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Paper detail

Parahydrogen enhanced zero-field nuclear magnetic resonance

Nuclear magnetic resonance (NMR), conventionally detected in multi-tesla magnetic fields, is a powerful analytical tool for the determination of molecular identity, structure, and function. With the advent of prepolarization methods and alternative detection schemes using atomic magnetometers or superconducting quantum interference devices (SQUIDs), NMR in very low- (~earth's field), and even zero-field, has recently attracted considerable attention. Despite the use of SQUIDs or atomic magnetometers, low-field NMR typically suffers from low sensitivity compared to conventional high-field NMR. Here we demonstrate direct detection of zero-field NMR signals generated via parahydrogen induced polarization (PHIP), enabling high-resolution NMR without the use of any magnets. The sensitivity is sufficient to observe spectra exhibiting 13C-1H J-couplings in compounds with 13C in natural abundance in a single transient. The resulting spectra display distinct features that have straightforward interpretation and can be used for chemical fingerprinting.

preprint2011arXivOpen access
Thomas TheisPaul GanssleGwendal KervernSvenja KnappeJohn KitchingMicah LedbetterDmitry BudkerAlex Pines
physics.atom-phphysics.chem-ph
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Thomas TheisPaul GanssleGwendal KervernSvenja KnappeJohn KitchingMicah LedbetterDmitry BudkerAlex Pines

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