James Webb Space Telescope begins historic mission

[dstig1]

Cool but it seems like Hubble is doing the same thing as a kid who just got a new sibling in the house. LOOK AT MEEEEEEE!!!!!! Mom & Dad: yeah yeah junior, we see you, but did you see what your new sister did??!?!?!

 

[cqaigy2]

Cool but it seems like Hubble is doing the same thing as a kid who just got a new sibling in the house. LOOK AT MEEEEEEE!!!!!! Mom & Dad: yeah yeah junior, we see you, but did you see what your new sister did??!?!?!

Seems to me it's more like, here is what Hubble did, as compared to what JWS is doing.

 

[ruffdog]

 

[ArlyA]

Behold! Webb Telescope’s first Mars image reveals a troubled planet​

The James Webb Space Telescope reveals a landscape of meteor impacts, massive eruptions, and flowing water.
Kiona Smith
18 hours ago
The James Webb Space Telescope’s first images of Mars reveal a swath of the planet’s eastern hemisphere, including one of the Solar System’s largest impact craters and a lava flow from a long-extinct shield volcano. Webb captured the images with its Near InfraRed Camera, or NIRCam, instrument on Sept. 5, along with data from its Near InfraRed Spectrometer (NIRSpec).
What’s new — About 4 billion years ago, something enormous slammed into the young planet Mars, leaving behind a crater 2,300 kilometers (1,400 miles) wide and 7 kilometers (4.4 miles) deep just south of the planet’s equator. The crater, now known as Hellas Basin, shows up in dark orange in Webb’s first image of the eastern half of Mars — a cooler splotch against the brightness of the rest of the daylit side of the planet, which glows bright yellow with radiating heat.

In these images, you can see a map of the Martian surface on the left, and Webb’s images of Mars in two different wavelengths on the right.ESA
Shorter wavelengths of infrared light reveal more detail; you can see the northeastern edge of the Hellas Basin, along with another of Mars’ largest craters, the 467 kilometer (290 mile) wide Huygens Crater. Water once flowed through Huygens, and it carved a branching network of channels into the rocky surface. NASA’s Mars Reconnaissance Orbiter also spotted clay and carbonate minerals, both of which only form in wet environments, exposed by a smaller impact crater inside Huygens.
To the east of Huygens Crater lies a dark flow of basalt from long-extinct volcano Syrtis Major. The basalt plain is just southwest of the Perseverance Rover’s landing site in Jezero Crater.
Digging into the details — Webb’s NIRSpec instrument also measured the spectrum of infrared light coming from the planet — in other words, NIRSpec sorted Mars’ light into individual wavelengths, which correspond to specific chemicals on the surface and in the atmosphere of Mars. That spectrum of light will help Heidi Hammel (of the Association of Universities for Research in Astronomy, or AURA) and her colleagues search for chemicals that may exist in only small amounts in Mars’ atmosphere, like methane and hydrogen chloride.

The “dips” in this graph show the wavelengths where molecules in Mars’ atmosphere absorb light; these wavelengths reveal the presence of water, carbon dioxide, and carbon monoxide.NASA
Because it’s so close to Earth, it’s tempting to think of Mars as an easier target for astronomers than a distant galaxy from the earliest years of the universe. But for Webb, Mars is so close and so bright that it’s actually hard to look at. All of Webb’s instruments were designed to pick up faint traces of light from the most distant objects in the universe, so the sunlight reflected from a nearby planet can actually overwhelm the telescope’s sensors — a problem astronomers call “detector saturation.”
Detector saturation also shows up in some of Webb’s earlier images, when the centers of bright, nearby stars appear dark and empty. To avoid that same effect in Webb’s first pictures of Mars, the team of astronomers led by Hammel, photographed Mars using very short exposures and developed special data-processing methods.

 

[ArlyA]

More from NASA!
----------------------------------------------------------

New Webb Image Captures Clearest View of Neptune’s Rings in Decades​

En español
NASA’s James Webb Space Telescope shows off its capabilities closer to home with its first image of Neptune. Not only has Webb captured the clearest view of this distant planet’s rings in more than 30 years, but its cameras reveal the ice giant in a whole new light.

Most striking in Webb’s new image is the crisp view of the planet’s rings – some of which have not been detected since NASA’s Voyager 2 became the first spacecraft to observe Neptune during its flyby in 1989. In addition to several bright, narrow rings, the Webb image clearly shows Neptune’s fainter dust bands.

“It has been three decades since we last saw these faint, dusty rings, and this is the first time we’ve seen them in the infrared,” notes Heidi Hammel, a Neptune system expert and interdisciplinary scientist for Webb. Webb’s extremely stable and precise image quality permits these very faint rings to be detected so close to Neptune.

Show only LeftShow only Right
What do we see in Webb's latest image of the ice giant Neptune? Webb captured seven of Neptune’s 14 known moons: Galatea, Naiad, Thalassa, Despina, Proteus, Larissa, and Triton. Neptune’s large and unusual moon, Triton, dominates this Webb portrait of Neptune as a very bright point of light sporting the signature diffraction spikes seen in many of Webb’s images.
Credits: NASA, ESA, CSA, STScI
Neptune has fascinated researchers since its discovery in 1846. Located 30 times farther from the Sun than Earth, Neptune orbits in the remote, dark region of the outer solar system. At that extreme distance, the Sun is so small and faint that high noon on Neptune is similar to a dim twilight on Earth.

This planet is characterized as an ice giant due to the chemical make-up of its interior. Compared to the gas giants, Jupiter and Saturn, Neptune is much richer in elements heavier than hydrogen and helium. This is readily apparent in Neptune’s signature blue appearance in Hubble Space Telescope images at visible wavelengths, caused by small amounts of gaseous methane.


Webb’s Near-Infrared Camera (NIRCam) images objects in the near-infrared range from 0.6 to 5 microns, so Neptune does not appear blue to Webb. In fact, the methane gas so strongly absorbs red and infrared light that the planet is quite dark at these near-infrared wavelengths, except where high-altitude clouds are present. Such methane-ice clouds are prominent as bright streaks and spots, which reflect sunlight before it is absorbed by methane gas.
Credits: NASA, ESA, CSA, STScI

Webb’s Near-Infrared Camera (NIRCam) images objects in the near-infrared range from 0.6 to 5 microns, so Neptune does not appear blue to Webb. In fact, the methane gas so strongly absorbs red and infrared light that the planet is quite dark at these near-infrared wavelengths, except where high-altitude clouds are present. Such methane-ice clouds are prominent as bright streaks and spots, which reflect sunlight before it is absorbed by methane gas. Images from other observatories, including the Hubble Space Telescope and the W.M. Keck Observatory, have recorded these rapidly evolving cloud features over the years.

More subtly, a thin line of brightness circling the planet’s equator could be a visual signature of global atmospheric circulation that powers Neptune’s winds and storms. The atmosphere descends and warms at the equator, and thus glows at infrared wavelengths more than the surrounding, cooler gases.

Neptune’s 164-year orbit means its northern pole, at the top of this image, is just out of view for astronomers, but the Webb images hint at an intriguing brightness in that area. A previously-known vortex at the southern pole is evident in Webb’s view, but for the first time Webb has revealed a continuous band of high-latitude clouds surrounding it.

Webb also captured seven of Neptune’s 14 known moons. Dominating this Webb portrait of Neptune is a very bright point of light sporting the signature diffraction spikes seen in many of Webb’s images, but this is not a star. Rather, this is Neptune’s large and unusual moon, Triton.

Covered in a frozen sheen of condensed nitrogen, Triton reflects an average of 70 percent of the sunlight that hits it. It far outshines Neptune in this image because the planet’s atmosphere is darkened by methane absorption at these near-infrared wavelengths. Triton orbits Neptune in an unusual backward (retrograde) orbit, leading astronomers to speculate that this moon was originally a Kuiper belt object that was gravitationally captured by Neptune. Additional Webb studies of both Triton and Neptune are planned in the coming year.

The James Webb Space Telescope is the world's premier space science observatory. Webb will solve mysteries in our solar system, look beyond to distant worlds around other stars, and probe the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and the Canadian Space Agency.

Laura Betz
NASA's Goddard Space Flight Center, Greenbelt, Md.

Hannah Braun

 

[ArlyA]

Lets not discount Hubble..
-----------------------------------------------
Sep 23, 2022

Hubble Unveils an Astronomical Explosion​

A shroud of thick gas and dust surrounds a bright young star in this image from the NASA/ESA Hubble Space Telescope. Hubble’s Wide Field Camera 3 inspected a young stellar object, over 9,000 light-years away in the constellation Taurus, to help astronomers understand the earliest stages in the lives of massive stars. This object – which is known to astronomers as IRAS 05506+2414 – may be an example of an explosive event caused by the disruption of a massive young star system.
The swirling discs of material surrounding a young star are usually funneled into twin outflows of gas and dust from the star. In the case of IRAS 05506+2414, however, a fan-like spray of material traveling at velocities of up to 217 miles per second (350 km per second) is spreading outwards from the center of this image.
Astronomers turned to Hubble’s Wide Field Camera 3 to measure the distance to IRAS 05506+2414. While it is possible to measure the velocity of material speeding outward from the star, astronomers cannot tell how far from Earth the star actually is from a single observation. To determine the star’s distance, they measured how far the outflow travels between successive images. From there they could infer the distance to IRAS 05506+2414. Knowing its distance allows astronomers to determine how bright the star is and how much energy it is emitting, and therefore estimate its mass – all vital information in determining the origin of this bright young star’s unusual outflow.
Text credit: European Space Agency
Image credit: ESA/Hubble & NASA, R. Sahai

 

[tradosaurus]

Since this telescope can see objects at these fantastic distances I would like for the JWT to point to the bottom of the earth so I can see ships and planes upside down.
Even an artist rendering like the images shown in these posts would work.

 

[ruffdog]

I would like for the JWT to point to the bottom of the earth so I can see ships and planes upside down.

Bottom of the Earth? Maybe ask some of the TBN members that live in the southern hemisphere (down under?) to take some pictures for you. Maybe all them penguins use anti-gravity suits?

 

[tradosaurus]

Bottom of the Earth? Maybe ask some of the TBN members that live in the southern hemisphere (down under?) to take some pictures for you. Maybe all them penguins use anti-gravity suits?

View attachment 764044

Simple really. If the earth is a globe half of the "planet" is upside down so all I want is a picture of activity upside down.

 

[MossRoad]

If I had a time machine, I'd go back and give someone's parents a pamphlet on birth control.