This award is funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5). The objective of this Major Research Instrumentation (MRI-R2) award is to acquire several complementary instruments to establish a strong capability in micro- and nano-characterization of mechanical behavior of materials in controlled environments and under external stimuli. Specifically, a nanoindenter and a nano-impact/fatigue tester will be acquired that are capable of operating in controlled temperature, atmosphere, and liquid environment while under thermal, electrical, electrochemical, and biological stimuli. The instruments will enable and enhance several research and education activities, including understanding and developing: (1) new materials for electrochemical energy storage; (2) lightweight materials for aerospace and automotive applications; (3) lead-free soldering for electronic interconnects, micro-electromechanical devices (MEMS), and micro-fluidic devices; and (4) biomaterials and multi-functional, smart materials for biomedical applications. Advancing these technologies requires measuring, at the micro- and nano-meter scale, mechanical behavior of functional and structural materials in application environments.
In the coming decade, coupled mechanical-X (where X can be thermal, electrical, electrochemical, or biological stimuli) will emerge as an active field of scientific pursuit with a broad range of applications. In situ nanomechanical measurements at application conditions will accelerate materials research in many critical technology areas, including more powerful and longer lasting batteries, lighter and stronger materials for automobiles and airplanes, and more robust bio-compatible and bio-degradable implants. Graduate and undergraduate students will benefit through hands-on laboratory training and participation in the research using the in situ nanomechanical systems. The instruments will be accessible to faculty members, students, and industrial partners from multiple disciplines who have a shared interest and a common need for nanomechanical characterization. The research activities enabled by the instruments will impact critical areas such as automotive, aerospace, electronics, medicine, and energy conversion and storage.
This award was funded under the American Recovery and Reinvestment Act of 2009 (Public Law 111-5). The objective of this Major Research Instrumentation (MRI-R2) award was to acquire several complementary instruments to establish a strong capability in micro- and nano-characterization of mechanical behavior of materials in controlled environments and under external stimuli. Specifically, a nanoindenter and a nanoimpact/fatigue tester have been acquired that are capable of operating in controlled temperature, atmosphere, and liquid environment while under thermal, electrical, electrochemical, and biological stimuli. The instruments have enabled and enhanced several research and educational activities, including understanding and developing: (1) new materials for electrochemical energy storage; (2) lightweight materials for aerospace and automotive applications; and (3) biomaterials and multi-functional, smart materials for biomedical applications. Advancing these technologies requires measuring, at the micro- and nano-meter scale, mechanical behavior of functional and structural materials in application environments. Recently, understanding coupled mechanical-X (where X can be thermal, electrical, electrochemical, or biological stimuli) phenomena is emerging as an active field of scientific pursuit with a broad range of applications. In situ nanomechanical measurements at application conditions are accelerating materials research in many critical technological areas, including more powerful and longer lasting batteries, lighter and stronger materials for automobiles and airplanes, and more robust bio-compatible and bio-degradable implants. A number of graduate students across University of Kentucky campus are using the two systems to study materials for lithium ion batteries, high temperature shape memory alloys, magnesium alloys for biodegradable implants, mechanical behavior of nanoporous metals, and the mechanical properties of bones. The research activities enabled by the instruments will impact critical areas such as automotive, aerospace, medicine, and energy conversion and storage.
