RF coil efficacy for efficient spin control in low field magnetic resonance experiments✰

Michele N. Martin, Anthony B. Kos, Stephen E. Russek, Karl F. Stupic
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Abstract

At low magnetic fields (<1 T), the low loss of radio frequency (RF) coils can cause RF pulses, in magnetic resonance (MR) experiments, to suffer from long rise and fall times. When severe, long rise and fall times can result in RF pulses with undesirable and/or unexpected shapes, lengths, and amplitudes leading to inadequate spin control during an MR experiment. Experimentally, the lack of spin control becomes evident in the shape of the nutation curve and the inversion efficiency, the degree to which full inversion is accomplished following a 180° pulse. Lowering the quality factor (Q) of tuned coil is shown to reduce the duration of the rise and fall times. The effects of long rise and fall times on the spin behavior during an MR experiment is explored. It is shown that the inversion efficiency can be used to provide a threshold that ensures high fidelity pulses with adequate spin control.

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射频线圈在低场磁共振实验中的高效自旋控制效能
在低磁场(< 1t)下,射频(RF)线圈的低损耗会导致射频脉冲在磁共振(MR)实验中有很长的上升和下降时间。在严重的情况下,长时间的上升和下降会导致RF脉冲具有不希望和/或意想不到的形状、长度和幅度,从而导致MR实验期间自旋控制不足。在实验中,缺乏自旋控制在章动曲线的形状和反转效率(在180°脉冲后完全反转的程度)中变得明显。降低调谐线圈的质量因子(Q)可以减少上升和下降时间的持续时间。探讨了长上升和下降时间对磁流变实验中自旋行为的影响。结果表明,反转效率可以提供一个阈值,以确保具有足够的自旋控制的高保真脉冲。
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