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IC 443

How to hold a Jellyfish (nebula):
3D Printing IC 443


The Jellyfish Nebula, also known by its official name IC 443, is the remnant of a supernova lying 5,000 light years from Earth. Chandra X-ray observations show that the explosion that created the Jellyfish Nebula may have also formed a peculiar object located on the southern edge of the remnant, called CXOU J061705.3+222127, or J0617 for short. The object is likely a rapidly spinning neutron star, or pulsar.

When a massive star runs out of thermonuclear fuel, it implodes, forming a dense stellar core called a neutron star. The outer layers of the star collapse toward the neutron star then bounce outward in a supernova explosion. A spinning neutron star that produces a beam of radiation is called a pulsar. The radiation sweeps by like a beacon of light from a lighthouse and can be detected as pulses of radio waves and other types of radiation.

IC 443

A composite image includes a wide-field view from an astrophotographer that shows the spectacular filamentary structure of IC 443. Within the inset box, another optical image from the Digitized Sky Survey (red, green, orange, and cyan) has been combined with X-ray data from Chandra (blue). The inset shows a close-up view of the region around J0617.

Credit: Wide Field Optical: Focal Pointe Observatory/B.Franke, Inset: X-ray: NASA/CXC/MSFC/D.Swartz et al, Inset: Optical: DSS, SARA

IC 443 Close Up

The Chandra image reveals a small, circular structure (or ring) surrounding the pulsar and a jet-like feature pointing roughly in an up-down direction that passes through the pulsar. It is unclear if the long, pink wisp of optical emission is related to the pulsar, as similar wisps found in IC 443 are unrelated to X-ray features from the pulsar. The ring may show a region where a high speed wind of particles flowing away from the pulsar is slowing down abruptly. Alternatively, the ring may represent a shock wave, similar to a sonic boom, ahead of the pulsar wind. The jet could be particles that are being fired away from the pulsar in a narrow beam at high speed.

The X-ray brightness of J0617 and its X-ray spectrum, or the amount of X-rays at different wavelengths, are consistent with the profiles from known pulsars. The spectrum and shape of the diffuse, or spread out, X-ray emission surrounding J0617 and extending well beyond the ring also match with expectations for a wind flowing from a pulsar.

The comet-like shape of the diffuse X-ray emission suggests motion towards the lower right of the image. As pointed out in previous studies, this orientation is about 50 degrees away from the direction expected if the pulsar was moving away from the center of the supernova remnant in a straight line. This misalignment has cast some doubt on the association of the pulsar with the supernova remnant. However, this misalignment could also be explained by movement towards the left of material in the supernova remnant pushing J0617's cometary tail aside.

This research points to an estimate for the age of the supernova remnant to be tens of thousands of years. This agrees with previous work that pegged IC 443's age to be about 30,000 years. However, other scientists have inferred much younger ages of about 3,000 years for this supernova remnant, so its true age remains in question.

IC 443/Jellyfish Nebula In 3D




This 3D model shows this stunning supernova remnant IC 443 in a new way. In the model, the shock wave (similar to a sonic boom produced by a jet) and the remains of the star have collided with a nearby gas cloud, and are interacting with it as they pass through it.

A comparison of the 3D model with X-ray data from ESA’s XMM-Newton shows that the collision of the shock wave and debris with the gas cloud is the main factor responsible for the unusually complex appearance of the X-ray emission from IC 443.

The 3D model also gives important information about the supernova explosion that formed IC 443. It shows that the explosion was weaker than most supernovas and that it occurred about 8,000 years ago, in Earth's time frame. In addition, this work provides new evidence that a source of X-rays discovered with Chandra (cyan in the inset image) contains the neutron star that formed when a massive star collapsed and exploded to create IC 443.


3D Printing: Print Your Own Jellyfish (IC 443)

IC 443 3D

Photo: NASA/CXC/SAO/K.Arcand

These 3D printable files were created by the Chandra team from the scientific 3D model, showing the ejecta in cross-section (printed here in blue (left), and also in white (right) with an option to color the point of the cutout for the pulsar wind nebula with a marker or nailpolish).

Select the 3D printer of your choice to make your own IC 443/Jellyfish nebula. Download the files below. For our 3D-printed example shown here, one color of PLA filament was used for each example model. If support structures are required, they can be removed after printing by using a dissolvable substrate with minimal hand-cleaning, or filed/sanded off.

STL Files:

Click for STL file
Blastwave
STL

Click for STL file
Ejecta
STL

Click for STL file
With PWN Plus Torus
STL

Click for STL file
Plus Torus
STL

Click for STL file
Torus Blast
STL

Click for STL file
With PWN
STL

Click for STL file
Molecular Cloud Torus
STL


Credit: Model: INAF-Osservatorio Astronomico di Palermo/S. Ustamujic et al; 3D print: NASA/CXC/SAO/A. Jubett




 

RESOURCES

DOWNLOADABLES

3D Print Your Own IC 443 Handout


LINKS TO OTHER ACTIVITIES

Coding & Astronomy
Recoloring the Universe with Pencil Code

3D Printing
Universe in 3D

SpaceMath

Astronomy
Make the Most of Your Universe
Learn more at chandra.si.edu/corps/



Published: August 2020

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Developed by the Chandra X-ray Center, at the Smithsonian Astrophysical Observatory, in Cambridge, MA, with funding by NASA under contract NAS8-03060   |   Privacy  |  Accessibility
Additional support from NASA's Universe of Learning (UoL). UoL materials are based upon work supported by NASA under award number NNX16AC65A to the Space
Telescope Science Institute, working in partnership with Caltech/IPAC, Jet Propulsion Laboratory, Smithsonian Astrophysical Observatory, and Sonoma State University.