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DMREF/Collaborative Research: Chemoresponsive Liquid Crystals Based on Metal Ion-Ligand Coordination

DMREF/合作研究：基于金属离子-配体配位的化学响应液晶

基本信息

批准号：
1902683
负责人：
Nicholas Abbott
金额：
$ 16.52万
依托单位：
Cornell University
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2018
资助国家：
美国
起止时间：
2018-08-16 至 2020-09-30
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1902683&HistoricalAwards=false
关键词：
DMREF Collaborative Research Chemoresponsive Liquid

项目摘要

DMREF: Collaborative Research: Chemoresponsive Liquid Crystals Based on Metal Ion-Ligand CoordinationNon-Technical Description: Computer-based methods that can predict materials properties have the potential to transform the current materials design paradigm into one based on integrated "cycles" of computation, experimentation and data analysis, thereby substantially accelerating materials development while decreasing costs. This DMREF project seeks to advance this vision through the formation of an interdisciplinary team with deep insight in computational chemistry (Mavrikakis), synthetic organic chemistry (Twieg) and physical property measurement (Abbott). The team will tackle the challenge of accelerating deployment of promising classes of chemically-responsive materials that are based on liquid crystals (LCs). In addition to addressing fundamental scientific questions related to the design of chemically functionalized LCs and interfaces, the project will advance the enormous technological and societal potential of these materials as the basis of new classes of sensors and actuators that can, for example, be used in the context of environmental monitoring of climate change, detection of toxic industrial chemicals or chemical warfare agents, and measurement of volatile gases in breath as an indicator of disease. The multi-disciplinary environment created by this DMREF project will also contribute to the training of a next generation workforce fully versed in the new materials deployment paradigm that integrates computational chemistry, synthesis and property characterization to rapidly design and realize functional materials. The project will be leveraged by the investigators to develop new university-level educational materials as well as new programs for public outreach efforts and engagement of underrepresented groups. Members of this DMREF team have a record of entrepreneurism; students and postdoctoral fellows engaged in this project will be provided with opportunities to participate in entrepreneurial activities. All of the efforts of the group will be integrated by an approach to data management that is designed also to interface to key US national databases and thus contribute to the Materials Genome Initiative national infrastructure by providing unfettered access to data and metadata for the broader scientific and industrial community. Technical Description: Laborious and slow experimental efforts over the past decade have demonstrated the promise of chemoresponsive liquid crystals (LCs) in the context of sensing one important class of chemical targets (organophosphonates). The principles, however, are far more general and thus an opportunity exists to design chemically tailored LCs and interfaces that respond selectively to many other classes of target molecules. This DMREF project will address this broad opportunity by integrating cycles of computation (performed at several levels, called Generations), organic synthesis of novel mesogens and physical property evaluation to accelerate the timeline for design of LC materials that respond selectively to societally important chemical species such as HCN, (CH3)2CO, HCHO, O3, CO, NH3, NO, ClCN, CO2, NO2 and H2O. A key aspect of the intellectual merit of this DMREF project lies in the development of new knowledge that will enable integration of computation, experiment and data analysis for the design of functional materials. The close feedback between computation (at the level of electronic structure), synthesis of functional mesogens and property characterization, which will lead to advances in each methodology, will define new principles for the design of chemoresponsive liquid crystalline materials based on metal-ligand coordination. It will also provide fundamental advances in our understanding of hierarchical design of chemically responsive materials, interfacial ordering of soft matter, and the use of metal ion-ligand coordination interactions to control the interfacial ordering of LCs.

DMREF：协作性研究：基于金属离子-配体配位的化学响应性液晶非技术描述：基于计算机的方法可以预测材料的性质，有可能将当前的材料设计范例转变为基于计算、实验和数据分析的综合“循环”，从而大大加快材料开发，同时降低成本。DMREF项目旨在通过组建一个在计算化学(Mavrikakis)、合成有机化学(Twiig)和物理性质测量(Abbott)方面具有深刻洞察力的跨学科团队来推动这一愿景。该团队将解决加快部署基于液晶(LCS)的有前途的化学响应材料类别的挑战。除了解决与化学功能化LCD和接口设计相关的基本科学问题外，该项目还将促进这些材料作为新型传感器和致动器的基础的巨大技术和社会潜力，例如，这些传感器和致动器可用于气候变化的环境监测、有毒工业化学品或化学战剂的检测，以及作为疾病指示器的呼气中挥发性气体的测量。DMREF项目创建的多学科环境还将有助于培训完全精通新材料部署范例的下一代劳动力，该范例集成了计算化学、合成和性能表征，以快速设计和实现功能材料。调查人员将利用该项目开发新的大学教育材料以及新的方案，用于公共宣传努力和参与代表性不足的群体。DMREF团队的成员具有创业精神；参与该项目的学生和博士后研究员将获得参与创业活动的机会。该小组的所有努力将被一种数据管理方法整合在一起，该方法还旨在与美国关键的国家数据库对接，从而通过为更广泛的科学和工业界提供不受限制的数据和元数据访问，为材料基因组计划的国家基础设施做出贡献。技术描述：在过去的十年里，艰苦而缓慢的实验工作证明了化学响应型液晶(LCS)在传感一类重要的化学目标(有机膦类)方面的前景。然而，这些原理要普遍得多，因此存在一个机会来设计化学定制的LC和界面，这些界面选择性地响应许多其他类别的目标分子。DMREF项目将通过整合计算(在几个层次上进行，称为世代)、新介元的有机合成和物理性质评估的循环来处理这一广泛的机会，以加快LC材料设计的时间表，这些材料对具有社会重要性的化学物种，如HCN、(CH3)2CO、HCHO、O3、CO、NH3、NO、CLCN、CO2、NO2和H2O有选择地做出响应。DMREF项目智力价值的一个关键方面在于新知识的开发，这将使功能材料设计的计算、实验和数据分析相结合。计算(在电子结构水平上)、功能介元的合成和性质表征之间的密切反馈将导致每种方法的进步，这将为基于金属-配体配位的化学响应性液晶材料的设计确定新的原则。它还将为我们理解化学响应材料的分层设计、软物质的界面有序化以及使用金属离子-配体配位相互作用来控制液晶的界面有序化提供基础性的进展。