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Collaborative Research: A Comprehensive Theoretical Study of Cosmological Magnetic Fields and Turbulence: from the Early to Late Time Universe

合作研究：宇宙磁场和湍流的综合理论研究：从宇宙早期到晚期

基本信息

批准号：
2307698
负责人：
Tina Kahniashvili
金额：
$ 35.91万
依托单位：
Carnegie-Mellon University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2023
资助国家：
美国
起止时间：
2023-09-01 至 2026-08-31
项目状态：
未结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=2307698&HistoricalAwards=false
关键词：
Collaborative Research Comprehensive Theoretical Study

项目摘要

The invisible magnetic fields permeate our Universe everywhere, at different length scales ranging from planets (as Earth’s magnetic field) and stars (as Sun’s magnetic field) to the large-scale fields observed in galaxies (as the Milky Way – our Galaxy’s magnetic field) and galaxy clusters, and even at larger scales filling the space between galaxy clusters. Recent observational data suggest the existence of magnetic fields in voids – the emptiest and darkest regions – as well. Scientists at Carnegie Mellon University and the Massachusetts Institute of Technology propose to carry out a theoretical research program aimed at understanding the origin of cosmic magnetism, which is one of the most challenging questions in modern astrophysics that impacts scales from the space surrounding Earth to the faraway regions of the Universe. As part of this project, the PIs will participate in a series of public outreach activities, with programming designed to engage local middle and high school students and teachers, disabled veterans, as well as the general public.The focus of this research program is to investigate the origin, evolution and observational consequences of cosmic magnetic fields, including physical processes in the early-universe as well as in the interstellar medium. It is commonly assumed that the observed cosmic magnetic fields originated from the weak seed fields of unknown origin. Two basic scenarios are generally considered: (1) a bottom-up (astrophysical) scenario, where the seed is typically very weak and the magnetic field is transferred from local sources within galaxies to larger scales; (2) a top-down (cosmological) scenario, where a strong seed field is generated prior to galaxy formation in the early universe on scales that are now large. This project will investigate the top-down scenario in order to illuminate the role of magnetic fields as a probe of fundamental physics. The physics of primordial magnetogenesis can be broken down into three main motifs that are addressed in the research program: the generation of a magnetic field in the early universe, the evolution of this field subject to magnetohydrodynamic effects through the various cosmological epochs, and the detection of this magnetic field with a comprehensive array of astrophysical and cosmological observations. To study these processes, the team will perform coherent theoretical and computational modeling as well as statistical analysis used to interpret the simulations and observational data. This work will provide the tools needed to discriminate between different magnetogenesis scenarios, and will establish whether the observed cosmic magnetic fields require physics beyond the Standard Model of cosmology and particle physics.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

看不见的磁场渗透到我们宇宙的各个地方，从行星（地球的磁场）和恒星（太阳的磁场）到在星系（银河系-我们银河系的磁场）和星系团中观察到的大尺度场，甚至在更大的尺度上填充星系团之间的空间。最近的观测数据表明，磁场也存在于空洞中--最空旷和最黑暗的区域。卡内基梅隆大学和马萨诸塞州理工学院的科学家提议开展一项理论研究计划，旨在了解宇宙磁力的起源，这是现代天体物理学中最具挑战性的问题之一，影响范围从地球周围的空间到宇宙的遥远区域。作为该项目的一部分，PI将参与一系列公共外展活动，旨在吸引当地初中和高中学生和教师，残疾退伍军人以及公众参与。该研究计划的重点是调查宇宙磁场的起源，演变和观测结果，包括早期宇宙和星际介质中的物理过程。通常认为，观测到的宇宙磁场起源于未知来源的弱种子场。一般认为有两种基本的情况：（1）自下而上（天体物理学）的情况，其中种子通常非常弱，磁场从星系内的本地源转移到更大的尺度;（2）自上而下（宇宙学）的情况，其中在早期宇宙中的星系形成之前，在现在的大尺度上产生了强大的种子场。这个项目将研究自上而下的方案，以阐明磁场作为基础物理学探测器的作用。原始磁生成的物理学可以分为三个主要主题，在研究计划中得到解决：在早期宇宙中产生磁场，通过各种宇宙学时代受磁流体动力学效应影响的磁场的演变，以及通过全面的天体物理学和宇宙学观测来检测这个磁场。为了研究这些过程，该团队将进行连贯的理论和计算建模以及用于解释模拟和观测数据的统计分析。这项工作将提供所需的工具来区分不同的磁生情景，并将确定所观察到的宇宙磁场是否需要超越宇宙学和粒子物理学标准模型的物理学。该奖项反映了NSF的法定使命，并已被认为是值得通过使用基金会的智力价值和更广泛的影响审查标准进行评估的支持。