Glossary term: 갈색왜성
Description: 갈색 왜성은 별이 되기에는 질량이 너무 작고, 행성이 되기에는 질량이 너무 큰 천체입니다. 보통 별은 중심(핵)에서 수소 융합으로 에너지를 얻습니다. 하지만 갈색 왜성은 내부 온도가 낮아서 수소 융합을 유지할 수 없습니다. 다만 갈색 왜성은 태어난 초기에는 중수소(더 무거운 형태의 수소)를 잠시 융합할 수 있습니다. 이 중수소 융합은 갈색 왜성과 행성을 구별하는 기준이 되기도 하지만, 실제로 관측하기는 어렵습니다. 갈색 왜성의 질량은 보통 태양 질량의 1.2%~8%(목성 질량의 약 12~80배) 정도이며, 크기는 목성과 거의 비슷합니다. 젊은 갈색 왜성은 표면 온도가 낮은 별인 적색 왜성과 비슷하지만, 내부에 에너지를 낼 열원이 부족하기 때문에 시간이 지나면서 식습니다. 오래된 갈색 왜성은 어떤 경우 섭씨 수백 도까지 온도가 내려가기도 합니다.
Related Terms:
See this term in other languages
Term and definition status: The original definition of this term in English have been approved by a research astronomer and a teacher The translation of this term and its definition is still awaiting approval
The OAE Multilingual Glossary is a project of the IAU Office of Astronomy for Education (OAE) in collaboration with the IAU Office of Astronomy Outreach (OAO). The terms and definitions were chosen, written and reviewed by a collective effort from the OAE, the OAE Centers and Nodes, the OAE National Astronomy Education Coordinators (NAECs) and other volunteers. You can find a full list of credits here. All glossary terms and their definitions are released under a Creative Commons CC BY-4.0 license and should be credited to "IAU OAE".
If you notice a factual or translation error in this glossary term or definition then please get in touch.
In Other Languages
- 아랍어: القزم البني
- 독일어: Brauner Zwerg
- 영어: Brown Dwarf
- 스페인어: Enana marrón
- 프랑스어: Naine brune
- 이탈리아어: Nana bruna
- 일본어: 褐色矮星 (external link)
- 브라질 포르투갈어: Anã marrom
- 중국어 간체: 褐矮星
- 중국어 번체: 褐矮星
Related Media
A binary brown dwarf system revealed
Caption: This image presents a nearby system of brown dwarfs, objects that fall between planets and stars in mass and do not sustain long-term nuclear fusion in their cores. Located about 6.5 light-years from Earth, this system (known as Luhman 16) is the third closest system to the Solar System after the Alpha Centauri system and Barnard's Star. It was initially observed as what seemed to be a single faint source of infrared light. Brown dwarfs are often difficult to study because of their low brightness, especially in visible light. However they shine brighter in infrared light due to their cooler effective temperatures.
The comparison highlights the importance of observational resolution. The image at the center, taken by NASA’s Wide-field Infrared Survey Explorer (WISE), shows the system as a single blurred object due to its lower resolution (WISE has a resolution of roughly 6 arcseconds). A highlighted zoomed-in view from the Gemini South Observatory in Chile reveals that this “single” source is actually a binary system of two brown dwarfs. The improved angular resolution (roughly 0.6 arcseconds) allows astronomers to separate the two objects clearly, demonstrating how higher-resolution observations uncover hidden structures in the universe. While the Gemini telescope is situated on the Earth and thus is affected by the blurring effects of the Earth's atmosphere, it has a substantially larger mirror than the WISE telescope (8m wide vs. 40cm wide) meaning it can achieve much higher resolutions.
Credit: NASA/JPL/Gemini Observatory/AURA/NSF
credit link
License: PD Public Domain icons
Related Diagrams
Hertzsprung-Russell diagram
Caption: This diagram shows the temperature and luminosity of different stars. The size of each point represents the star’s radius and its colour is the colour the human eye would see. The stars range in colour from a washed-out blue to a washed-out reddish-orange. No star has a pure colour like red, green or blue as stars’ spectra include light from lots of different colours. However the reddest stars are commonly referred to as red and the bluest stars as blue. The sample of stars used to make this diagram was chosen to show a wide range of stars of different types so the relative number of each type of star is not representative of how commonly each type is found.
From the top left to bottom right there is a long line of stars burning hydrogen in their cores. This is called the main sequence. On this line, one sees the stars Mintaka, Achenar, Sirius A, the Sun and Proxima Centauri. The objects around Proxima Centauri at the lower right end of the main sequence are known as red dwarfs. To the lower right of the red dwarfs are Teide 1 and Kelu-1 A. These two objects are brown dwarfs, objects too low in mass to have cores hot enough to fuse hydrogen for a sustained period of time. As they do not burn hydrogen, brown dwarfs are not considered main sequence stars. The name brown dwarf is unrelated to their colour.
Above the main sequence, we find subgiants, giants and supergiants. These are stars that have finished burning hydrogen in their core and have evolved into larger objects. A star’s brightness depends on its temperature and size so giant stars are brighter than stars with a smaller radius but the same temperature. In time these objects will move towards the end of their lives and undergo either a planetary nebula phase or become supernovae. Stars which end their lives with a planetary nebula phase become a type of stellar remnant called a white dwarf. Such objects are much smaller than stars of the same temperature and thus are fainter and are found significantly below the main sequence. Stars which end their lives as supernovae become either black holes or neutron stars. These are not shown on this plot.
Credit: IAU OAE/Niall Deacon
License: CC-BY-4.0 Creative Commons 저작자표시 4.0 국제 (CC BY 4.0) icons
Related Activities
The Brown Dwarf builder's guide
astroEDU educational activity (links to astroEDU website) Description: Make your own model of a failed star!
License: CC-BY-4.0 Creative Commons 저작자표시 4.0 국제 (CC BY 4.0) icons
Age Ranges:
14-16
Education Level:
Secondary
Areas of Learning:
Fine Art focussed
, Observation based
, Project-based learning
Costs:
Low Cost
Duration:
3 hours
Skills:
Analysing and interpreting data
, Communicating information
, Developing and using models
