HP-Xe to go: Storage and transportation of hyperpolarized (129)Xenon

J Magn Reson. 2016 Apr:265:197-9. doi: 10.1016/j.jmr.2016.02.011. Epub 2016 Feb 22.

Abstract

Recently the spin-lattice relaxation time T1 of hyperpolarized (HP)-(129)Xe was significantly improved by using uncoated and Rb-free storage vessels of GE180 glass. For these cells, a simple procedure was established to obtain reproducible wall relaxation times of about 18 h. Then the limiting relaxation mechanism in pure Xe is due to the coupling between the nuclear spins and the angular momentum of the Xe-Xe van-der-Waals-molecules. This mechanism can be significantly reduced by using different buffer gases of which CO2 was discovered to be the most efficient so far. From these values, it was estimated that for a 1:1 mixture of HP-Xe with CO2 a longitudinal relaxation time of about 7 h can be expected, sufficient to transport HP-Xe from a production to a remote application site. This prediction was verified for such a mixture at a total pressure of about 1 bar in a 10 cm glass cell showing a storage time of T1≈9 h (for T1(wall)=(34±9) h) which was transported inside a magnetic box over a distance of about 200 km by car.

Keywords: (129)Xe; Break-up rate; Buffer gases; Destruction rate; Laser polarization; Longitudinal; Relaxation; Spin–lattice; Transport boxes; Van der Waals; Wall.

Publication types

  • Research Support, Non-U.S. Gov't