Collaborative Research: LSC Center for Coatings Research

合作研究：LSC 涂料研究中心

• 批准号: 1707876
• 负责人: Stefan Ballmer
• 金额: $ 35万
• 依托单位: Syracuse University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2017
• 资助国家: 美国
• 起止时间: 2017-08-15 至 2021-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1707876&HistoricalAwards=false
• 关键词: Collaborative; Research; LSC; Center; Coatings

The LIGO Scientific Collaboration (LSC) Center for Coatings Research (CCR), funded by the NSF and with planned co-funding by the Gordon and Betty Moore Foundation, seeks to extend the reach of the next generation of gravitational wave detectors by addressing the dominant noise source limiting their performance, thermal noise in the interferometer mirrors. This noise reduces the number of observable gravitational wave signals from astronomical sources. It arises from thermal excitation of the vibrational modes of the mirrors in the LIGO detector optics. The effect of these excitations is reduced as the mechanical quality factor (Q) of the mirrors is increased. Since the Q of the mirrors is limited by the reflective coatings deposited on their surfaces, lower noise requires development of better coatings. The CCR combines groups from 10 institutions in the US working on computational modeling of amorphous materials, deposition of coatings, and characterization of their atomic structure and macroscopic properties. 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 of accelerating discoveries arises from close integration of these three communities focused on a unified research goal. Coating thermal noise is also a limiting factor in the fields of precision timing, quantum information, low noise interferometry, and precision measurements like the search for deviations in the gravitational inverse-square law. Coatings improving on the state of the art in mechanical and optical properties developed under this program would be applicable to these communities as well. On broader impacts in education, the mixture of undergraduate institutions with elite graduate programs provides research opportunities at all education levels and establishes clear avenues of advancement for students who wish to pursue a career within the physical sciences. In addition, the CCR has a strong commitment to the advancement of women and underrepresented minorities; and will also continue its participants' activities in issues of education and public outreach through all major channels of public and social media.The A+ LIGO detector, planned for 2021, will reduce quantum noise with squeezed light injection, leaving thermal noise dominant in the mid-band of the detector. Reducing this noise source requires reducing the mechanical dissipation in the mirror coatings on the test masses. The goal of this project is to develop mirror coatings consistent with A+ LIGO's mechanical and optical requirements. Meeting this goal requires solution of a longstanding problem in the physics of amorphous materials: the nature and control of the low-energy excitations in amorphous oxides. On a longer time scale, developing mirror coatings for the cryogenic LIGO Voyager detector broadens the possibilities to include amorphous or crystalline semiconductors. The primary research focus is to find conditions under which amorphous metal-oxide coatings can be deposited as "ultrastable glasses", which have a low density of the structural motifs that form two-level systems, the source of elastic dissipation. A second research track seeks methods to stabilize coatings against crystallization during high temperature annealing, another method known to reduce room temperature elastic losses. For the longer term research towards LIGO Voyager applications, the group will investigate non-oxide coatings such as single-crystal semiconductors AlGaAs and AlGaP, which have shown low mechanical loss for small geometries but whose scale up to the size of LIGO optics is challenging; and also amorphous silicon and silicon nitride, which have attractive mechanical properties but whose optical properties must be improved.

LIGO科学合作(LSC)涂层研究中心(CCR)由NSF资助，计划由Gordon和Betty Moore基金会共同资助，旨在通过解决限制其性能的主要噪声源-干涉仪镜中的热噪声-来扩展下一代引力波探测器的覆盖范围。这种噪声减少了来自天文来源的可观测引力波信号的数量。它是由LIGO探测器光学系统中反射镜振动模式的热激发引起的。这些激发的影响随着反射镜的机械品质因数(Q)的增加而减小。由于反射镜的Q受其表面沉积的反射膜的限制，要想降低噪声就需要开发更好的膜层。CCR结合了来自美国10个机构的小组，致力于非晶态材料的计算建模、涂层的沉积以及其原子结构和宏观性质的表征。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前景来自于这三个社区的紧密结合，专注于一个统一的研究目标。涂层热噪声也是精密计时、量子信息、低噪声干涉测量和精密测量领域的限制因素，如寻找引力平方反比定律的偏差。根据该计划开发的在机械和光学性能方面不断改进的涂料也将适用于这些社区。在更广泛的教育影响方面，本科生机构和精英研究生课程的混合为所有教育水平的研究提供了机会，并为希望在物理科学领域寻求职业生涯的学生建立了明确的晋升途径。此外，CCR坚定地致力于提高妇女和代表性不足的少数群体的地位；还将通过所有主要的公共和社交媒体渠道，继续其参与者在教育和公共宣传问题上的活动。计划于2021年推出的A+LIGO探测器将通过压缩光注入减少量子噪声，使热噪声在探测器的中频占据主导地位。减少这种噪声源需要减少测试质量块上的镜面涂层中的机械损耗。该项目的目标是开发符合A+LIGO机械和光学要求的镜面涂层。要实现这一目标，需要解决非晶态材料物理学中的一个长期存在的问题：非晶态氧化物中低能激发的性质和控制。在更长的时间尺度上，为低温LIGO旅行者探测器开发镜面涂层扩大了包括非晶态或晶态半导体的可能性。主要的研究重点是寻找在什么条件下非晶态金属氧化物涂层可以被沉积成“超稳定玻璃”，这种玻璃具有形成二能级系统的低密度结构基元，是弹性耗散的来源。第二个研究轨道是寻找在高温退火过程中稳定涂层抗结晶的方法，这是另一种已知的减少室温弹性损失的方法。对于LIGO Voyager应用的长期研究，该小组将研究非氧化物涂层，如单晶半导体AlGaAs和AlGaP，这种涂层的小几何尺寸具有较低的机械损失，但其尺寸达到LIGO光学元件的大小具有挑战性；还有非晶硅和氮化硅，它们具有诱人的机械性能，但其光学性能必须得到改善。