麻豆淫院

For this new Picture of the Month feature, the NASA/ESA/CSA James Webb Space Telescope has provided a fantastic new view of IRAS 04302+2247, a planet-forming disk located about 525 light-years away in a dark cloud within the Taurus star-forming region. With Webb, researchers can study the properties and growth of dust grains within protoplanetary disks like this one, shedding light on the earliest stages of planet formation.

In stellar nurseries across the galaxy, baby stars are forming in giant clouds of cold gas. As young stars grow, the gas surrounding them collects in narrow, dusty protoplanetary disks. This sets the scene for the formation of planets, and observations of distant protoplanetary disks can help researchers understand what took place roughly 4.5 billion years ago in our own solar system, when the sun, Earth, and the other planets formed.

IRAS 04302+2247, or IRAS 04302 for short, is a beautiful example of a protostar鈥攁 young star that is still gathering mass from its environment鈥攕urrounded by a protoplanetary disk in which baby planets might be forming. Webb is able to measure the disk at 65 billion km across鈥攕everal times the diameter of our solar system.

From Webb's vantage point, IRAS 04302's disk is oriented edge-on, so we see it as a narrow, dark line of dusty gas that blocks the light from the budding protostar at its center. This dusty gas is fuel for planet formation, providing an environment within which young planets can bulk up and pack on mass.

When seen face-on, protoplanetary disks can have a variety of structures like rings, gaps and spirals. These structures can be signs of baby planets that are burrowing through the dusty disk, or they can point to phenomena unrelated to planets, like gravitational instabilities or regions where dust grains are trapped.

The edge-on view of IRAS 04302's disk shows instead the vertical structure, including how thick the dusty disk is. Dust grains migrate to the midplane of the disk, settle there and form a thin, dense layer that is conducive to planet formation; the thickness of the disk is a measure of how efficient this process has been.

The dense streak of dusty gas that runs vertically across this image cocoons IRAS 04302, blotting out its bright light such that Webb can more easily image the delicate structures around it. As a result, we're treated to the sight of two gauzy nebulas on either side of the disk. These are reflection nebulas, illuminated by light from the central protostar reflecting off of the nebular material. Given the appearance of the two reflection nebulas, IRAS 04302 has been nicknamed the "Butterfly Star."

This view of IRAS 04302 features observations from Webb's Near-InfraRed Camera (NIRCam) and its Mid-InfraRed Instrument (MIRI), combined with optical data from the NASA/ESA Hubble Space Telescope. Together, these powerful facilities paint a fascinating multiwavelength portrait of a planetary birthplace.

Webb reveals the distribution of tiny dust grains as well as the reflection of near-infrared light off of dusty material that extends a large distance from the disk, while Hubble focuses on the dust lane as well as clumps and streaks surrounding the dust that suggest the star is still collecting mass from its surroundings as well as shooting out jets and outflows.

The Webb observations of IRAS 04302 were taken as part of the Webb GO program #2562 (PI F. Me虂nard, K. Stapelfeldt). This program investigates four protoplanetary disks that are oriented edge-on from our point of view, aiming to understand how dust evolves within these disks. The growth of dust grains in protoplanetary disks is believed to be an important step toward planet formation.