Zusammenfassung
Laser-polarized xenon can be used to increase the sensitivity of NMR experiments by 4-5 orders of magnitude, enabling numerous applications in physics, chemistry, biology, and medicine. For the production of hyperpolarized (hp) Xe-129, continuous flow pump cells are commonly used. Based on a 3D numerical model consisting of eight partial differential equations [1], we describe the optimization of ...
Zusammenfassung
Laser-polarized xenon can be used to increase the sensitivity of NMR experiments by 4-5 orders of magnitude, enabling numerous applications in physics, chemistry, biology, and medicine. For the production of hyperpolarized (hp) Xe-129, continuous flow pump cells are commonly used. Based on a 3D numerical model consisting of eight partial differential equations [1], we describe the optimization of continuous flow cells with respect to several experimental parameters in this contribution. We also compare our simulations with data from literature.
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