Advanced Functional Properties in Coordination Framework Materials. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic synthesis of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and negative thermal expansion. This innovative work will lead to important fundamental advances ....Advanced Functional Properties in Coordination Framework Materials. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic synthesis of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and negative thermal expansion. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how physical properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with future application of the materials in molecular separations, sensing, energy conversion, electronics and photonics.Read moreRead less
Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental ....Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in molecular separations and sensing, clean energy storage, electronics and photonics.Read moreRead less
Cation Ordering - A Strategy to Prepare Multiferroic Oxides. This project will produce new families of functional metal oxides with technologically relevant properties, especially multiferroic behavior. Such materials are highly sort-after in the rapidly emerging field of spintronics. Through comprehensive experimental studies of a number of such materials this project will enhance the ability of industry to develop new and improved materials.
Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. Th ....Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in electronics, photonics, molecular sensing, drug synthesis and purification, clean energy and the controlled release of agrochemicals and pharmaceuticals.Read moreRead less
Structural and Electronic Properties of Layered Bismuth Oxides. A systematic study of the role of cation substitutions and temperature on the structural and electronic properties of a number of layered bismuth oxides will undertaken with the aim of developing improved ferroelectric materials for use in electronic devices.
Complex Phenomena and Phase Transitions in Ferroric Perovskites. The ultimate aim of this project is to identify high performance, multiferroic magnetoelectrics suitable for use in the next generation electronic devices. These oxides exhibit a strong interaction between the polarisation and magnetic response. Understanding the factors that control the response of such materials to applied magnetic and electric fields is critical to the discovery, optimization and, ultimately, industrial exploi ....Complex Phenomena and Phase Transitions in Ferroric Perovskites. The ultimate aim of this project is to identify high performance, multiferroic magnetoelectrics suitable for use in the next generation electronic devices. These oxides exhibit a strong interaction between the polarisation and magnetic response. Understanding the factors that control the response of such materials to applied magnetic and electric fields is critical to the discovery, optimization and, ultimately, industrial exploitation of such materials. Through comprehensive experimental and theoretical studies of a number of such materials this project will enhance the ability of industry to develop new and improved materials. Development of advanced materials is a designated National Research Priority area. Read moreRead less