MRI: Acquisition of a Cryogenic, Aberration-Corrected Scanning Transmission Electron Microscope for Advanced Materials Research and Education

MRI：采购低温、像差校正扫描透射电子显微镜，用于先进材料研究和教育

• 批准号: 1429155
• 负责人: Lena Kourkoutis
• 金额: $ 269.84万
• 依托单位: Cornell University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-09-01 至 2016-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1429155&HistoricalAwards=false
• 关键词: MRI; Acquisition; Cryogenic; Aberration; Corrected

Nontechnical: This award supports the acquisition of a first-of-its-kind electron microscope that allows materials to be studied in their natural environment using an electron beam that can be focused down to a subatomic spot, producing three-dimensional images of their structure and chemistry. While traditional electron microscope studies are limited to only materials that can survive in a hard vacuum comparable to that of outer space, this new instrument will, for the first time, allow researchers to take snapshots of both solids and liquids, and more importantly see the processes that occur at interfaces between solids and liquids stabilized by snap freezing. Understanding such interfaces has a wide-ranging impact, from enabling scientists and engineers to design more durable batteries, more efficient catalysts for automotive fuel cells, to better retain nutrients in soil. To meet the huge demand for this capability both across campus, and also from industries and universities across the country, this instrument will be available as part of Cornell Center for Materials Research (CCMR) to researchers and students across campus as well as from other universities, industry and national labs. The microscope will also provide hands-on research opportunities for undergraduates, particularly under-represented minorities and women as part of the CCMR Research Experience for Undergraduates program, offer middle school girls the opportunity to experience the excitement of science as part of the Expanding Your Horizons program, and support K-12 teachers development through CCMR's Research Experience for Teachers program, and through MicroWorld, a microscopy-based activity that will be adapted to meet the challenges of the Next Generation Science Standards. This instrument will have broad impacts on science research and training by providing unique characterization capabilities of materials and devices and by educating a new generation of electron microscopists, which will lead to major scientific and technical advances in broad areas of research that are critical to the fulfillment of the nation?s research agenda, and the maintenance of the country's competitive position in critically important fields of science and technology. Technical: Recent advances in electron microscopy design have opened a new era of atomic resolution imaging and spectroscopy inside solids. Liquid/solid interfaces have yet to be imaged at high spatial resolution, but play a critical role in a range of biological, chemical and physical processes from catalysis to electrochemical energy storage to the formation of biominerals. With the ability to study liquids snap-frozen in a vitreous state, this cryo-STEM, combining the low-vibration cryo-stages from biology with the resolution-enhancing aberration-correctors from materials science, will enable presently unfeasible structural and spectroscopic studies of electrode/electrolyte interfaces in batteries and fuel cells, organic/mineral interfaces in breast cancer tumors and calcified aortic valves, and liquid/mineral complexes in soils. More generally, this class of "hard/soft" interfaces between minerals and liquids or soft tissue has not been explored at high spatial resolution, as the methods for studying the "hard" and "soft" components have been incompatible. Operating at cryogenic temperatures will also allow users to gain unprecedented insights into the macromolecular organization of cellular environments at nanometer resolution and to access a new range of emergent electronic states and phases in artificially engineered materials and strongly-correlated systems. With the ability to capture the early stages of nucleation at interfaces, long unanswered questions in fields across multiple disciplines from biomineralization to energy conversion and storage, complex electronic materials and carbon sequestration using soils can be addressed.

非技术：该奖项支持获得首台电子显微镜，该显微镜允许使用电子束在自然环境中研究材料，电子束可以聚焦到亚原子点，产生其结构和化学的三维图像。虽然传统的电子显微镜研究仅限于能够在与外太空相当的硬真空中存活的材料，但这种新仪器将首次允许研究人员拍摄固体和液体的快照，更重要的是看到固体和液体之间的界面发生的过程。了解这种界面具有广泛的影响，从使科学家和工程师能够设计更耐用的电池，更有效的汽车燃料电池催化剂，到更好地保留土壤中的养分。为了满足整个校园以及全国各地的工业和大学对这种能力的巨大需求，该仪器将作为康奈尔材料研究中心（CCMR）的一部分提供给整个校园以及其他大学，工业和国家实验室的研究人员和学生。作为CCMR本科生研究体验项目的一部分，这台显微镜还将为本科生，特别是代表性不足的少数民族和女性提供动手研究的机会，为中学女生提供体验科学兴奋的机会，作为拓展视野项目的一部分，并通过CCMR的教师研究体验项目和MicroWorld支持K-12教师的发展。这是一项以显微镜为基础的活动，将适应“下一代科学标准”的挑战。该仪器将对科学研究和培训产生广泛的影响，通过提供材料和设备的独特表征能力，并通过培养新一代电子显微镜学家，这将导致对国家实现至关重要的广泛研究领域的重大科学和技术进步。美国的研究议程，以及维持国家在至关重要的科学技术领域的竞争地位。技术：电子显微镜设计的最新进展开启了固体内部原子分辨率成像和光谱学的新时代。液体/固体界面尚未在高空间分辨率下成像，但在从催化到电化学能量存储到生物矿物形成的一系列生物，化学和物理过程中发挥着关键作用。由于能够研究玻璃体状态下的液体快速冷冻，这种冷冻stem结合了生物学的低振动冷冻阶段和材料科学的分辨率增强像差校正器，将使目前不可行的电池和燃料电池中的电极/电解质界面，乳腺癌肿瘤和钙化主动脉瓣中的有机/矿物界面以及土壤中的液体/矿物复合物的结构和光谱研究成为可能。更普遍的是，由于研究“硬”和“软”成分的方法不相容，这类矿物与液体或软组织之间的“硬/软”界面尚未在高空间分辨率下进行探索。在低温下操作还将允许用户以纳米分辨率获得对细胞环境大分子组织的前所未有的见解，并访问人工工程材料和强相关系统中出现的新电子状态和相。由于能够在界面处捕获成核的早期阶段，从生物矿化到能量转换和储存，复杂的电子材料和利用土壤的碳封存等多个学科领域长期悬而未决的问题可以得到解决。

项目成果

Solid electrolyte interphases for high-energy aqueous aluminum electrochemical cells

• DOI: 10.1126/sciadv.aau8131
• 发表时间: 2018-11
• 期刊: Science Advances
• 影响因子: 13.6
• 作者: Qing Zhao;M. Zachman;Wajdi I Al Sadat;Jing Zheng;L. Kourkoutis;L. Archer

Probing the Native Structure and Chemistry of Dendrites and SEI Layers in Li-Metal Batteries by Cryo-FIB Lift-Out and Cryo-STEM

通过 Cryo-FIB Lift-Out 和 Cryo-STEM 探测锂金属电池中枝晶和 SEI 层的天然结构和化学性质

• DOI: 10.1017/s1431927618008073
• 发表时间: 2018
• 期刊: Microscopy and Microanalysis
• 影响因子: 2.8
• 作者: Zachman, Michael J.;Tu, Zhengyuan;Archer, Lynden A.;Kourkoutis, Lena F.
• 通讯作者: Kourkoutis, Lena F.