Temperature calibration for high-temperature MAS NMR to 913 K: 63Cu MAS NMR of CuBr and CuI, and 23Na MAS NMR of NaNbO3

The solid-state phase transitions of CuBr, CuI and NaNbO₃ can be readily observed using ⁶³Cu and ²³Na high-temperature magic-angle spinning nuclear magnetic resonance spectroscopy. Temperature has large, linear effects on the peak maximum of ⁶³Cu in each solid phase of CuBr and CuI, and there is large jump in shift across each phase transition. The ²³Na MAS NMR peak intensities and the line widths in NaNbO₃ also clearly show its high-temperature transition to the cubic phase. These data can be used to calibrate high-temperature MAS NMR probes up to 913 K, which is two hundred degrees higher than the commonly-used temperature calibration based on the chemical shift of ²⁰⁷Pb in Pb(NO₃)₂.     

Molecular reorientation and phase transition in pyridinium hexafluoroantimonate

The temperature dependence of ¹H and ¹⁹F NMR second moment and spin lattice relaxation times in high (v _L = 60 MHz and low (B ₁ = 2 mT) magnetic fields allow one to determine both ion dynamics in polycrystalline pyridinium hexafluoroantimonate. The solid-solid phase transition discovered at 268 K appears to be connected with symmetrization of energy barriers for pseudohexagonal cation reorientation. The energy difference Δ characterizing the inequivalence of the potential wells can be treated as an order parameter. The effect of coupling of the rotational modes of cations and anions is found at the phase transition.     

Solid-State Rb NMR Study in Powdered RbMnCl3

Structural phase transition at 290 K and the implication on the intermediate phase above 290 K in powdered RbMnCl₃ are observed by using a solid-state ⁸⁷Rb NMR spectroscopy. Quadrupole coupling constants (e²qQ/h), the asymmetry parameters (η), and the relative peak intensities for two physically nonequivalent Rb sites, Rb(I) and Rb(II), are determined from nonlinear least-squares fits to the ⁸⁷Rb NMR powder patterns in the temperature range from 260 to 330 K. Quadrupole coupling constants and the asymmetry parameters are examined for the detection of the phase transition resulting in a significant structural change in the Rb(II) site. In addition, changes in the relative peak intensity between the Rb(I) and Rb(II) sites seem to suggest the existence of an anomalous intermediate phase, which is complemented by the differential scanning calorimetry and X-ray diffraction studies.     

Interaction of keratolytic drug,salicylic acid with dipalmitoyl phosphatidylethanolamine vesicles

Salicylic acid (SA), a keratolytic drug, is used to treat skin disorder like corns, warts, and acne. To understand the mechanism by which SA interacts with the cell membranes, we have investigated its interaction with dipalmitoyl phosphatidylethanolamine (DPPE) vesicles using DSC, ¹H NMR and Raman spectroscopy. Presence of drug asymmetrically broadened the acyl chain melting transition and shifted the transition temperature, T _m, to lower value. Both, NMR and DSC studies indicate that the drug molecules are located in the glycerol backbone region of the lipid bilayer and increase the membrane headgroup fluidity. At high drug concentration, additional transitions are observed whose intensity increases with increasing drug concentration. In cholesterol doped DPPE dispersion the interaction of SA with DPPE bilayer is more. The transformation of the gel phase of DPPE dispersion to a stable crystalline subgel phase(s) is accelerated by the presence of SA.     

2H nuclear magnetic resonance study of deuterated water dynamics in perfluorosulfonic acid ionomer Nafion

We have employed deuteron nuclear magnetic resonance (NMR) spectroscopy in order to study the dynamics of the deuterated water (D₂O) molecules introduced into a perfluorosulfonic acid ionomer Nafion (NR-211) film. According to the ²H NMR spectral analysis, the deuterated water molecules at low temperatures occupied either relatively rigid or mobile sites up to the temperature T_M=240 K where all the deuterated water molecules became mobile. The temperature-dependent NMR linewidths sensitively reflected the motional narrowing of the rigid and mobile sites, and the NMR chemical shift reflected significant changes in the hydrogen bonds of the deuterated water. While a slow- to fast-limit motional transition was manifested at T_M in the laboratory-frame NMR spin–lattice relaxation, the rotating-frame spin–lattice relaxation indicated no bulk liquid water state down to 200 K.     

Two-Dimensional Dynamic-Director C NMR of Liquid Crystals

A novel nuclear magnetic resonance (NMR) experiment for facilitating the resolution and assignment of liquid crystalline ¹³C NMR spectra is described. The method involves the motor-driven reorientation of the liquid crystalline director, in synchrony with the acquisition of a 2D chemical shift correlation spectrum. By monitoring in this fashion the ¹³C NMR evolution of spins in the liquid crystal at two different director orientations with respect to the magnetic field, the method distinguishes anisotropic from isotropic displacements and can be utilized for assigning the resonances and estimating local degrees of order. Of various potential pairs of angles suitable for such a correlation, the (0°, 90°) choice was found to be most convenient, as it avoids line broadening complications that may otherwise originate from heterogeneities of the oriented phase. The technique thus derived was employed in the analysis of a series of monomeric and polymeric liquid crystal systems.     

Spin Kinetics of Liquid <Superscript>3</Superscript>He in Contact with a DyF<Subscript>3</Subscript> Micropowder at Ferromagnetic Ordering of Dy<Superscript>3+</Superscript> Ions

The spin kinetics of liquid ³He in contact with a mixture of LaF₃ (99.67%) and DyF₃ (0.33%) micropowders at temperatures of 1.5–3 K has been studied by pulsed nuclear magnetic resonance (NMR). The DyF3 is a dipolar dielectric ferromagnet with the phase transition temperature T_c= 2.55 K, whereas the diamagnetic fluoride LaF₃ is a diluting substance for the optimal observation conditions of ³Не NMR in powder pores. The magnetic phase transition in DyF₃ is accompanied by a considerable change in the character of fluctuations of the magnetic moments of dysprosium ions, which affect the spin kinetics of ³Не in contact with the substrate. Significant changes in the relaxations rates of the longitudinal and transverse magnetizations of 3Не have been discovered in the region of magnetic ordering of the solid matrix. The technique of studying the static and fluctuating magnetic fields of a solid matrix at low temperatures using liquid ³He as a probe has been proposed.     

Dynamic symmetry breaking in kscn: A 39K and 14N NMR study

Abstract

The ³⁹K ½ → ?½ NMR angular rotation patterns in KSCN show no symmetry change on going through T_c . We have directly determined with ¹⁴N NMR the SCN head-tail flipping rate. The results show that the absence of a symmetry change in ³⁹K angular rotation patterns is due to the fact that the time scale for the SCN fluctuations is much longer than the characteristic time scale of this experiment. The same is true for the diffuse neutron scattering data where both above and below T_c the SCN groups appear ordered and static and disorder is restricted to domain boundaries. KSCN thus seems to be the first known example where a structural phase transition can be observed in the slow motion and not in the fast motion regime and where a dynamic breaking of the symmetry of the high temperature phase takes place.     

Design, synthesis and characterization of a linear hydrogen bonded homologous series

A linear hydrogen bonded liquid crystalline homologous series has been synthesized and characterized. Hydrogen bond is formed between p-n-dodecyloxy benzoic acid and various p-n-alkyl benzoic acids whose alkyl chain vary from octyl to ethyl. Synthesized complexes are characterized by FTIR, ¹H NMR and ¹³C NMR studies for inferring the formation of hydrogen bonds. Polarizing Optical Microscopy (POM) and DSC studies reveal various mesophases and their corresponding transition temperatures along with respective enthalpy values. All the seven synthesized complexes exhibit rich liquid crystalline mesomorphism. A new phase namely smectic X has been observed in five of the complexes with a narrow thermal range. This phase has been characterized by optical textural, DSC, tilt angle and helicoidal pitch studies. Smectic X is sandwiched between traditional smectic C and re-entrant smectic C (designated as C_R) phases. Homeotropic transition in nematic phase is observed in all the mesogens and thus these materials can be used as thermally controlled optical shutters. Tilt angle in smectic C, smectic X and smectic C_R phases have been experimentally elucidated for all the mesogens.     

The Na-TiS2 system: A critical discussion of the phase boundaries,structural and NMR studies

We present new evaluations of phase boundaries in the Na_xTiS₂ system from electrochemical intercalation and from X-ray and NMR measurements in samples intercalated using the liquid ammonia technique. After a critical discussion of the influence of the method of intercalation on the phase limits we present an extensive NMR study of the system. ²³Na quadrupolar coupling determinations support the fact that the low concentration (x < 0.25) phase II is a stage 2 phase. ²³Na Knight shift results show that the transition from the Ib trigonal prismatic phase to the Ia trigonal antiprismatic phase with increasing Na concentration takes place with a change in the electronic band structure. The stability of this phase is discussed in terms of the balance between elastic and electronic energies.     

PIC microcontroller based external fast analog to digital converter to acquire wide-lined solid NMR spectra by BRUKER DRX and Avance-I spectrometers

Concerning many former liquid or hybrid liquid/solid NMR consoles, the built in Analog-to-Digital Converters (ADCs) are incapable of digitizing the fids at sampling rates in the MHz range. Regarding both strong anisotropic interactions in the solid state and wide chemical shift dispersion nuclei in solution phase such as ¹⁹⁵Pt, ¹¹⁹Sn, ²⁰⁷Pb etc., the spectrum range of interest might be in the MHz range. As determining the informative tensor components of anisotropic NMR interactions requires nonlinear fitting over the whole spectrum including the asymptotic baseline, it is prohibited by low sampling rates of the ADCs. Wide spectrum width is also useful in solution NMR, since windowing of wide chemical shift ranges is avoidable. We built an external analog to digital converter with 10 MHz maximal sampling rate, which can work simultaneously with the built in ADC of the spectrometer. The ADC was tested on both Bruker DRX and Avance-I NMR consoles. In addition to the analog channels it only requires three external digital lines of the NMR console. The ADC sends data to PC via USB. The whole process is controlled by software written in JAVA which is implemented under TopSpin.     

NMR study of heterogeneity in pyridine-N-oxide...HCl crystal

An origin of narrow ¹H NMR signals in pyridine-N-oxide (PyO)...HCl crystal has been investigated by means of MAS, SPEDAS, NOESY and COSY techniques. Spectra of crystalline samples are compared with those of solid phase obtained from liquid PyO...HCl solutions (in acetonitile/H₂O) after the heterogeneous phase separation. It has been concluded that partially resolved peaks in ¹H NMR spectra of solids are related with heterogeneity of spin system and presence of different H-bond clusters of water molecules. NOESY spectra show no cross-peaks even at very long mixing time (500 ms). This indicates there is no exchange process between spins causing different peaks, and thus the corresponding molecular aggregates are captured in “islands of mobility8 without any channels sufficient for exchange. Appearance of MAS side bands as “pseudo8 cross-peaks in 2D NMR spectra using MAS/COSY technique is reported. In the case of accidental coincidence of spinning frequency (ω _MAS ) with spectral distances between some diagonal signals, intensive non-diagonal peaks are observed at the corresponding cross-positions. A misleading conclusion concerning spin coupling is easy to avoid using various ω _MAS . This work is dedicated to Professor Robert Blinc on the occasion of his 70^th birthday.     

Charge density wave transition in Na2Ti2Sb2O probed by 23Na NMR

Herein we investigated the electronic properties of layered transition-metal oxides Na2Ti2Sb2O by23Na nuclear magnetic resonance(NMR)measurement.The resistivity,susceptibility and specific heat measurements show a phase transition at approximately 114 K(TA).No splitting or broadening in the central line of23Na NMR spectra is observed below and above the transition temperature indicating no internal field being detected.The spin-lattice relaxation rate divided by T(1/T1T)shows a sharp drop at about 110 K which suggests a gap opening behavior.Below the phase transition temperature zone,1/T1T shows Fermi liquid behavior but with much smaller value indicating the loss of large part of electronic density of states(DOS)because of the gap.No signature of the enhancement of spin fluctuations or magnetic order is found with the decreasing temperature.These results suggest a commensurate charge-density-wave(CDW)phase transition occurring.     

Proton Dynamics in Letovicite, (NH4)3H(SO4)2: A H and N NMR Spectroscopic Study

The improper ferroelastic phase letovicite (NH₄)₃H(SO₄)₂ has been studied by ¹H MAS NMR as well as by static ¹⁴N NMR experiments in the temperature range of 296–425 K. The ¹H MAS NMR resonance from ammonium protons can be well distinguished from that of acidic protons. A third resonance appears just below the phase transition temperature which is due to the acidic protons in the paraelastic phase. The lowering of the second moment M₂ for the ammonium protons takes place in the same temperature range as the formation of domain boundaries, while the signals of the acidic protons suffer a line narrowing in the area of T_c. The static ¹⁴N NMR spectra confirm the temperature of the motional changes of the ammonium tetrahedra. Two-dimensional ¹H NOESY spectra indicate a chemical exchange between ammonium protons and the acidic protons of the paraphase.     

低温诱导桑蚕体内腺体相行为的高分辨13C固体核磁共振研究

为什么蚕在常温常压水溶液条件下即能纺出力学性能优异的蚕丝纤维,一直是科学家们感兴趣的问题. 在过去的几十年,人们曾用多种表征手段,如双折射、扫描电镜、原子力显微镜和电子散射等,在界观尺度下对蚕在吐丝过程中腺体的相行为进行研究. 发现腺体在靠近吐丝口时呈液晶态,并认为这是导致蚕丝力学性能的重要因素. 本文则在分子水平尺度下利用核磁共振方法, 对五龄蚕活体在常温和6 ℃下存储数天后解剖的腺体进行研究. 经对化学位移及其线型的各向异性分析发现,当将体内腺体沿吐丝方向分为3部,即后部、中部及靠近吐丝口的前部时,常温下,腺体后部和中后部分子呈无规线团,而腺体中中部、中前部和前部分子呈液晶态. 6 ℃时, 中后部分子亦呈液晶态,前部分子排列则各向异性更大,说明更为有序. 这种液晶态呈分形结构,在小于纳米尺度下为无规线团,大于纳米尺度呈有序排列. 这表明,降温过程可使呈无规线团的丝素蛋白分子转变为液晶态,其效果如同蚕在吐丝过程中对其腺体施加的剪切应力. 该结果对于人们探索人工合成高性能类丝素纤维的纺丝工艺和条件将有启发和指导作用.      

H and C NMR studies of molecular orientation and dynamics in liquid crystal 6BA

The dynamics and orientation of dimers accompanying the formation and destruction of hydrogen bonds in the nematic phases of 4-n-hexylbenzoic acid (6BA) were studied by ¹³C and ²H NMR. The orientational order parameter S in the nematic phase was estimated from the quadrupole splitting of the ²H NMR spectrum. The intermolecular interaction energy for the molecular order in the nematic phase decreased with increasing temperature. The flexibility of dimers due to the destruction of the hydrogen bond is closely related to a decrease in the intermolecular interaction energy. The proportion of ²H NMR spin-lattice relaxation time (T₁) to S, which reveals the coupling of the orientational fluctuations with the hydrogen bonding processes, was observed.     

35Cl NQR and2H NMR analysis of the critical dynamics close to the displacive normal-incommensurate phase transition in an organic crystal

Nuclear magnetic resonance (NMR) experiments,³⁵C1 nuclear quadrupole resonance (NQR) and²H NMR, have been performed close to the displacive normal-incommensurate phase transition in the organic crystal of bis-(4-chlorophenyl)-sulfone. Calculations using coherent neutron scattering results show that the soft-mode contribution cannot explain the rapid increase of the spin-lattice relaxation rates close to the transition temperature. Calculations of the spectral densities taking into account the existence of a central-peak phenomenon describe both³⁵C1 NQR and²H NMR spin-lattice relaxation rates on approaching the phase transition. In this way, the width of the central peak can be estimated to be in the range of several gigahertz.     

High-resolution 31P nuclear magnetic resonance study of phase transitions in TlH2PO4

High-resolution ³¹P nuclear magnetic resonance (NMR) techniques were employed to study a KH₂PO₄-type ferroelectric system, TlH₂PO₄. A marked temperature dependence of the isotropic chemical shift below the ferroelastic phase transition temperature is indicative of an electronic instability. The NMR linewidth showed a discontinuity at the ferroelastic phase transition, and the anisotropy was measured to increase rapidly below the antiferroelectric phase transition. Thus, the changes in the microscopic environments associated with the phase transitions were sensitively reflected in a characteristic manner.     

Influence of salicylic acid on the biophysical properties of dipalmitoyl phosphatidylcholine vesicles

The effect of the keratolytic drug salicylic acid (SA) on the thermotropic behaviour, and dynamics of dipalmitoyl phosphatidyl choline (DPPC)–water/buffer pH?7.4 vesicles was studied using DSC and ¹H NMR. In both systems, incorporation of SA in DPPC bilayer causes a significant depression in the transition temperature of both the pre-transition (PT) and the gel-to-liquid crystalline (CM) transition. The presence of the drug reduces the cooperativity of both the PT and CM transitions. These findings indicate that SA is bound strongly to the lipid bilayer leading to increased membrane fluidity. The DPPC vesicles incorporated with high drug concentration show phase segregation. One of the interesting findings in this study is the formation of a more ordered high temperature gel (L_β2) phase when the SA-doped DPPC dispersion is prepared at physiological pH. The effect of inclusion of cholesterol in the SA-free and SA-doped DPPC dispersion was also studied.     

An NMR Analysis of Transitions in FexNbxV2-2xO4

The first order semiconductor - metall phase transition with the lattice symmetry change from monoclinic to tetragonal and the conductivity jump of several orders of magnitude is observed in pure vanadium dioxide and the dioxide doped by varios impurities [I]. Transition temperature T_t for pure VO₂ is 68°C and depends on the impurity. For example, the impurities which enter the insulating phase as pentavalent ions Nb⁵⁺ [2] give rise to a decrease in metal-semiconductor transition temperature at low concentrations and the trivalent ions Cr³⁺, Fe³⁺ [3,4] lead to an increase in T_t. In the latter case three different monoclinic phases are stabilized at a temperature below T_t. It has been already shown [5] that for double doping of vanadium dioxide by pentavalent Nb⁵⁺ and trivalent Fe³⁺ or Cr³⁺ ions three semiconductor phases exist (M_I, M₂, M₃) but the transition temperature decreases as the impurity concentration increases.