Collaborative Research: Center for Coatings Research

合作研究：涂料研究中心

• 批准号: 2309297
• 负责人: Carmen Menoni
• 金额: $ 21.03万
• 依托单位: Colorado State University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2023
• 资助国家: 美国
• 起止时间: 2023-09-01 至 2025-08-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2309297&HistoricalAwards=false
• 关键词: Collaborative; Research; Center; Coatings

The Center for Coatings Research (CCR) focuses on the development of advanced mirror coatings for gravitational wave detectors, a new and booming field of observational astrophysics. By reducing mechanical loss and thus thermal noise in mirror coatings, the project aims to enhance the sensitivity of Cosmic Explorer (CE), the proposed third generation gravitational wave detector. This research holds significant importance as it expands our understanding of the universe by enabling observations of cosmic events, such as the collision of remnants from the first stars. Moreover, the project has broader impacts on precision measurement technology, benefiting areas like precision timing, quantum information, low noise interferometry, and the search for deviations in the gravitational inverse-square law. The outcomes of this research can also have implications for the semiconductor, laser, and quantum computing communities, as correlations between mechanical loss and other loss mechanisms are explored. Additionally, this collaboration between materials science and gravitational wave communities promotes education and diversity, providing research opportunities for students at different education levels and advancing the participation of women and underrepresented minorities.This project aims to develop mirror coatings that meet the mechanical and optical requirements for implementation in CE. Through extending the length of the interferometer arms from the current 4 km to 20 and/or 40 km systems, CE's observational reach will be significantly expanded. To fully utilize this infrastructure, improvements are necessary in the mirror coatings' mechanical loss and thermal noise reduction. The CCR combines groups working on coating deposition, characterization of atomic structure and macroscopic material properties, and computational modeling. These components are often performed by three diverse communities that work in relative isolation from each other. The strength of the CCR and its promise for accelerating discoveries arises from close integration of these communities focusing on a unified research goal. Since the formation of the CCR in 2017, the collaboration has become a knowledge repository for gravitational wave detector coatings research, making significant progress on all the proposed research directions, including uncovering atomic structural motifs associated with room temperature vs cryogenic mechanical losses, using that understanding to develop Ti:GeO2 coatings that can meet the requirements for Advanced LIGO + (A+). Going forward research efforts include the development of improved amorphous coatings and crystalline AlGaAs coatings. The project will investigate atomic structural motifs associated with mechanical losses at different temperatures, aiming for at least a two-fold reduction in thermal noise compared to Advanced LIGO + coatings. CCR contributions have implications for precision measurement, impacting various fields and potentially benefiting the semiconductor, laser, and quantum computing communities. Overall, this research advances the field of gravitational wave detection, supports education at multiple levels, and promotes diversity within the physical sciences.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.

涂层研究中心(CCR)致力于为引力波探测器开发先进的镜面涂层，这是一个新兴的观测天体物理学领域。通过减少镜面涂层中的机械损耗和热噪声，该项目旨在提高拟议的第三代引力波探测器宇宙探测器(CE)的灵敏度。这项研究具有重要意义，因为它通过观察宇宙事件，如第一批恒星的残骸碰撞，扩大了我们对宇宙的理解。此外，该项目对精密测量技术产生了更广泛的影响，受益于精确计时、量子信息、低噪声干涉测量和寻找引力平方反比定律的偏差等领域。这项研究的结果也可能对半导体、激光和量子计算社区产生影响，因为我们正在探索机械损失和其他损失机制之间的相关性。此外，材料科学和引力波社区之间的这种合作促进了教育和多样性，为不同教育水平的学生提供了研究机会，并促进了妇女和代表性不足的少数民族的参与。该项目旨在开发满足CE实施的机械和光学要求的镜面涂层。通过将干涉仪臂的长度从目前的4公里延长到20和/或40公里系统，CE的观测范围将显著扩大。为了充分利用这一基础设施，必须在镜面涂层的机械损耗和热噪声降低方面进行改进。CCR结合了致力于涂层沉积、原子结构和宏观材料属性的表征以及计算建模的小组。这些组件通常由彼此相对独立的三个不同的社区执行。CCR的优势及其加速发现的承诺源于这些社区的紧密整合，专注于统一的研究目标。自2017年CCR成立以来，该合作已成为引力波探测器涂层研究的知识库，在所有拟议的研究方向上都取得了重大进展，包括揭示与室温和低温机械损失相关的原子结构主题，利用这一理解开发出能够满足Advanced LIGO+(A+)要求的Ti：GeO2涂层。未来的研究工作包括开发改进的非晶涂层和晶态AlGaAs涂层。该项目将研究与不同温度下的机械损失有关的原子结构主题，目标是与先进的LIGO+涂层相比，至少将热噪声降低两倍。CCR的贡献对精密测量具有影响，影响到各个领域，并可能使半导体、激光和量子计算社区受益。总体而言，这项研究推进了引力波探测领域，支持了多层次的教育，并促进了物理科学的多样性。该奖项反映了NSF的法定使命，并通过使用基金会的智力优势和更广泛的影响审查标准进行评估，被认为值得支持。