Your search keyword '"Anthony J. Horsewill"' showing total 7 results

1. Radical-induced hetero-nuclear mixing and low-field

Author

Hana, Kouřilová, Michael, Jurkutat, David, Peat, Karel, Kouřil, Alixander S, Khan, Anthony J, Horsewill, James F, MacDonald, John, Owers-Bradley, and Benno, Meier

Abstract

Radicals serve as a source of polarization in dynamic nuclear polarization, but may also act as polarization sink, in particular at low field. Additionally, if the couplings between the electron spins and different nuclear reservoirs are stronger than any of the reservoirs' couplings to the lattice, radicals can mediate hetero-nuclear polarization transfer. Here, we report radical-enhanced

Published

2022

2. Experimental, theoretical and computational investigation of the inelastic neutron scattering spectrum of a homonuclear diatomic molecule in a nearly spherical trap: H

Author

Salvatore, Mamone, Mónica, Jiménez-Ruiz, Mark R, Johnson, Stéphane, Rols, and Anthony J, Horsewill

Abstract

In this paper we report a methodology for calculating the inelastic neutron scattering spectrum of homonuclear diatomic molecules confined within nano-cavities of spherical symmetry. The method is based on the expansion of the confining potential into multipoles of the coupled rotational and translational angular variables. The Hamiltonian and the INS transition probabilities are evaluated analytically. The method affords a fast and computationally inexpensive way to simulate the inelastic neutron scattering spectrum of molecular hydrogen confined in fullerene cages. The potential energy surface is effectively parametrized in terms of few physical parameters comprising an harmonic term, anharmonic corrections and translation-rotation couplings. The parameters are refined by matching the simulations against the experiments and the excitation modes are identified for transfer energies up to 215 meV.

Published

2016

3. Low-field thermal mixing in [1-(13)C] pyruvic acid for brute-force hyperpolarization

Author

John Owers-Bradley, James G. Kempf, Anthony J. Horsewill, Matthew L. Hirsch, David T. Peat, and David G. Gadian

Subjects

Zeeman effect, Proton, Annealing (metallurgy), Chemistry, Analytical chemistry, Time constant, General Physics and Astronomy, Carbon-13 NMR, 010402 general chemistry, Polarization (waves), 01 natural sciences, 030218 nuclear medicine & medical imaging, 0104 chemical sciences, 03 medical and health sciences, Dipole, symbols.namesake, 0302 clinical medicine, symbols, Hyperpolarization (physics), Physical and Theoretical Chemistry

Abstract

We detail the process of low-field thermal mixing (LFTM) between (1)H and (13)C nuclei in neat [1-(13)C] pyruvic acid at cryogenic temperatures (4-15 K). Using fast-field-cycling NMR, (1)H nuclei in the molecule were polarized at modest high field (2 T) and then equilibrated with (13)C nuclei by fast cycling (∼300-400 ms) to a low field (0-300 G) that activates thermal mixing. The (13)C NMR spectrum was recorded after fast cycling back to 2 T. The (13)C signal derives from (1)H polarization via LFTM, in which the polarized ('cold') proton bath contacts the unpolarised ('hot') (13)C bath at a field so low that Zeeman and dipolar interactions are similar-sized and fluctuations in the latter drive (1)H-(13)C equilibration. By varying mixing time (tmix) and field (Bmix), we determined field-dependent rates of polarization transfer (1/τ) and decay (1/T1m) during mixing. This defines conditions for effective mixing, as utilized in 'brute-force' hyperpolarization of low-γ nuclei like (13)C using Boltzmann polarization from nearby protons. For neat pyruvic acid, near-optimum mixing occurs for tmix∼ 100-300 ms and Bmix∼ 30-60 G. Three forms of frozen neat pyruvic acid were tested: two glassy samples, (one well-deoxygenated, the other O2-exposed) and one sample pre-treated by annealing (also well-deoxygenated). Both annealing and the presence of O2 are known to dramatically alter high-field longitudinal relaxation (T1) of (1)H and (13)C (up to 10(2)-10(3)-fold effects). Here, we found smaller, but still critical factors of ∼(2-5)× on both τ and T1m. Annealed, well-deoxygenated samples exhibit the longest time constants, e.g., τ∼ 30-70 ms and T1m∼ 1-20 s, each growing vs. Bmix. Mixing 'turns off' for Bmix∼100 G. That T1m≫τ is consistent with earlier success with polarization transfer from (1)H to (13)C by LFTM.

Published

2016

4. Symmetry-breaking in the endofullerene H₂O@C6₆₀ revealed in the quantum dynamics of ortho and para-water: a neutron scattering investigation

Author

Kelvin S K, Goh, Mónica, Jiménez-Ruiz, Mark R, Johnson, Stéphane, Rols, Jacques, Ollivier, Mark S, Denning, Salvatore, Mamone, Malcolm H, Levitt, Xuegong, Lei, Yongjun, Li, Nicholas J, Turro, Yasujiro, Murata, and Anthony J, Horsewill

Abstract

Inelastic neutron scattering (INS) has been employed to investigate the quantum dynamics of water molecules permanently entrapped inside the cages of C60 fullerene molecules. This study of the supramolecular complex, H2O@C60, provides the unique opportunity to study isolated water molecules in a highly symmetric environment. Free from strong interactions, the water molecule has a high degree of rotational freedom enabling its nuclear spin isomers, ortho-H2O and para-H2O to be separately identified and studied. The INS technique mediates transitions between the ortho and para spin isomers and using three INS spectrometers, the rotational levels of H2O have been investigated, correlating well with the known levels in gaseous water. The slow process of nuclear spin conversion between ortho-H2O and para-H2O is revealed in the time dependence of the INS peak intensities over periods of many hours. Of particular interest to this study is the observed splitting of the ground state of ortho-H2O, raising the three-fold degeneracy into two states with degeneracy 2 and 1 respectively. This is attributed to a symmetry-breaking interaction of the water environment.

Published

2014

5. High polarization of nuclear spins mediated by nanoparticles at millikelvin temperatures

Author

John Owers-Bradley, David G. Gadian, David T. Peat, Kelvin S. K. Goh, and Anthony J. Horsewill

Subjects

Carbon Isotopes, Magnetic Resonance Spectroscopy, Spins, Oxide, Temperature, General Physics and Astronomy, chemistry.chemical_element, Nanoparticle, Metal Nanoparticles, Polarization (waves), Copper, Magnetic field, chemistry.chemical_compound, Nuclear magnetic resonance, Magnetic Fields, chemistry, Chemical physics, Hyperpolarization (physics), Physical and Theoretical Chemistry, Insensitive nuclei enhanced by polarization transfer, Aluminum

Abstract

Nuclear magnetic resonance (NMR) techniques are extensively used in many areas of basic and clinical research, as well as in diagnostic medicine. However, NMR signals are intrinsically weak, and this imposes substantial constraints on the amounts and concentrations of materials that can be detected. The signals are weak because of the low energies characteristic of NMR and the resulting very low (typically 0.0001-0.01%) polarization of the nuclear spins. Here, we show that exposure to very low temperatures and high magnetic fields, in conjunction with nanoparticle-mediated relaxation enhancement, can be used to generate extremely high nuclear polarization levels on a realistic timescale; with copper nanoparticles at 15 mK and 14 T, (13)C polarization grew towards its equilibrium level of 23% with an estimated half-time of about 60 hours. This contrasts with a (13)C half-time of at least one year in the presence of aluminium nanoparticles. Cupric oxide nanoparticles were also effective relaxation agents. Our findings lead us to suspect that the relaxation may be mediated, at least in part, by the remarkable magnetic properties that some nanoparticle preparations can display. This methodology offers prospects for achieving polarization levels of 10-50% or more for many nuclear species, with a wide range of potential applications in structural biology and medicine.

Published

2013

6. Achievement of high nuclear spin polarization using lanthanides as low-temperature NMR relaxation agents

Author

Angel J. Perez Linde, Anthony J. Horsewill, Walter Köckenberger, David G. Gadian, David T. Peat, and John Owers-Bradley

Subjects

Thermal equilibrium, Magnetic Resonance Spectroscopy, Chemistry, Gadolinium, Relaxation (NMR), Analytical chemistry, Temperature, General Physics and Astronomy, chemistry.chemical_element, Pentetic Acid, Reference Standards, Lanthanoid Series Elements, Boltzmann distribution, Ion, Solid-state nuclear magnetic resonance, Chemical physics, Dysprosium, Physical and Theoretical Chemistry, Holmium

Abstract

Many approaches are now available for achieving high levels of nuclear spin polarization. One of these methods is based on the notion that as the temperature is reduced, the equilibrium nuclear polarization will increase, according to the Boltzmann distribution. The main problem with this approach is the length of time it may take to approach thermal equilibrium at low temperatures, since nuclear relaxation times (characterized by the spin-lattice relaxation time T1) can become very long. Here, we show, by means of relaxation time measurements of frozen solutions, that selected lanthanide ions, in the form of their chelates with DTPA, can act as effective relaxation agents at low temperatures. Differential effects are seen with the different lanthanides that were tested, holmium and dysprosium showing highest relaxivity, while gadolinium is ineffective at temperatures of 20 K and below. These observations are consistent with the known electron-spin relaxation time characteristics of these lanthanides. The maximum relaxivity occurs at around 10 K for Ho-DTPA and 20 K for Dy-DTPA. Moreover, these two agents show only modest relaxivity at room temperature, and can thus be regarded as relaxation switches. We conclude that these agents can speed up solid state NMR experiments by reducing the T1 values of the relevant nuclei, and hence increasing the rate at which data can be acquired. They could also be of value in the context of a simple low-cost method of achieving several-hundred-fold improvements in polarization for experiments in which samples are pre-polarized at low temperatures, then rewarmed and dissolved immediately prior to analysis.

Published

2013

7. A dedicated spectrometer for dissolution DNP NMR spectroscopy

Author

Walter Köckenberger, Josef Granwehr, James Leggett, Robert I. Hunter, Graham Smith, Jonathan McMaster, Angel J. Perez-Linde, Anthony J. Horsewill, and Rafal Panek

Subjects

Liquid state, Spectrometer, Chemistry, Magnet, Dynamic nuclear polarisation, Analytical chemistry, General Physics and Astronomy, Nuclear magnetic resonance spectroscopy, Physical and Theoretical Chemistry, Atomic physics, Spin (physics), Spectroscopy, Dissolution

Abstract

Using low temperature dynamic nuclear polarisation (DNP) in conjunction with dissolution makes it possible to generate highly polarised nuclear spin systems for liquid state applications of nuclear magnetic resonance spectroscopy. However, in its current implementation, which requires the transfer of the solute between two different magnets, the hyperpolarisation strategy is limited to spin systems with relatively long longitudinal relaxation time constants. Here we describe the design and construction of a dedicated spectrometer for DNP applications that is based on a magnet with two isocentres. DNP enhancement is carried out in the upper compartment of this magnet in a low temperature environment at 3.35 T, while a 9.4 T isocentre in the lower compartment is used for high resolution NMR spectroscopy. The close proximity (85 cm) of the two isocentres makes it possible to transfer the sample in the solid state with very little loss of spin polarisation. In first performance tests this novel experimental set-up proved to be superior to the strategy involving two separate magnets.

Published

2010