Iuga D, Schäfer H, Verhagen R, Kentgens A P
NWO/CW HF-NMR Facility, NSR Center, Toernooiveld 1, 6525 ED Nijmegen, The Netherlands.
J Magn Reson. 2000 Dec;147(2):192-209. doi: 10.1006/jmre.2000.2192.
We have recently shown that the sensitivity of single- and multiple-quantum NMR experiments of half-integer (N/2) quadrupolar nuclei can be increased significantly by introducing so-called double frequency sweeps (DFS) in various pulse schemes. These sweeps consist of two sidebands generated by an amplitude modulation of the RF carrier. Using a time-dependent amplitude modulation the sidebands can be swept through a certain frequency range. Inspired by the work of Vega and Naor (J. Chem. Phys. 75, 75 (1981)), this is used to manipulate +/-(m - 1) <--> +/-m (3/2 < or = m < or = N/2) satellite transitions in half-integer spin systems simultaneously. For (23)Na (I = 3/2) and (27)Al (I = 5/2) spins in single crystals it proved possible to transfer the populations of the outer +/-m spin levels to the inner +/-1/2 spin levels. A detailed analysis shows that the efficiency of this process is a function of the adiabaticity with which the various spin transitions are passed during the sweep. In powders these sweep parameters have to be optimized to satisfy the appropriate conditions for a maximum of spins in the powder distribution. The effects of sweep rate, sweep range, and RF field strength are investigated both numerically and experimentally. Using a DFS as a preparation period leads to significantly enhanced central transition powder spectra under both static and MAS conditions, compared to single pulse excitation. DFSs prove to be very efficient tools not only for population transfer, but also for coherence transfer. This can be exploited for the multiple- to single-quantum transfer in MQMAS experiments. It is demonstrated, theoretically and experimentally, that DFSs are capable of transferring both quintuple-quantum and triple-quantum coherence into single-quantum coherence in I = 5/2 spin systems. This leads to a significant enhancement in signal-to-noise ratio and strongly reduces the RF power requirement compared to pulsed MQMAS experiments, thus extending their applicability. This is demonstrated by (27)Al 3QMAS experiments on 9Al(2)O(3). 2B(2)O(3) and the mineral andalusite. In the latter compound, Al experiences a quadrupolar-coupling constant of 15.3 MHz in one of the sites. Finally a 5QMAS spectrum on 9Al(2)O(3). 2B(2)O(3) demonstrates the sensitivity enhancement of this experiment using a double frequency sweep.
我们最近表明,通过在各种脉冲序列中引入所谓的双频扫描(DFS),半整数(N/2)四极核的单量子和多量子核磁共振实验的灵敏度可以显著提高。这些扫描由射频载波的幅度调制产生的两个边带组成。使用随时间变化的幅度调制,边带可以扫过一定的频率范围。受Vega和Naor(《化学物理杂志》75, 75 (1981))工作的启发,这被用于同时操纵半整数自旋系统中的±(m - 1) ↔ ±m(3/2 ≤ m ≤ N/2)卫星跃迁。对于单晶中的(23)Na(I = 3/2)和(27)Al(I = 5/2)自旋,已证明有可能将外部±m自旋能级的布居转移到内部±1/2自旋能级。详细分析表明,该过程的效率是扫描期间各种自旋跃迁通过的绝热性的函数。在粉末中,必须优化这些扫描参数以满足粉末分布中最大数量自旋的适当条件。通过数值和实验研究了扫描速率、扫描范围和射频场强的影响。与单脉冲激发相比,在静态和MAS条件下,使用DFS作为制备期会导致中心跃迁粉末光谱显著增强。DFS被证明不仅是用于布居转移的非常有效的工具,而且也是用于相干转移的工具。这可用于MQMAS实验中的多量子到单量子转移。从理论和实验上证明了DFS能够在I = 5/2自旋系统中将五重量子和三重量子相干都转移为单量子相干。与脉冲MQMAS实验相比,这导致信噪比显著提高,并大大降低了射频功率要求,从而扩展了它们的适用性。这通过对9Al(2)O(3). 2B(2)O(3)和矿物红柱石进行的(27)Al 3QMAS实验得到了证明。在后者的化合物中,Al在其中一个位置经历了15.3 MHz的四极耦合常数。最后在9Al(2)O(3). 2B(2)O(3)上的5QMAS光谱展示了使用双频扫描该实验的灵敏度增强。
