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The facility contains five million dollars of equipment and has been developed with the support of the Australian Research Council and the Max Planck Institute of Chemical Energy Conversion. Bruker Biospec MRI device installed at The Weizmann Institute of Science. Low temperature measurements from 3.8 K to Room temperature are supported. It allows for continuous wave, pulsed, transient measurements, in situ electrochemistry, in situ gas exchange and in situ light (Solar, UV, LED, laser) excitation. The facility is available to all researchers across Australia and New Zealand, and the Asia-Pacific. It contains three instruments operating at X (9 GHz), Q (34 GHz) and W (94 GHz) bands with field strengths of 0.3 to 6 Tesla. The EPR centre at ANU is Australia’s premier facility, hosting the only High-Field EPR instrument in the Southern Hemisphere. This complements six other spectrometers operating at field strengths between 4.7 and 14.1 Tesla. Pulsed Fourier Transform: the Piano Experiment.
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Nuclear Magnetic Resonance: Spin, Field, Precession. The Centre now has one of the most sophisticated NMR spectrometers in Australia including very fast solid state (MAS) capacity. These visuals are made from the original lecture transparencies. ANU was a joint recipient of an Australian Research Council grant for the purchase of an 800 MHz NMR spectrometer and cryoprobe. Data collection and control were performed using Bruker WinEPR version 4.40 software. EPR measurements were performed on a Bruker A300 spectrometer at room temperature. magnetization shifts in very high frequency pulsed electron paramagnetic. The 27Al nutation frequency of the irradiation field was about 50 kHz. The NMR Centre at ANU is one of the most advanced in Australia, boasting equipment worth over eight million dollars and catering for over 100 staff and students across six Schools and Faculties. Takahashi for pioneering the high-field EPR work at UCSB and for useful. The magnetic resonance facility based at the Research School of Chemistry caters for both Nuclear Magnetic Resonance (NMR) and Electron Paramagnetic Resonance (EPR). It has many important applications in biological and material sciences including macro-molecular and surface science, catalysis, photochemistry, medicine and physics. It is the single most powerful method available to chemists for studying the composition, structure and function of molecules. Magnetic Resonance techniques have applications in all fields of the experimental sciences.