Extreme Physics with Pulsars and Radio Transients

脉冲星和无线电瞬变的极端物理

• 批准号: RGPIN-2017-04057
• 负责人: Stairs, Ingrid
• 金额: $ 5.25万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2019
• 资助国家: 加拿大
• 起止时间: 2019-01-01 至 2020-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=691645
• 关键词: Extreme; Physics; Pulsars; Radio; Transients

Compact stellar objects such as neutron stars offer the opportunity to probe a wide range of fundamental physics problems. Many neutron stars emit lighthouse-like radio beams, which may hit the Earth once per rotation and cause us to label the star a pulsar. The fastest-spinning pulsars rotate several hundred times per second and can rival the stability of atomic clocks on short timescales. An array of these millisecond pulsars, spread across the sky, can be used to make a direct detection of gravitational waves passing near the Earth. The main sources of these gravitational waves is predicted to be pairs of supermassive black holes as the centres of galaxies that have recently undergone mergers, highly complementary to the stellar-mass black holes recently detected by the Laser Interferometric Gravitational-wave Observatory (LIGO). The pulsar timing array research proposed here will enhance the effectiveness of the North American Nanohertz Observatory for Gravitational Waves (NANOGrav), by improving the current data-reduction methods and by bringing in entirely new data which will address systematics due to variations in the interstellar medium. These data will come from the Canadian Hydrogen Intensity Mapping Experiment (CHIME) telescope under construction in Penticton, B.C. Simultaneously with its original cosmology mission, CHIME will provide daily data on the Northen NANOGrav pulsars, allowing us to model the variations in the interstellar medium in more detail than currently possible and providing corrections to the higher-frequency NANOGrav data. This project will accelerate the timeline for NANOGrav to make a detection of gravitational waves. CHIME will also provide dense data sets on numerous other interesting pulsars, including relativistic binaries, which are another long-term interest of this research group.******CHIME holds still more promise, for tackling the still-mysterious Fast Radio Bursts (FRBs). These are single spikes of radio emission, almost certainly extragalactic in origin, seen with some of the largest radio telescopes in existence. One of these sources has now been seen to repeat, but it is unclear at present whether there are two classes of source. What causes the bursts is still unknown-- in fact there are more published ideas than bursts at present -- but the inferred brightness and short timescale indicate that the involvement of a compact object such as a neutron star is likely. With a dedicated second instrument on CHIME, we expect to detect several tens of FRBs per day; the vastly improved statistics will constrain models and may help to localize the bursts well enough to identify host galaxies.

中子星等致密恒星天体为探索广泛的基础物理问题提供了机会。 许多中子星会发出类似灯塔的射电光束，每旋转一次，这些射电光束可能会撞击地球一次，使我们将这颗恒星标记为脉冲星。 旋转最快的脉冲星每秒旋转数百次，在短时间尺度上的稳定性可以与原子钟相媲美。 这些遍布天空的毫秒脉冲星阵列可用于直接探测经过地球附近的引力波。 据预测，这些引力波的主要来源是最近经历合并的星系中心的一对超大质量黑洞，与激光干涉引力波天文台（LIGO）最近探测到的恒星质量黑洞高度互补。 这里提出的脉冲星定时阵列研究将通过改进当前的数据缩减方法并引入全新的数据来解决由于星际介质的变化而引起的系统学问题，从而提高北美纳赫兹引力波观测站（NANOGrav）的有效性。 这些数据将来自于不列颠哥伦比亚省彭蒂克顿正在建造的加拿大氢强度测绘实验（CHIME）望远镜。 在执行最初的宇宙学任务的同时，CHIME 将提供有关北方 NANOGrav 脉冲星的每日数据，使我们能够比目前更详细地模拟星际介质的变化，并对更高频率的 NANOGrav 数据进行修正。 该项目将加快 NANOGrav 探测引力波的时间。 CHIME 还将提供许多其他有趣的脉冲星的密集数据集，包括相对论性双星，这是该研究小组的另一个长期兴趣。******CHIME 在解决仍然神秘的快速射电爆发（FRB）方面还有更多希望。 这些是射电发射的单个尖峰，几乎可以肯定起源于河外，可以用现有的一些最大的射电望远镜观察到。 其中一种来源现已被发现重复，但目前尚不清楚是否存在两类来源。 导致爆发的原因仍然未知——事实上，目前已发表的想法比爆发还要多——但推断出的亮度和短时间尺度表明，很可能涉及中子星等致密天体。 借助 CHIME 上的第二台专用仪器，我们预计每天可以检测到数十个 FRB；大大改进的统计数据将限制模型，并可能有助于充分定位爆发以识别宿主星系。