Cosmic Dawn Center (DAWN), Copenhagen, Denmark.
Niels Bohr Institute, University of Copenhagen, Copenhagen, Denmark.
Nature. 2023 Feb;614(7948):436-439. doi: 10.1038/s41586-022-05616-x. Epub 2023 Feb 15.
The mergers of neutron stars expel a heavy-element enriched fireball that can be observed as a kilonova. The kilonova's geometry is a key diagnostic of the merger and is dictated by the properties of ultra-dense matter and the energetics of the collapse to a black hole. Current hydrodynamical merger models typically show aspherical ejecta. Previously, Sr was identified in the spectrum of the only well-studied kilonova AT2017gfo, associated with the gravitational wave event GW170817. Here we combine the strong Sr P Cygni absorption-emission spectral feature and the blackbody nature of kilonova spectrum to determine that the kilonova is highly spherical at early epochs. Line shape analysis combined with the known inclination angle of the source also show the same sphericity independently. We conclude that energy injection by radioactive decay is insufficient to make the ejecta spherical. A magnetar wind or jet from the black-hole disk could inject enough energy to induce a more spherical distribution in the overall ejecta; however, an additional process seems necessary to make the element distribution uniform.
中子星合并会抛出一个富含重元素的火球,这个火球可以被观测到,被称为千新星。千新星的几何形状是合并的关键诊断指标,由超密物质的性质和塌缩为黑洞的能量决定。目前的流体力学合并模型通常显示出非球形的喷射物。此前,在与引力波事件 GW170817 相关的唯一研究充分的千新星 AT2017gfo 的光谱中,已经鉴定出 Sr。在这里,我们结合 Sr P Cygni 吸收-发射谱线特征的强吸收和千新星光谱的黑体性质,确定在早期千新星是高度球形的。谱线形状分析结合源的已知倾斜角也独立地显示了相同的球形度。我们得出结论,放射性衰变产生的能量不足以使喷射物成为球形。来自黑洞盘的磁星风或喷流可以注入足够的能量,在整个喷射物中产生更球形的分布;然而,似乎还需要一个额外的过程来使元素分布均匀。
