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ESO110629 宇宙中最明亮的类星体

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叶程婉 发表于 2011-7-2 20:36 | 显示全部楼层 |阅读模式 来自: 中国–广东–佛山–顺德区 电信

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本帖最后由 叶程婉 于 2011-7-2 20:39 编辑

http://www.eso.org/public/news/eso1122/
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欧洲天文学家小组利用欧洲南方天文台甚大望远镜和辅助望远镜阵列观测并研究宇宙中距离地球最遥远的类星体。类星体作为宇宙极为神秘的天体,其辐射功率常常具有惊人的数量级。而天文学家观测到的这个类星体编号为ULAS J1120+0641,其辐射功率由一个质量巨大的黑洞推动,达到20亿倍太阳质量。这是迄今为止在早期宇宙中发现的最远且最亮的天体。这项研究成果已经发表在6月30日的《自然》期刊上。
科学家发现这个在早期宇宙中亮等最高的天体,这个发现不仅挑战了传统理论上对超大质量黑洞发展以及演化的认识,同时也预示着这类活动星系核在早期宇宙中所扮演的极为重要的角色这颗距离地球最遥远的类星体辐射功率是我们太阳的60万亿倍,达到10兆的数量级,而一般的星系,整个星系的辐射功率都还不够这个量,这也是类星体之所以神秘之处。
而发现这颗类星体的过程确是相当艰苦的,欧洲的天文学家之前使用英国皇家红外波段天文望远镜深空巡天,一共观测了2000万个天体,前后一共花费了5年的时间。根据英国伦敦帝国学院天体物理学家兼该项目的研究员Daniel Mortlock介绍:天文观测工作是非常漫长而缓慢的,宇宙深空中有数不尽的天体而且许多天体已经有记录在案,而在其中找一颗具有极为特殊且意义非凡的天体比从沙子淘金还要难,同时也考验相关研究人员的耐心还有运气。
ULAS J1120+0641类星体不仅由皇家红外望远镜巡天进行观测,要得到欧洲南方天文台甚大望远镜阵列与双子座北站天文台的帮助。这种观测首先必须确认的问题是:发现的这颗类星体中辐射出来的光等射线是如何被宇宙膨胀的效应所影响,也就是观测到极为不寻常的红移值。从这个角度反推,科学家估计这颗类星体在极早期的宇宙中就存在了,时间范围可以确定在大爆炸之后的7.7亿年。
进一步分析地球上接收到的来自ULAS J1120+0641类星体的光,研究人员算出其辐射功率必须具有20亿倍的太阳质量,这个数量级的辐射功率背后极有可能是一个超大质量黑洞。但是还不能肯定是由一个质量特大的黑洞所发射出来,只能说在人类现有的天体理论范围之内,可以将其认为是一个黑洞的作用。因为这里还有一个问题:这个只在大爆炸7.7亿年左右出现的类星体,而背后又有着如此巨大数量级的黑洞,那这个特大质量的黑洞是如何在这个早期宇宙中出现的?早期宇宙环境是如何提供这个级别的黑洞进行演化的?这一切都还是谜团中的谜团。
针对这个异常现象,科学家提出一些理论来对其进行解释,例如:在极早期宇宙中存在许多黑洞的“种子”,这些种子的产生是由宇宙诞生过程中的某种机制进行控制,而这些黑洞“种子”质量超过1000倍太阳质量,且具有极高的吞并率,可以在较短的时间尺度上进行合并膨胀,质量也随着这种进程出现指数级的增长,合并的同时也有大量早期宇宙物质溅落到吸积盘中,在这两个因素的共同作用下,早期宇宙中就有可能出现特大质量的黑洞,这种成长的规律确实有些异常。
虽然这个发现的类星体增加了一个关于在早期宇宙中出现特大质量之谜,但是却帮助科学家揭示了另一个关于137亿年前宇宙大爆炸的谜团:宇宙诞生过程中的再电离阶段(reionization)。大约在大爆炸之后的1.5亿年至8亿年间,宇宙中充满着等离子态的中性氢,宇宙不断膨胀的过程中,质子和电子结合成氢原子,整个宇宙呈中性态。然而目前的宇宙空间是高度电离的,也就是说,宇宙在那个时期必须经历一个由中性态到电离态的一个过程,而这个过程的开始则有宇宙中诞生的第一颗恒星发出的第一束光照亮宇宙的那一刻开始。
根据来自这颗新发现的类星体的光谱发现:在大爆炸之后的7.7亿年,宇宙中还存在着大量的中性氢,这就是说整个宇宙的再电离过程至少在大爆炸之后的7.7亿年还没结束。下一步我们将得到可见光与红外巡天望远镜(VISTA)和超广域全景巡天望远镜系统的支持,继续寻找类星体的踪迹,并且将任务定位在距大爆炸时间点更近更古老的类星体
 楼主| 叶程婉 发表于 2011-7-2 20:37 | 显示全部楼层 来自: 中国–广东–佛山–顺德区 电信
本帖最后由 叶程婉 于 2011-7-2 20:40 编辑

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    A team of European astronomers has used ESO’s Very Large Telescope and a host of other telescopes to discover and study the most distant quasar found to date. This brilliant beacon, powered by a black hole with a mass two billion times that of the Sun, is by far the brightest object yet discovered in the early Universe. The results will appear in the 30 June 2011 issue of the journal Nature.
“This quasar is a vital probe of the early Universe. It is a very rare object that will help us to understand how supermassive black holes grew a few hundred million years after the Big Bang,” says Stephen Warren, the study’s team leader.
Quasars are very bright, distant galaxies that are believed to be powered by supermassive black holes at their centres. Their brilliance makes them powerful beacons that may help to probe the era when the first stars and galaxies were forming. The newly discovered quasar is so far away that its light probes the last part of the reionisation era [1].
The quasar that has just been found, named ULAS J1120+0641 [2], is seen as it was only 770 million years after the Big Bang (redshift 7.1, [3]). It took 12.9 billion years for its light to reach us.
Although more distant objects have been confirmed (such as a gamma-ray burst at redshift 8.2, eso0917, and a galaxy at redshift 8.6, eso1041), the newly discovered quasar is hundreds of times brighter than these. Amongst objects bright enough to be studied in detail, this is the most distant by a large margin.
The next most-distant quasar is seen as it was 870 million years after the Big Bang (redshift 6.4). Similar objects further away cannot be found in visible-light surveys because their light, stretched by the expansion of the Universe, falls mostly in the infrared part of the spectrum by the time it gets to Earth. The European UKIRT Infrared Deep Sky Survey (UKIDSS) which uses the UK's dedicated infrared telescope [4] in Hawaii was designed to solve this problem. The team of astronomers hunted through millions of objects in the UKIDSS database to find those that could be the long-sought distant quasars, and eventually struck gold.
“It took us five years to find this object,” explains Bram Venemans, one of the authors of the study. “We were looking for a quasar with redshift higher than 6.5. Finding one that is this far away, at a redshift higher than 7, was an exciting surprise. By peering deep into the reionisation era, this quasar provides a unique opportunity to explore a 100-million-year window in the history of the cosmos that was previously out of reach.”
The distance to the quasar was determined from observations made with the FORS2 instrument on ESO’s Very Large Telescope (VLT) and instruments on the Gemini North Telescope [5]. Because the object is comparatively bright it is possible to take a spectrum of it (which involves splitting the light from the object into its component colours). This technique allowed the astronomers to find out quite a lot about the quasar.
These observations showed that the mass of the black hole at the centre of ULAS J1120+0641 is about two billion times that of the Sun. This very high mass is hard to explain so early on after the Big Bang. Current theories for the growth of supermassive black holes predict a slow build-up in mass as the compact object pulls in matter from its surroundings.
“We think there are only about 100 bright quasars with redshift higher than 7 over the whole sky,” concludes Daniel Mortlock, the leading author of the paper. “Finding this object required a painstaking search, but it was worth the effort to be able to unravel some of the mysteries of the early Universe.”
Notes
[1] About 300 000 years after the Big Bang, which occurred 13.7 billion years ago, the Universe had cooled down enough to allow electrons and protons to combine into neutral hydrogen (a gas without electric charge). This cool dark gas permeated the Universe until the first stars started forming about 100 to 150 million years later. Their intense ultraviolet radiation slowly split the hydrogen atoms back into protons and electrons, a process called reionisation, making the Universe more transparent to ultraviolet light.  It is believe that this era occurred between about 150 million to 800 million years after the Big Bang.
[2] The object was found using data from the UKIDSS Large Area Survey, or ULAS. The numbers and prefix ‘J’ refer to the quasar’s position in the sky.
[3] Because light travels at a finite speed, astronomers look back in time as they look further away into the Universe. It took 12.9 billion years for the light from ULAS J1120+0641 to travel to telescopes on Earth so the quasar is seen as it was when the Universe was only 770 million years old. In those 12.9 billion years, the Universe expanded and the light from the object stretched as a result. The cosmological redshift, or simply redshift, is a measure of the total stretching the Universe underwent between the moment when the light was emitted and the time when it was received.
[4] UKIRT is the United Kingdom Infrared Telescope. It is owned by the UK’s Science and Technology Facilities Council and operated by the staff of the Joint Astronomy Centre in Hilo, Hawaii.
[5] FORS2 is the VLT’s FOcal Reducer and low dispersion Spectrograph. Other instruments used to split up the light of the object were the Gemini Multi-Object Spectrograph (GMOS) and the Gemini Near-Infrared Spectrograph (GNIRS). The Liverpool Telescope, the Isaac Newton Telescope and the UK Infrared Telescope (UKIRT) were also used to confirm survey measurements.
More information
This research was presented in a paper to appear in the journal Nature on 30 June 2011.
The team is composed of Daniel J. Mortlock (Imperial College London [Imperial], UK), Stephen J. Warren (Imperial), Bram P. Venemans (ESO, Garching, Germany), Mitesh Patel (Imperial), Paul C. Hewett (Institute of Astronomy [IoA], Cambridge, UK), Richard G. McMahon (IoA), Chris Simpson (Liverpool John Moores University, UK), Tom Theuns (Institute for Computational Cosmology, Durham, UK and University of Antwerp, Belgium), Eduardo A. Gonzáles-Solares (IoA), Andy Adamson (Joint Astronomy Centre, Hilo, USA), Simon Dye (Centre for Astronomy and Particle Theory, Nottingham, UK), Nigel C. Hambly (Institute for Astronomy, Edinburgh, UK), Paul Hirst (Gemini Observatory, Hilo, USA), Mike J. Irwin (IoA), Ernst Kuiper (Leiden Observatory, The Netherlands), Andy Lawrence (Institute for Astronomy, Edinburgh, UK), Huub J. A. Röttgering (Leiden Observatory, The Netherlands).
ESO, the European Southern Observatory, is the foremost intergovernmental astronomy organisation in Europe and the world’s most productive astronomical observatory. It is supported by 15 countries: Austria, Belgium, Brazil, the Czech Republic, Denmark, France, Finland, Germany, Italy, the Netherlands, Portugal, Spain, Sweden, Switzerland and the United Kingdom. ESO carries out an ambitious programme focused on the design, construction and operation of powerful ground-based observing facilities enabling astronomers to make important scientific discoveries. ESO also plays a leading role in promoting and organising cooperation in astronomical research. ESO operates three unique world-class observing sites in Chile: La Silla, Paranal and Chajnantor. At Paranal, ESO operates the Very Large Telescope, the world’s most advanced visible-light astronomical observatory and two survey telescopes. VISTA works in the infrared and is the world’s largest survey telescope and the VLT Survey Telescope is the largest telescope designed to exclusively survey the skies in visible light. ESO is the European partner of a revolutionary astronomical telescope ALMA, the largest astronomical project in existence. ESO is currently planning a 40-metre-class European Extremely Large optical/near-infrared Telescope, the E-ELT, which will become “the world’s biggest eye on the sky”.
Links
Research paper: Nature paper
Photos of the VLT
Contacts
Daniel Mortlock
Astrophysics Group, Blackett Laboratory, Imperial College London
London, United Kingdom
Tel: +44 20 7594 7878
Email: d.mortlock@imperial.ac.uk
Bram Venemans
ESO Astronomer
Garching bei München, Germany
Tel: +49 89 3200 6631
Email: bveneman@eso.org
Richard Hook
ESO, La Silla, Paranal, E-ELT and Survey Telescopes Public Information Officer
Garching bei München, Germany
Tel: +49 89 3200 6655
Email: rhook@eso.org
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woshiwangqh 发表于 2011-7-2 20:54 | 显示全部楼层 来自: 中国–江苏–无锡 移动
是不是中间的那个红点?
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寒水若倒流 发表于 2011-7-2 20:56 | 显示全部楼层 来自: 中国–福建–泉州 电信
开图慢了点~~~   等他们继续找到更亮的
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m87星云 发表于 2011-7-2 21:06 | 显示全部楼层 来自: 中国–广东–韶关 电信
中心位置是黑洞来的,类星体可能是黑洞引力场对其他天体或尘埃的巨大吸引力造成的,因为在哪里可以看到大量的新星在形成,同时存在着极为巨大的红移现象支持
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ZCJHAI 发表于 2011-8-2 18:20 | 显示全部楼层 来自: LAN
据说类星体的喷流是黑洞吞噬其附近气体时候打的嗝,有没有人能具体解释下呢?
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SDRC43 发表于 2011-8-2 22:44 | 显示全部楼层 来自: 中国–安徽–淮南 电信
提示: 作者被禁止或删除 内容自动屏蔽
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a303252369 发表于 2011-8-10 20:16 | 显示全部楼层 来自: 中国–安徽–池州 电信
看不明白啊 谁解释下?????????
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