Nuclear magnetic resonance spin polarization transfer

To bridge the gap between ideal and practical catalysts, optical spectroscopies, electron spin resonance (ESR), nuclear magnetic resonance (NMR), and Mossbauer spectroscopy can be used. All have been reviewed recently (373, 396), and some examples have been cited earlier (107, 108). Electron spin resonance has been used in several studies of electroorganic reactions (357,371). It can detect short-lived radicals resulting from electron transfer. Recent application of Mossbauer spectroscopy in situ in electrochemical cells deserves mentioning, although it addressed only the anodic polarization and film stability of Co- and Sn-coated electrodes (397,398). Extension to electrocatalytic studies involving Mossbauer nuclides seems feasible. 

We present a solid-state nuclear magnetic resonance (NMR) experiment that allows the observation of a high-resolution two-dimensional heteronuclear correlation (2D HETCOR) spectrum between aluminum and phosphorous in aluminophosphate molecular sieve VPI-5. The experiment uses multiple quantum magic angle spinning (MQMAS) spectroscopy to remove the second order quadrupolar broadening in Al nuclei. The magnetization is then transferred to spin-1/2 nuclei of P via cross polarization (CP) to produce for the first time isotropic resolution in both dimensions. 

Nuclear Overhauser effect (NOE), the transfer of spin polarization from one spin population to another by cross-relaxation in nuclear magnetic resonance spectroscopy. The NOE in, e.g., NOESY spectra can be used to derive distance information between two nuclei in a molecule and, hence, serves as a tool for structure elucidation. 

Nuclear magnetic resonance (NMR) has been applied to the study of homogeneity in miscible polymer blends and has been reviewed by Cheng [11a] and Roland [11b]. When the components of a blend have different Tg s, proton NMR can be used to assess the phase structure of the blend by taking advantage of the rapid decrease of proton-proton coupling with nuclear separation [lie]. For blends containing elastomers of almost identical Tg, proton MAS NMR is applied to blends where one of the components is almost completely deuterated [12], Another technique is crosspolarization MAS NMR [13], The transfer of spin polarization from protons to the atoms of... 

Due to the ALTADENA procedure, nuclear polarization is transferred to all magnetically active nuclei, since all resonance frequencies are virtually the same for all nuclei at the very low magnetic field of the Earth. The corresponding spin systems are of a high order, i.e. the difference in the resonance frequencies between the carbons (i C) and the protons is small, compared with their coupling constants. This is an essential prerequisite for an efficient polarization transfer from protons to a large number of carbons. 

A major limitation for NMR spectroscopy is the intrinsically low sensitivity due to the rather unfavorable Boltzmann distribution for nuclear spins at thermal equilibrium. Thus, considerable effort in magnetic resonance spectroscopy is made towards sensitivity enhancement by hyperpolarization techniques, such as optical polarization, para-hydrogen-induced polarization enhancement, and dynamic nuclear polarization (DNP), a method which exploits the magnetization of unpaired electrons in stable radicals or transition metals to enhance nuclear polarization beyond the Boltzmann limit. In the chapter Dynamic Nuclear Hyperpolarization in Liquids, the fundamental theory for different polarization transfer... 

Electrically-detected magnetic resonance has been used with Si P to sensitively probe nuclear spins with pulsed ENDOR at high and low magnetic fields/ High magnetic fields have been used to polarize Si P electron spins and this has been transferred to nuclear spins with optical excitation and entirely electrically/ As shown in Fig. 1, EDMR has been used to show that strain is useful for tuning Si P resonance frequencies. ... 

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