Assessing the potential of LIGO-India in resolving the Hubble Tension

arXiv - PHYS - General Relativity and Quantum Cosmology Pub Date : 2024-09-17 DOI:arxiv-2409.11361

Kanchan Soni, Aditya Vijaykumar, Sanjit Mitra

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Abstract

Determining the Hubble constant (H0), a fundamental parameter describing cosmic expansion, remains a challenge due to conflicting measurements from the early and late universe. Gravitational wave (GW) observations from binary neutron star (BNS) mergers, with identified host galaxies through electromagnetic (EM) follow-up, offer an independent method to measure H0. However, this requires detection of numerous events, which could take decades with current GW detectors. LIGO-India can dramatically accelerate this effort. With sensitivity comparable to the existing LIGO detectors, its addition to the LIGO-Virgo network could increase detected events by 70%. This improvement nearly doubles when accounting for the detector's 70% duty cycle, increasing the probability of simultaneous operation of three detectors by a factor of ~2. We perform end-to-end simulations to estimate triple-coincidence detection rates and sky localization, considering realistic BNS populations, lightcurves, and EM observatory specifications. Our findings suggest LIGO-India could increase BNS events with observed kilonovae by ~2-7 times. The factor of few improvements in source localization precision with LIGO-India can allow much deeper EM follow-up campaigns (not considered in the simulations), potentially increasing the overall rate of detection of EM counterparts by a factor of ~20, which can have an enormous impact in addressing critical questions in different areas of astronomy. We evaluate the impact of LIGO-India in the context of H0 measurement and argue that it can cut down the required observation time of several decades by a factor of few and possibly to just few years with regular sensitivity upgrades.

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评估 LIGO-India 在解决哈勃张力方面的潜力

哈勃常数（H0）是描述宇宙膨胀的一个基本参数，由于早期和晚期宇宙的测量结果相互矛盾，因此确定哈勃常数（H0）仍然是一个挑战。双中子星（BNS）合并产生的引力波（GW）观测，以及通过电磁（EM）跟踪确定的宿主星系，为测量哈勃常数提供了一种独立的方法。然而，这需要探测大量的事件，而目前的引力波探测器可能需要几十年的时间。LIGO-India的灵敏度与现有的LIGO探测器相当，将其加入LIGO-Virgo网络可以将探测到的事件增加70%。如果考虑到探测器70%的占空比，这种提高几乎会翻倍，使三个探测器同时工作的概率提高约2倍。我们进行了端到端模拟，以估计三重碰撞检测率和天空定位，并考虑了现实的BNS群、光曲线和电磁观测台规格。我们的研究结果表明，LIGO-India 可以使观测到千新星的 BNS 事件增加约 2-7 倍。LIGO-India在源定位精度上的几倍改进可以允许更深入的电磁跟踪活动（模拟中没有考虑），可能会将电磁对应物的总体探测率提高约20倍，这对解决天文学不同领域的关键问题会产生巨大影响。我们评估了 LIGO-India 在 H0 测量方面的影响，认为它可以将所需的几十年观测时间缩短数倍，如果定期升级灵敏度，可能只需几年时间。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - General Relativity and Quantum Cosmology

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