACS 0723. High-resolution imaging from NASA’s James Webb Space Telescope combined with a natural effect known as gravitational lensing made this finely detailed image possible.
First, focus on the galaxies responsible for the lensing: the bright white elliptical galaxy at the center of the image and smaller white galaxies throughout the image. Bound together by gravity in a galaxy cluster, they are bending the light from galaxies that appear in the vast distances behind them. The combined mass of the galaxies and dark matter act as a cosmic telescope, creating magnified, contorted, and sometimes mirrored images of individual galaxies.
Clear examples of mirroring are found in the prominent orange arcs to the left and right of the brightest cluster galaxy. These are lensed galaxies – each individual galaxy is shown twice in one arc. Webb’s image has fully revealed their bright cores, which are filled with stars, along with orange star clusters along their edges.
Not all galaxies in this field are mirrored – some are stretched. Others appear scattered by interactions with other galaxies, leaving trails of stars behind them.
Webb has refined the level of detail we can observe throughout this field. Very diffuse galaxies appear like collections of loosely bound dandelion seeds aloft in a breeze. Individual “pods” of star formation practically bloom within some of the most distant galaxies – the clearest, most detailed views of star clusters in the early universe so far.
One galaxy speckled with star clusters appears near the bottom end of the bright central star’s vertical diffraction spike – just to the right of a long orange arc. The long, thin ladybug-like galaxy is flecked with pockets of star formation. Draw a line between its “wings” to roughly match up its star clusters, mirrored top to bottom. Because this galaxy is so magnified and its individual star clusters are so crisp, researchers will be able to study it in exquisite detail, which wasn’t previously possible for galaxies this distant.
The galaxies in this scene that are farthest away – the tiniest galaxies that are located well behind the cluster – look nothing like the spiral and elliptical galaxies observed in the local universe. They are much clumpier and more irregular. Webb’s highly detailed image may help researchers measure the ages and masses of star clusters within these distant galaxies. This might lead to more accurate models of galaxies that existed at cosmic “spring,” when galaxies were sprouting tiny “buds” of new growth, actively interacting and merging, and had yet to develop into larger spirals. Ultimately, Webb’s upcoming observations will help astronomers better understand how galaxies form and grow in the early universe.
NIRCam was built by a team at the University of Arizona and Lockheed Martin’s Advanced Technology Center.
For a full array of Webb’s first images and spectra, including downloadable files, please visit: https://webbtelescope.org/news/first-images
Object Name SMACS 0723-73 (1RXS J072319.7-732735, SMACS J0723.3-7327)
Object Description Lensing Galaxy Cluster
R.A. Position 07:23:19.5
Dec. Position -73:27:15.6
Constellation Volans
Distance Redshift of cluster is z=0.39 (about 4.24 billion light-years)
Dimensions Image is about 2.4 arcmin across
Instrument NIRCam
Exposure Dates 7 June 2022
Filters F090W, F150W, F200W, F277W, F356W, F444W
Credits
IMAGE: NASA, ESA, CSA, STScI
Processing STYX AI
@NASA @NASAGoddard @NASAJPL @NASAgovVideo @NASAWebbTelescope @EuropeanSpaceAgency
#science #new #astronomy
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https://www.youtube.com/watch?v=D2bH1hNY8vA
In December 2020, the ESA/Hubble team published a breathtaking image of GAL-CLUS-022058s, located in the constellation of Fornax. This image shows one of the largest and most complete Einstein rings ever discovered, created by the process of gravitational lensing. This phenomenon is where light shining from far away is bent and pulled by the gravity of an object between its source and the observer. In this case, the light from the background galaxy has been distorted into an almost perfect ring by the gravity of the galaxy cluster sitting in front of it.
A team of European astronomers used a multi-wavelength dataset, which includes inputs from the Hubble Space Telescope, to study this Einstein ring in detail. The team used a lensing model, derived from the Hubble imaging, to calculate the amplification factor, which allowed them to study the intrinsic physical properties of the lensed galaxy. They determined the galaxy’s magnification factor to be 20, which effectively makes the Hubble Space Telescope’s observing capability equivalent to that of a 48-metre telescope. This finding is larger than the currently planned extremely large telescopes.
Styx AI is developing innovative techniques based on quantum mechanics, depth maps, generative imaging, machine learning, and new mathematics to move the "looking glass" of complex nonuniform spacetime. Their process can break down an image into nearly infinite pieces, providing greater depth and detail to reveal previously unseen information.
Credit: ESA/Hubble & NASA, S. Jha
Acknowledgement: L. Shatz
Processed by STYX AI
#hubblespacetelescope #space #nasa #GravitationalLensing #astronomy #styxai #quantummechanics #machinelearning #galaxy
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https://www.youtube.com/watch?v=vUsfZVkgeVU
Welcome to Styx AI, a pioneering force in the realm of image processing for medical and astronomical applications. With our deep-rooted expertise and innovative techniques grounded in quantum mechanics, we have completely transformed the imaging landscape across diverse industries. Our unwavering commitment to pushing the boundaries of technology drives us to develop and validate software that uncovers novel information and insights about the vast universe. By harnessing the pristine data derived from astronomical imaging, we enable groundbreaking discoveries and simultaneously advance the field of medical imaging, particularly in the area of cancer detection.
At Styx AI, our image decomposition techniques empower us to extract remarkably accurate features, reconstruct images, and provide invaluable insights into the intricate structural morphology of target images. Through this meticulous process, we possess the ability to deconstruct an image into a nearly infinite number of segments, expertly reconstructing them to reveal hidden depths and previously obscured details. Our ongoing endeavors also include the development of advanced 3D depth models, elevating the realm of image processing to new dimensions.
Situated in the northern celestial hemisphere, Abell 1703 stands as a breathtaking cosmic spectacle. Comprised of over a hundred distinct galaxies, it acts as a gravitational lens, akin to a cosmic telescope. The gravitational pull exerted by the massive foreground galaxy cluster (represented by the scattered yellow elliptical galaxies in the image) bends the trajectory of light rays, thereby stretching and amplifying the brightness of distant galaxies. This process leads to the distortion of their shapes and the creation of multiple banana-shaped images, culminating in the captivating visual masterpiece presented here. Through this gravitational lensing phenomenon, we are afforded a glimpse deeper into the universe than what current technology alone can offer. Abell 1703 resides at an astounding distance of 3 billion light-years from Earth, denoted by a redshift of 0.26.
Join us at Styx AI as we continue to push the frontiers of image processing, pioneering breakthroughs in both medical and astronomical realms. Through our cutting-edge techniques and quantum-powered innovations, we unlock the hidden treasures of the universe, revealing its grandeur in ways never before imagined.
#StyxAI
#ImageProcessing
#quantummechanics
#AstronomicalDiscoveries
#cancerdetection
#3DDepthModels
#gravitationallensing
#Abell1703
#UnlockingTheUniverse
Original image Credit: NASA, ESA, and Johan Richard (Caltech, USA)
Acknowledgement: Davide de Martin & James Long (ESA/Hubble)
Processed Depth Model: STYX AI
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https://www.youtube.com/watch?v=JF27j_cbJyo
Welcome to Styx AI, a pioneering force in the field of image processing for medical and astronomical applications. With our deep-rooted expertise and innovative techniques grounded in quantum mechanics, we are revolutionizing imaging across diverse industries. Our relentless pursuit of technological advancements drives us to develop and validate software that uncovers new information and insights about the vast universe. By harnessing pristine astronomical imaging data, we enable groundbreaking discoveries and advance the field of image processing, leading to remarkable insights.At Styx AI, our cutting-edge image decomposition techniques empower us to extract highly accurate features, reconstruct images, and provide invaluable insights into the intricate structural morphology of target images. Through our meticulous process, we possess the ability to deconstruct an image into a nearly infinite number of segments, expertly reconstructing them to unveil hidden depths and previously obscured details. As part of our ongoing endeavors, we are actively developing advanced 3D depth models that elevate image processing to new dimensions.In this captivating image captured by NASA's Hubble Space Telescope's Advanced Camera for Surveys (ACS), we are treated to a breathtaking sight. A massive cluster of yellowish galaxies appears ensnared within a mesmerizing red and blue spider web of eerily distorted background galaxies. This awe-inspiring picture showcases the phenomenon of gravitational lensing, made possible by the immense gravitational pull of the trillion stars and dark matter within the extraordinary galaxy cluster known as Abell 1689. Acting as a two-million-light-year-wide "lens" in space, the gravitational influence of this cluster bends and magnifies the light from galaxies located far beyond its reach. Remarkably, some of the faintest objects captured in this image are estimated to be over 13 billion light-years away, offering us a glimpse into the early universe (redshift value 6).While gravitational lensing has been previously studied by Hubble and ground-based telescopes, this ACS image provides an unparalleled level of detail. It reveals ten times more arcs than what would be visible through ground-based telescopes, thanks to the ACS's exceptional sensitivity and superior image resolution compared to previous Hubble cameras. The picture presents an immense jigsaw puzzle for Hubble astronomers to spend months untangling. Interlaced with the foreground cluster are thousands of galaxies, which represent lensed images of galaxies from the background universe. Detailed analysis of these images promises to shed light on various aspects of astrophysics, including galaxy evolution, the curvature of space, and the mysteries surrounding dark matter. The picture stands as a remarkable testament to Albert Einstein's prediction that gravity warps space and distorts the paths of light.Join us on an extraordinary journey as we explore the captivating wonders of Abell 1689, delving into its gravitational lensing effects and unraveling the mysteries it holds. Through our advanced image processing techniques, we strive to unlock deeper insights into the workings of the cosmos and contribute to the ever-expanding frontiers of knowledge.
Credit:NASA, N. Benitez (JHU), T. Broadhurst (The Hebrew University), H. Ford (JHU), M. Clampin(STScI), G. Hartig (STScI), G. Illingworth (UCO/Lick Observatory), the ACS Science Team and ESA
3D image models, video, and filters: STYX AI
#styxai #quantummechanics #astronomicaldiscoveries #gravitationallensing #astrophotography #Abell1689 #hubblespacetelescope #cosmicwonders #astronomy
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https://www.youtube.com/watch?v=3I2Fn0Ffyo4