Welcome to DU!
The truly grassroots left-of-center political community where regular people, not algorithms, drive the discussions and set the standards.
Join the community:
Create a free account
Support DU (and get rid of ads!):
Become a Star Member
Latest Breaking News
Editorials & Other Articles
General Discussion
The DU Lounge
All Forums
Issue Forums
Culture Forums
Alliance Forums
Region Forums
Support Forums
Help & Search
Science
Related: About this forumHow a special type of neutron star, a magnatar (might) form
https://www.scientificamerican.com/article/this-bizarre-star-could-become-one-of-the-strongest-magnets-in-the-universe/?/In the vastness of the known universe, few things are more wondrous than a magnetar. These stars are deceptively pint-sized; they squeeze multiple suns worth of mass into an orb no bigger than a city. And they boast mind-bogglingly powerful magnetic fields that are trillions of times stronger than the one that encompasses our planet. A magnetars magnetic field is so strong, in fact, that it can crack open the stars surface to release powerful bursts of energy that may be visible across billions of light-years. Despite these amazing properties, astronomers arent quite sure how magnetars form, with a myriad of possibilities on the table. We have too many ideas, and were not sure which ones are right, says Christopher White of the Flatiron Institute in New York City. Now researchers may have pinned down one possible pathway to a magnetar by finding an unusually massive and magnetic star that might be on the cusp of forming one of these enigmatic objects.
Tomer Shenar of the University of Amsterdam and his colleagues studied a pair of stars about 3,000 light-years from Earth that are collectively called HD 45166. One member of the pair had previously been identified as a Wolf-Rayet stara very rare, hot and massive star in the final stages of its life. Such stars have exhausted their hydrogen fuel and instead burn helium, which makes them shine brighter and raises intense stellar winds that can blow off their outer layers. Studying the star in more detail, Shenars team discovered this was a particularly unusual Wolf-Rayet star with a magnetic field of 43,000 gauss. (Earths field, for comparison, is a paltry half-gauss, and our suns is just a single gauss.) This makes the star, whose mass is twice that of our sun, the most magnetic massive star ever discovered. We have never detected magnetic fields in these types of stars, Shenar says. It turned out to have an extremely powerful magnetic field, and it is a prime candidate for becoming a magnetar. The research was published today in Science.
Using the Canada-France-Hawaii Telescope on Mauna Kea in Hawaiialong with data from Brazils National Laboratory for Astrophysics, La Silla Observatory in Chile and the Roque de los Muchachos Observatory in Spains Canary IslandsShenars team studied the star via a process called Zeeman-Doppler imaging, which can tease out details of a stellar magnetic field from subtle changes the magnetism imparts to the polarization of a stars light. The researchers then modeled the Wolf-Rayet stars history to better understand how its remarkable magnetic field might have formed and found that the star was likely the result of two helium-rich stars merging together. We think it was quite a complicated merger, Shenar saysone that possibly involved a helium-rich lower mass star spiraling into the puffy stellar atmosphere of an accompanying red supergiant. The rapid rotation of the two progenitors in the merging process would have spun up the postmerger stars magnetic field, amplifying it to a high degree, says Lidia Oskinova of the University of Potsdam in Germany, who is a co-author of the new paper. This is a new type of object, she says.
Magnetarsonly about 30 of which are known in our galaxyare a type of neutron star, a remnant core that is left behind after a massive star ends its life. Neutron stars are the closing phase of stellar evolution, the last stop that dying massive stars can reach if they arent sufficiently hefty to collapse further to form a black hole. Many are born via a supernovasuch neutron stars are created when a stars explosive death leaves behind a dense, compressed core that is barely 10 miles across. That extreme compressionand an associated boost to the cores rotation that leaves it spinning around several dozens of times per secondcan in principle supercharge any preexisting magnetic field to reach the levels measured for magnetars: some 100 trillion gauss.
InfoView thread info, including edit history
TrashPut this thread in your Trash Can (My DU » Trash Can)
BookmarkAdd this thread to your Bookmarks (My DU » Bookmarks)
4 replies, 1375 views
ShareGet links to this post and/or share on social media
AlertAlert this post for a rule violation
PowersThere are no powers you can use on this post
EditCannot edit other people's posts
ReplyReply to this post
EditCannot edit other people's posts
Rec (5)
ReplyReply to this post
4 replies
= new reply since forum marked as read
Highlight:
NoneDon't highlight anything
5 newestHighlight 5 most recent replies
How a special type of neutron star, a magnatar (might) form (Original Post)
Takket
Aug 2023
OP
Permanut
(6,638 posts)1. Hard to get our little human brains around the scale of these phenomena.
sir pball
(4,941 posts)2. The article puts in in perspective pretty well
If a magnetar was the same distance from Earth as the Moon, it would erase all magnetic data, e.g. credit cards and OG hard drives.
Takket
(22,518 posts)3. i remember years ago reading about magnatars...
that if you got too close they would literally pull the iron right out of your blood and kill you......
sir pball
(4,941 posts)4. Oh, they'll do even worse than that
We probably read the same Scientific American article ten or twelve years ago; get close enough and it'll literally rip the aroms in your body apart. Biology doesn't function too well when a hydrogen atom is shaped like a string instead of a sphere