液体NMR中平板间多量子相干受限扩散行为的有限差分模拟

将平板间单量子相干受限扩散理论表述推广到多量子相干,并结合积算符矩阵、Bloch方程和有限差分方法进行模拟. 通过模拟找出平板间受限扩散信号衰减随平板间距变化的规律,并与实际体系比较. 结果表明：平板间n量子相干的自旋回波信号衰减曲线与单量子类似,且其产生同样衍射图样所需的脉冲梯度场强度仅为单量子的1/|n|,可用于测量微小的平板间距. 本文的模拟方法可进一步推广到复杂体系的研究.     

具有残留耦合的分子间和分子内多量子相干及其应用

核磁共振中分子内与分子间多量子相干已得到充分的发展和广泛的使用. 为深入系统地比较研究两种多量子相干的物理机理与性质及其潜在的应用,本文总结近年来相关研究的前沿,首先系统地论述了产生这两种多量子相干的基础－偶极耦合－的作用机理,然后再分别描述基于分子内偶极耦合的分子内多量子相干和基于分子间偶极耦合的分子间多量子相干的原理、性质、及其在化学、生物等领域中的应用.      

基于分子间多量子相干的矢量场磁共振成像模拟

对基于分子间多量子相干的矢量场成像进行了系统的模拟研究. 模拟结果表明：这类成像能够对几十微米量级的异质结构进行成像,并较好地抑制来自均匀介质的信号. 即使不存在梯度磁场情况下,通过相位循环该方法亦可实现对异质结构的成像. 这将有助于开拓基于分子间多量子相干成像的应用领域,深化对其成像机制的理解.     

不均匀场下基于分子间双量子相干核磁共振技术的果肉检测

核磁共振（NMR）谱图可在不破坏生物样品的状态下提供组织成分组成及其含量的信息,已被广泛应用于生物、医学和食品检测等领域.NMR谱图分辨率越高,提供的与组织成分相关的信息越丰富、越准确,也越有利于未知成分的定性和定量分析.传统的高分辨NMR谱图通常要在均匀磁场下采集.但在实际应用中,均匀的磁场较难获得.这就使得我们采集的NMR谱图的分辨率,以及由此获得的生物组织成分组成和含量等信息的准确性受到影响.源于远程偶极相互作用的分子间双量子相干（iDQC）技术对磁场均匀度不敏感,可在不均匀场下获得高分辨率NMR谱图.本文采用基于iDQC技术的IDEAL-Ⅱ序列对甲基丙烯酸丁酯、蕃茄和西瓜三种样品进行了NMR实验,结果证明基于iDQC技术在不均匀场下获得水果的高分辨NMR谱图是可行的,这对食品科学以及食品检测具有积极的意义.     

分子间多量子相干横向弛豫时间(和自扩散系数)测量的参数优化和数据处理方法

针对测量横向弛豫时间T₂的CPMG脉冲序列和我们所设计的可同时测量高极化单组份单 峰核自旋体系n阶分子间多量子相干横向弛豫时间T_2,n和自扩散系数D_n的改进的CRAZED脉冲序列,分析了影响测量T₂、T_2,n（或D_n）的各种因素,并着重从技术方面讨论了准确测量T_2,n和D_n的实验参数优化和实验数据处理方法.     

双Z脉冲实现多量子相干选择检测

本文提出一种改进的多量子相干选择检测(滤波)方法。滤波Z脉冲分别在准备期和混合期末。它能有效地防止单量子相干的"漏进"并避免使用数字相移器。在一般谱仪上容易实现,用密度算符理论对AMX体系进行理论计算,实验结果与理论预期相符。     

非对称自旋-轨道耦合系统的多体量子相干含时演化

本文以具有非对称性自旋相互作用的三体自旋系统为研究对象,重点研究了三体量子相干含时演化规律.采用精确量子对角化和基于量子主方程的数值模拟方法,讨论了三体量子系统中多种量子相干组分及其退相干.研究发现,量子相干组分的含时演化与整个系统的初态量子特性紧密相关.当初态为可分离纯态时,在较短时间内,非对称相互作用有利于增加多体量子相干度.这些量子相干度因受噪声影响而逐渐衰减.当初态为类Werner态时,量子相干度的分布满足加和性,即三体量子相干度等于所有两体量子相干度之和.自旋之间非对称相互作用和环境噪声都会引起三体量子相干度大于所有两体量子相干度之和.这些结论有助于多体量子资源的制备.     

基于碰撞感应激发产生的量子相干效应研究

近年来，量子相干在诸如高灵敏高精度激光光谱和新型量子频标、分子运动和物理化学反应的操控、原子分子激发态结构信息、量子态绝热布居转移、量子计算和量子信息处理等方面具有广泛的应用而受到人们的关注。基于量子干涉效应而产生的量子相干可分为频域和时域内的两种：频域内的量子相干来源于两个或多个同时的不同跃迁路径间的干涉，时域内的量子相干来源于两个或多个具有一定延时的同一跃迁路径间的干涉。本报告对以往较少涉及的原子及原子——分子混合体系中基于非相干碰撞而产生的频域和时域内多能级系统量子相干效应进行研究，并着重探索量子相干产生的条件及其对外界条件的依赖关系等。     

量子环中量子比特的消相干时间

在量子环中电子与体纵光学声子强耦合的情况下,通过求解能量本征方程,得出了电子的基态和第一激发态的本征能量及其波函数,进而以电子-声子体系的基态与第一激发态构造一个量子比特.结果讨论了消相干时间与耦合强度,色散系数以及量子环内径、外径的变化关系.     

多光束相干控制光学跃迁的理论研究

根据量子干涉的基本原理，研究了在多束相干激光场作用下分子或凝聚态体系光学跃迁几率与光场的相位关系，推导了作为相干控制基础的多路径光学跃迁的一般模型及其特殊情形的跃迁几率的关系表达式，归纳了已有的相干控制激发方案，提出的频域的相干控制可用统一的量子理论描述，理论研究的结果表明，对多路径量子跃迁过程，在相干外场的作用下，会引起态的量子干涉，使总跃迁几率的大小随外场的相位变化而改变，这是实现与光学跃迁过     

Separation and characterization of different signals from intermolecular three-spin orders in solution NMR

In this paper, signals originating from a pure specific coherence of intermolecular three-spin orders were separated and characterized experimentally in highly polarized two-component spin systems. A modified CRAZED sequence with selective radio-frequency excitation was designed to separate the small signals from the strong conventional single-spin single-quantum signals. General theoretical expressions of the pulse sequence with arbitrary flip angle pulses were derived using dipolar field treatment. The expressions were used to predict the relaxation and diffusion properties and optimal experimental parameters such as flip angles. For the first time, relaxation and diffusion properties of pure intermolecular single-quantum, double-quantum, and triple-quantum coherences of three-spin orders were characterized and analyzed in one-dimensional experiments. All experimental observations are in excellent agreement with the theoretical predictions. The theoretical results show that the quantum-mechanical treatment leads to exactly the same predictions as the dipolar field treatment. The quantitative study of intermolecular multiple-quantum coherences of three-spin orders presented herein provides a better understanding of their mechanisms.     

Heteronuclear Multiple-Quantum Coherence NMR Spectroscopy of Im-cyt C

Some ¹³C chemical shifts of the CH_n groups in the aliphatic side chains of Im-cyt c have been determined for the first time based on the H chemical shifts of their attached protons with the aid of heteronuclear multiple-quantum coherence (HMQC) spectroscopy. Comparison of chemical shifts of these specifically assigned ¹³C and H resonances from Im-cyt c with those from cyt c indicates that ¹³C-NMR spectra may provide an opportunity to probe the electronic structure and conformational changes induced by axial ligand substitution.     

Quadrupolar and Chemical Shift Tensors Characterized by 2D Multiple-Quantum NMR Spectroscopy

The present work discusses a new 2D NMR method for characterizing the principal values and relative orientations of the electric field gradient and the chemical shift tensors of half-integer quadrupolar sites. The technique exploits the different contributions that quadrupolar and shielding interactions impart on the evolution of multiple-quantum and of single-quantum coherences, in order to obtain 2D powder lineshapes that are highly sensitive to these nuclear spin coupling parameters. Different spinning variants of this experiment were assayed, but it was concluded that a static version can yield the highest sensitivity to the values of the principal components and to the relative geometries of the local coupling tensors. It was found that correlating the central transition evolution with the highest available order of the spin coherence was also helpful for maximizing this spectral information. Good agreement between data obtained on ⁸⁷Rb (S = ) and ⁵⁹Co (S = ) samples and ideal theoretical lineshape predictions of this experiment was obtained, provided that heterogeneities in the multiple-quantum excitation and conversion processes were suitably accounted by procedures similar to those described in the spin- multiple-quantum NMR literature.     

Multiple-quantum magic-angle spinning NMR with cross-polarization: Spectral editing of high-resolution spectra of quadrupolar nuclei

An experiment is presented that combines the multiple-quantum magic-angle spinning (MQMAS) technique with cross-polarization (CP). As a preliminary test of this new method, we measured and compared the ²⁷Al 3QMAS and ¹⁹F → ²⁷A1 CP 3QMAS spectra of a fluorinated AlPO₄ aluminophosphate. Complete discrimination between the fluorinated and nonfluorinated Al sites was easily achieved, which demonstrates the usefulness of CP MQMAS for spectral editing. Future applications of this experiment will include other spin pairs and heteronuclear correlation NMR spectroscopy.     

Diffusion studies in confined nematic liquid crystals by MAS PFG NMR

Pulsed field gradient (PFG) NMR and magic-angle spinning (MAS) NMR have been combined in order to measure the diffusion coefficients of liquid crystals in confined geometry. Combination of MAS NMR with PFG NMR has a higher spectroscopic resolution in comparison with conventional PFG NMR and improves the application of NMR diffusometry to liquid crystals. It is found that the confinement of the liquid crystal 5CB in porous glasses with mean pore diameters of 30 and 200 nm does not notably change its diffusion behavior in comparison with the bulk state.     

Separation of isotropic chemical and second-order quadrupolar shifts by multiple-quantum double rotation NMR

Using a two-dimensional multiple-quantum (MQ) double rotation (DOR) experiment the contributions of the chemical shift and quadrupolar interaction to isotropic resonance shifts can be completely separated. Spectra were acquired using a three-pulse triple-quantum z-filtered pulse sequence and subsequently sheared along both the ν₁ and ν₂ dimensions. The application of this method is demonstrated for both crystalline (RbNO₃) and amorphous samples (vitreous B₂O₃). The existence of the two rubidium isotopes (⁸⁵Rb and ⁸⁷Rb) allows comparison of results for two nuclei with different spins (I = 3/2 and 5/2), as well as different dipole and quadrupole moments in a single chemical compound. Being only limited by homogeneous line broadening and sample crystallinity, linewidths of approximately 0.1 and 0.2 ppm can be measured for ⁸⁷Rb in the quadrupolar and chemical shift dimensions, enabling highly accurate determination of the isotropic chemical shift and the quadrupolar product, P_Q. For vitreous B₂O₃, the use of MQDOR allows the chemical shift and electric field gradient distributions to be directly determined—information that is difficult to obtain otherwise due to the presence of second-order quadrupolar broadening.     

Homogeneous broadenings in 2D solid-state NMR of half-integer quadrupolar nuclei

The question of the homogeneous broadening that occurs in 2D solid-state NMR experiments is examined. This homogeneous broadening is mathematically introduced in a simple way, versus the irreversible decay rates related to the coherences that are involved during t1 and t2. We give the pulse sequences and coherence transfer pathways that are used to measure these decay rates. On AlPO4 berlinite, we have measured the 27Al echo-type relaxation times of the central and satellite transitions on 1Q levels, so that of coherences that are situated on 2Q, 3Q, and 5Q levels. We compare the broadenings that can be deduced from these relaxation times to those directly observed on the isotropic projection of berlinite with multiple-quantum magic-angle spinning (MAS), or satellite-transition MAS. We show that the choice of the high-resolution method, should be done according to the spin value and the corresponding homogeneous broadening.     

Diffusion exchange NMR spectroscopy in inhomogeneous magnetic fields

Two-dimensional diffusion exchange experiments in the presence of a strong, static magnetic field gradient are presented. The experiments are performed in the stray field of a single sided NMR sensor with a proton Larmor frequency of 11.7 MHz. As a consequence of the strong and static magnetic field gradient the magnetization has contributions from different coherence pathways. In order to select the desired coherence pathways, a suitable phase cycling scheme is introduced. The pulse sequence is applied to study diffusion as well as the molecular exchange properties of organic solvents embedded in a mesoporous matrix consisting of a sieve of zeolites with a pore size of 0.8 nm and grain size of 2 μm. This pulse sequence extends the possibilities of the study of transport properties in porous media, with satisfying sensitivity in measurement times of a few hours, in a new generation of relatively inexpensive low-field NMR mobile devices.