Jul 19, 2024
artfight attack on @booleanbug's fan wizardmon, geminga! i don't have time for any more first hits probably, but i couldn't leave this guy alone cuz he didn't have ANY attacks yet and that was an injustice >:V
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artfight attack on @booleanbug's fan wizardmon, geminga! i don't have time for any more first hits probably, but i couldn't leave this guy alone cuz he didn't have ANY attacks yet and that was an injustice >:V
(NASA) Chandra Images Show That Geometry Solves a Pulsar Puzzle
Image credit: Geminga image: NASA/CXC/PSU/B. Posselt et al; Infrared: NASA/JPL-Caltech; B0355+54: X-ray: NASA/CXC/GWU/N. Klingler et al; Infrared: NASA/JPL-Caltech; Illustrations: Nahks TrEhnl
NASA'S Chandra X-ray Observatory has taken deep exposures of two nearby energetic pulsars flying through the Milky Way galaxy. The shape of their X-ray emission suggests there is a geometrical explanation for puzzling differences in behavior shown by some pulsars.
Pulsars − rapidly rotating, highly magnetized, neutron stars born in supernova explosions triggered by the collapse of massive stars − were discovered 50 years ago via their pulsed, highly regular, radio emission. Pulsars produce a lighthouse-like beam of radiation that astronomers detect as pulses as the pulsar's rotation sweeps the beam across the sky.
Since their discovery, thousands of pulsars have been discovered, many of which produce beams of radio waves and gamma rays. Some pulsars show only radio pulses and others show only gamma-ray pulses. Chandra observations have revealed steadier X-ray emission from extensive clouds of high-energy particles, called pulsar wind nebulas, associated with both types of pulsars. New Chandra data on pulsar wind nebulas may explain the presence or absence of radio and gamma-ray pulses.
This four-panel graphic shows the two pulsars observed by Chandra. Geminga is in the upper left and B0355+54 is in the upper right. In both of these images, Chandra’s X-rays, colored blue and purple, are combined with infrared data from NASA’s Spitzer Space Telescope that shows stars in the field of view. Below each data image, an artist’s illustration depicts more details of what astronomers think the structure of each pulsar wind nebula looks like.
Full article here
(NASA) Chandra Images Show That Geometry Solves a Pulsar Puzzle
NASA'S Chandra X-ray Observatory has taken deep exposures of two nearby energetic pulsars flying through the Milky Way galaxy. The shape of their X-ray emission suggests there is a geometrical explanation for puzzling differences in behavior shown by some pulsars.
Pulsars − rapidly rotating, highly magnetized, neutron stars born in supernova explosions triggered by the collapse of massive stars − were discovered 50 years ago via their pulsed, highly regular, radio emission. Pulsars produce a lighthouse-like beam of radiation that astronomers detect as pulses as the pulsar's rotation sweeps the beam across the sky.
(...) This four-panel graphic shows the two pulsars observed by Chandra. Geminga is in the upper left and B0355+54 is in the upper right. In both of these images, Chandra’s X-rays, colored blue and purple, are combined with infrared data from NASA’s Spitzer Space Telescope that shows stars in the field of view. Below ach data image, an artist’s illustration depicts more details of what astronomers think the structure of each pulsar wind nebula looks like.
Read full article here
La pulsar Geminga risolve un mistero nel nostro giardino cosmico?
La pulsar Geminga risolve un mistero nel nostro giardino cosmico?
Rappresentazione artistica delle tre code di Geminga .
Una nuova ricerca degli scienziati della NASA suggerisce che Geminga, una delle più brillanti pulsar situate a circa 800 anni luce di distanza nella costellazione Gemelli, scoperta nel 1972 dalla NASA, potrebbe essere responsabile di un enigma decennale sul perché un tipo di particella cosmica sia stranamente abbondante vicino alla…
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Overschot positronen lijkt niet van pulsars afkomstig. Mmmmmm, dan toch van donkere materie?
De HAWC detector in Mexico. Credit: Jordan A Goodman
We blijven even in de sferen van donkere materie, na m’n eerdere blog vanochtendover het verband tussen donkere materie en het verdwijnen van de dinosurussen 65 miljoen jaar geleden. Al sinds de waarnemingen met de Italiaans-Russische PAMELA satelliet wordt er gespeculeerd over het waargenomen overschot aan positronen in de kosmische straling,…
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Geminga culla di pianeti
Geminga culla di pianeti
Un team di astronomi britannici ha studiato la formazione di esopianeti intorno a una stella di neutroni, resto di una supernova. Le immagini della pulsar Geminga mostrano come la stella di neutroni catturi nuovo materiale dalla nube interstellare, per la genesi di nuovi mondi. Dai resti di un’esplosione di supernova possono nascere nuovi pianeti. Lo afferma un team di scienziati britannici…
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Two articles published in "The Astrophysical Journal" describing research on as many pulsar that allow to better understand the geometry of the plasma in their vicinity. Two independent team used NASA's Chandra space telescope to study the pulsar Geminga, also known as PSR B0633+17, and PSR B0355+54 gathering information on the nebulas of high-energy particles called in jargon plerions generated by the pulsars.
Due articoli pubblicati sulla rivista "The Astrophysical Journal" descrivono ricerche su altrettante pulsar che permettono di capire meglio la geometria del plasma nelle loro vicinanze. Due team indipendenti hanno usato il telescopio spaziale Chandra della NASA per studiare le pulsar Geminga, conosciuta anche come PSR B0633+17, e PSR B0355+54 raccogliendo informazioni sulle nubi di particelle ad alta energia chiamate in gergo plerioni generate dalle pulsar.