1] Department of Astronomy, Laboratory for Millimeter-wave Astronomy and Joint Space Institute, University of Maryland, College Park, Maryland 20742, USA [2] Centre for Astrophysics and Supercomputing, Swinburne University, PO Box 218, Hawthorn, Victoria 3122, Australia.
Department of Astronomy, Laboratory for Millimeter-wave Astronomy and Joint Space Institute, University of Maryland, College Park, Maryland 20742, USA.
Nature. 2014 Jan 9;505(7482):186-9. doi: 10.1038/nature12765. Epub 2013 Dec 8.
Galaxies observed at redshift z > 6, when the Universe was less than a billion years old, thus far very rarely show evidence of the cold dust that accompanies star formation in the local Universe, where the dust-to-gas mass ratio is around one per cent. A prototypical example is the galaxy Himiko (z = 6.6), which--a mere 840 million years after the Big Bang--is forming stars at a rate of 30-100 solar masses per year, yielding a mass assembly time of about 150 × 10(6) years. Himiko is thought to have a low fraction (2-3 per cent of the Sun's) of elements heavier than helium (low metallicity), and although its gas mass cannot yet be determined its dust-to-stellar mass ratio is constrained to be less than 0.05 per cent. The local dwarf galaxy I Zwicky 18, which has a metallicity about 4 per cent that of the Sun's and is forming stars less rapidly (assembly time about 1.6 × 10(9) years) than Himiko but still vigorously for its mass, is also very dust deficient and is perhaps one of the best analogues of primitive galaxies accessible to detailed study. Here we report observations of dust emission from I Zw 18, from which we determine its dust mass to be 450-1,800 solar masses, yielding a dust-to-stellar mass ratio of about 10(-6) to 10(-5) and a dust-to-gas mass ratio of 3.2-13 × 10(-6). If I Zw 18 is a reasonable analogue of Himiko, then Himiko's dust mass must be around 50,000 solar masses, a factor of 100 below the current upper limit. These numbers are quite uncertain, but if most high-z galaxies are more like Himiko than like the very-high-dust-mass galaxy SDSS J114816.64 + 525150.3 at z ≈ 6, which hosts a quasar, then our prospects for detecting the gas and dust inside such galaxies are much poorer than hitherto anticipated.
在红移 z>6 处观测到的星系,当时宇宙的年龄还不到 10 亿年,到目前为止,这些星系很少有证据表明存在冷尘埃,而冷尘埃是在本地宇宙中恒星形成时伴随的,本地宇宙中尘埃与气体的质量比约为 1%。一个典型的例子是星系 Himiko(z=6.6),它在大爆炸后仅仅 8.4 亿年,就以每年 30-100 个太阳质量的速度形成恒星,质量组装时间约为 150×10^6 年。Himiko 的元素丰度(氦以外的元素)较低(太阳的 2-3%),被认为是低金属丰度星系,尽管它的气体质量目前还无法确定,但它的尘埃与恒星的质量比被限制在 0.05%以下。本地矮星系 I Zwicky 18 的金属丰度约为太阳的 4%,形成恒星的速度比 Himiko 慢(组装时间约为 1.6×10^9 年),但对于其质量来说仍然非常活跃,它的尘埃也非常匮乏,也许是最适合详细研究的原始星系之一。在这里,我们报告了对 I Zw 18 的尘埃发射的观测结果,从中我们确定了它的尘埃质量为 450-1800 个太阳质量,尘埃与恒星的质量比约为 10^-6 到 10^-5,尘埃与气体的质量比为 3.2-13×10^-6。如果 I Zw 18 是 Himiko 的一个合理的类比,那么 Himiko 的尘埃质量大约是 50000 个太阳质量,比目前的上限低 100 倍。这些数字相当不确定,但如果大多数高 z 星系更像 Himiko 而不是像尘埃质量非常高的星系 SDSS J114816.64+525150.3 那样,后者的红移约为 6,其中有一个类星体,那么我们探测这些星系内部气体和尘埃的前景就比预期的要差得多。
