Complex deuteron NMR signals

IF 2.8 3区物理与天体物理 Q2 PHYSICS, NUCLEAR

The European Physical Journal A Pub Date : 2025-07-26 DOI:10.1140/epja/s10050-025-01644-z

Michael McClellan, Elena Long

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Abstract

To determine the spin polarization of deuterons, nuclear magnetic resonance (NMR) is used. This is necessary for polarized targets, such as for the upcoming \(A_{zz}\) and \(b_{1}\) experiment at Jefferson Lab. NMR measures the impedance of a solenoid around a deuterated sample. Although the impedance is a complex value, conventionally only the real part of the impedance has been used for this purpose. However, often the tune is not precisely real, meaning the signal has at least some small imaginary portion. This conventionally has been dealt with by an offset parameter, such as Dulya’s false asymmetry method. For vector polarization, this suffices, as the tuning is factored into the overall error of the results, and for a small phase angle doesn’t make much of a difference. However, for tensor polarization, the exact lineshape of the signal is quite significant, and treating the impedance as complex during analysis removes the need for an offset parameter. It also provides more accurate results, as the conventional false asymmetry method over- or underestimates polarization, depending on the sign of the phase angle.

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复合氘核磁共振信号

为了确定氘核的自旋极化，使用了核磁共振（NMR）。这对于极化目标是必要的，例如即将在杰斐逊实验室进行的\(A_{zz}\)和\(b_{1}\)实验。核磁共振测量氘化样品周围螺线管的阻抗。虽然阻抗是一个复数值，但传统上只使用阻抗的实部来实现这一目的。然而，通常情况下，音调不是完全真实的，这意味着信号至少有一些小的虚部。这通常是通过偏移参数来处理的，比如杜利亚的假不对称方法。对于矢量偏振，这就足够了，因为调谐被考虑到结果的总体误差中，并且对于小相角不会产生太大的差异。然而，对于张量极化，信号的确切线形是相当重要的，并且在分析时将阻抗视为复杂的消除了对偏移参数的需要。它还提供了更准确的结果，因为传统的假不对称方法高估或低估极化，取决于相位角的符号。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

The European Physical Journal A 物理-物理：核物理

CiteScore

5.00

自引率

18.50%

发文量

216

审稿时长

3-8 weeks

期刊介绍： Hadron Physics Hadron Structure Hadron Spectroscopy Hadronic and Electroweak Interactions of Hadrons Nonperturbative Approaches to QCD Phenomenological Approaches to Hadron Physics Nuclear and Quark Matter Heavy-Ion Collisions Phase Diagram of the Strong Interaction Hard Probes Quark-Gluon Plasma and Hadronic Matter Relativistic Transport and Hydrodynamics Compact Stars Nuclear Physics Nuclear Structure and Reactions Few-Body Systems Radioactive Beams Electroweak Interactions Nuclear Astrophysics Article Categories Letters (Open Access) Regular Articles New Tools and Techniques Reviews.