A solid-state NMR instrument for Northern Ireland
Lead Research Organisation:
Queen's University Belfast
Department Name: Sch of Chemistry and Chemical Eng
Abstract
Nuclear Magnetic Resonance (NMR) is a powerful analytical technique with applications which span a wide range of areas from medicine (MRI) to engineering, materials, pharmaceutical and chemical science. It is based on the principle that atomic nuclei change their orientation when placed in a strong magnetic field, in order to align with the magnetic field itself, and can be probed for information about their environment using a complex sequence of radiofrequency pulses. The most common variant of NMR as an analytical tool is solution state NMR, in which case samples are dissolved in an appropriate, usually deuterated, solvent prior to analysis. Despite the immense usefulness of this analysis mode, dissolution of a sample means key information for its structure in its native form, usually solid, which is also the form in which the sample is often meant to be used, is lost. For example a pharmaceutical compound that is to be taken as a tablet or a polymer coating to be used on a medical device or engineering application, should be tested as solids and not in the dissolved state. Furthermore, modern materials such as ceramics, composites, but also tissue, foodstuffs and environmental samples such as soil, are insoluble in common solvents, which renders them incompatible with NMR analysis.
These limitations have been overcome with the introduction of solid-state NMR (SS-NMR) which is able to analyse solid samples, using more powerful pulses and complex signal processing. In this case, scientists are able to gather invaluable information about sample structure, homogeneity and purity directly, in its native form. The technique has found applications in chemical, pharmaceutical and materials science, but also food and environmental analysis.
In this proposal, we are requesting funding to purchase and install a SS-NMR instrument at the School of Chemistry and Chemical Engineering at Queen's University Belfast, which will be the first and only of its kind in Northern Ireland and one of very few similar instruments on the island of Ireland, the north of England, and Scotland. This investment will offer academic and industrial researchers simpler, faster and less expensive access to this state-of-the-art technique, thus supporting the rapidly growing materials, energy, manufacturing, food, pharma and healthcare research and development in Northern Ireland, and neighbouring regions.
These areas align strongly with the UN Sustainable Development Goals, as well as the EPSRC's strategic research themes, and will support leading research in energy (CASE), healthcare technologies (MATCH), AI/Robotics and Manufacturing the Future (i-AMS, ECIT), and wider UKRI priority areas such as BBSRC's Bioscience for Sustainable Agriculture and Food theme (IGFS).
Apart from academic institutions NI, this application is supported by key industrial partners in the region and beyond, among which some of the biggest employers for skilled graduates in the energy, food, pharmaceuticals and manufacturing sectors.
These limitations have been overcome with the introduction of solid-state NMR (SS-NMR) which is able to analyse solid samples, using more powerful pulses and complex signal processing. In this case, scientists are able to gather invaluable information about sample structure, homogeneity and purity directly, in its native form. The technique has found applications in chemical, pharmaceutical and materials science, but also food and environmental analysis.
In this proposal, we are requesting funding to purchase and install a SS-NMR instrument at the School of Chemistry and Chemical Engineering at Queen's University Belfast, which will be the first and only of its kind in Northern Ireland and one of very few similar instruments on the island of Ireland, the north of England, and Scotland. This investment will offer academic and industrial researchers simpler, faster and less expensive access to this state-of-the-art technique, thus supporting the rapidly growing materials, energy, manufacturing, food, pharma and healthcare research and development in Northern Ireland, and neighbouring regions.
These areas align strongly with the UN Sustainable Development Goals, as well as the EPSRC's strategic research themes, and will support leading research in energy (CASE), healthcare technologies (MATCH), AI/Robotics and Manufacturing the Future (i-AMS, ECIT), and wider UKRI priority areas such as BBSRC's Bioscience for Sustainable Agriculture and Food theme (IGFS).
Apart from academic institutions NI, this application is supported by key industrial partners in the region and beyond, among which some of the biggest employers for skilled graduates in the energy, food, pharmaceuticals and manufacturing sectors.
Organisations
Publications
Pacchione M
(2024)
Evaluation of Performance and Stability of a Gel-Type Polymer Sorbent for Recovery of Phosphate from Waste Streams
in ACS Applied Polymer Materials
| Description | The research funded through this award has helped drive forward our understanding and practical use of advanced materials. In simple terms, here's what has been achieved: Peering into Materials at the Atomic Level: The installation and use of a solid-state NMR instrument have allowed researchers at Queen's University Belfast to "see" the detailed structure of materials at the molecular level. This means that scientists can understand exactly how the atoms in a material are arranged and how they interact with each other. Improving Material Performance: With this clearer picture, the team has been able to design and test new materials that are stronger, more efficient, or have unique properties. This can lead to better components in everything from electronics to energy storage devices. Advancing Antimicrobial Research: In parallel, the research supports work in discovering new antimicrobial compounds. By studying materials at a very detailed level, researchers are finding innovative ways to develop substances that can fight harmful bacteria. This is especially important in an era where antibiotic resistance is a growing concern. Broad Impact Across Fields: While the focus is on materials science, the techniques and insights from this research have wider applications. They can improve technologies in healthcare, such as creating better drug delivery systems, and in industry, such as developing more resilient materials for construction and manufacturing. Overall, this award has enabled significant advancements in our understanding of how materials work at the microscopic level, paving the way for innovative solutions in both everyday technologies and critical challenges like antimicrobial resistance. |
| Exploitation Route | The outcomes of this funding have the potential to be taken forward in several impactful ways: Advanced Materials Development: The detailed insights provided by the solid-state NMR instrument enable researchers to understand material structures at the atomic level. This knowledge can be used to design and optimize advanced materials with improved performance in sectors such as electronics, energy storage, and aerospace. Innovation in Antimicrobial Research: By applying these techniques, scientists are also exploring novel antimicrobial compounds. The ability to pinpoint subtle molecular interactions helps in designing new substances that can effectively combat antibiotic-resistant bacteria-a crucial advancement for public health. Industrial and Commercial Applications: The research outcomes can form the basis for new technologies that industry partners can adopt. For example, the methodologies developed might lead to more efficient manufacturing processes or the creation of high-performance materials for consumer products and medical devices. Academic Collaboration and Further Research: The findings and data generated provide a robust platform for further academic studies. Other research groups can build on these methods to explore new areas in chemical and materials science, thereby expanding our collective understanding and opening up further innovation. Knowledge Transfer and Training: The expertise developed through this project can be shared through training programs and collaborative networks. This helps to cultivate a skilled workforce and fosters partnerships between academia and industry, ensuring that the benefits of the research extend well beyond the initial study. |
| Sectors | Chemicals Education Energy Environment Healthcare Manufacturing including Industrial Biotechology Pharmaceuticals and Medical Biotechnology |
| Description | Although it is still early since award, the detailed insights into material structures achieved with the solid-state NMR instrument are being used to inform the development of advanced materials that industry partners can use to optimise products in sectors such as materials, energy storage, and manufacturing. These collaborations are expected to lead to new commercial products or improvements in manufacturing processes. |
| First Year Of Impact | 2025 |
| Sector | Chemicals,Environment,Healthcare,Manufacturing, including Industrial Biotechology,Pharmaceuticals and Medical Biotechnology |
| Impact Types | Economic |