Search

Your search keyword '"Soundararajan, Murari"' showing total 24 results
Start Over Author "Soundararajan, Murari"
24 results on '"Soundararajan, Murari"'

1. Solid-state $^3\mathrm{He}$ NMR of the superconducting rubidium endofulleride $\mathrm{Rb_3(^3He@C_{60})}$

Author

Soundararajan, Murari, Bacanu, George R., Giustiniano, Francesco, Walkey, Mark C., Hoffman, Gabriela, Carravetta, Marina, Lees, Martin R., Whitby, Richard J., and Levitt, Malcolm H.

Subjects
Condensed Matter - Superconductivity, Physics - Chemical Physics
Abstract

A new variant of the superconducting fulleride $\mathrm{Rb_{3}C_{60}}$ is presented, with $\mathrm{^{3}He}$ atoms encapsulated in the $\mathrm{C_{60}}$ cages. The $\mathrm{^{3}He}$ nuclei act as sensitive NMR probes embedded in the material. The superconducting and normal states are characterised by $\mathrm{^{3}He}$ NMR. Evidence is found for co-existing vortex liquid and vortex solid phases below the superconducting transition temperature. A strong dependence of the spin-lattice relaxation time constant on spectral frequency is observed in the superconducting state, as revealed by two-dimensional NMR utilising an inverse Laplace transform. Surprisingly, this phenomenon persists, in attenuated form, at temperatures well above the superconducting transition., Comment: 20 pages, 15 figures

Published
2023

2. The $^{103}$Rh NMR Spectroscopy and Relaxometry of the Rhodium Formate Paddlewheel Complex

Author

Collins, Harry Harbor, Sabba, Mohamed, Moustafa, Gamal, Legrady, Bonifac, Soundararajan, Murari, Leutzsch, Markus, and Levitt, Malcolm H.

Subjects
Physics - Chemical Physics, Quantum Physics
Abstract

The NMR spectroscopy of spin-1/2 nuclei with low gyromagnetic ratio is challenging, due to the low NMR signal strength. Methodology for the rapid acquisition of $^{103}$Rh NMR parameters is demonstrated for the case of the rhodium formate "paddlewheel" complex $\mathrm{Rh_2(HCO_2)_4}$. A scheme is described for enhancing the $^{103}$Rh signal strength by polarization transfer from $^{1}$H nuclei and which also greatly reduces the interference from ringing artifacts, a common hurdle for the direct observation of low-$\gamma$ nuclei. The $^{103}$Rh relaxation time constants $T_1$ and $T_2$ are measured within 20 minutes using $^{1}$H-detected experiments. The field-dependence of the $^{103}$Rh $T_1$ is measured. The high-field relaxation is dominated by the chemical shift anisotropy (CSA) mechanism. The $^{103}$Rh shielding anisotropy is found to be very large: $|\Delta\sigma|=9900\pm540\mathrm{\,ppm}$. This estimate is compared with density functional theory calculations., Comment: submitted to JCP

Published
2023

3. Squeezing formaldehyde into C60 fullerene

Author

Vyas, Vijyesh K., Bacanu, George R., Soundararajan, Murari, Marsden, Elizabeth S., Jafari, Tanzeeha, Shugai, Anna, Light, Mark E., Nagel, Urmas, Rõõm, Toomas, Levitt, Malcolm H., and Whitby, Richard J.

Published
2024
Full Text
View/download PDF

5. High-field solution state DNP using cross-correlations

Author

Concilio, Maria Grazia, Soundararajan, Murari, Frydman, Lucio, and Kuprov, Ilya

Subjects
Quantum Physics, Physics - Chemical Physics
Abstract

At the magnetic fields of common NMR instruments, electron Zeeman frequencies are too high for efficient electron-nuclear dipolar cross-relaxation to occur in solution. The rate of that process fades with the electron Zeeman frequency as omega^{-2} - in the absence of isotropic hyperfine couplings, liquid state dynamic nuclear polarisation (DNP) in high-field magnets is therefore impractical. However, contact coupling and dipolar cross-relaxation are not the only mechanisms that can move electron magnetisation to nuclei in liquids: multiple cross-correlated (CC) relaxation processes also exist, involving various combinations of interaction tensor anisotropies. The rates of some of those processes have more favourable high-field behaviour than dipolar cross-relaxation, but due to the difficulty of their numerical - and particularly analytical - treatment, they remain largely uncharted. In this communication, we report analytical evaluation of every rotationally driven relaxation process in liquid state for 1e1n and 2e1n spin systems, as well as numerical optimisations of the steady-state DNP with respect to spin Hamiltonian parameters. A previously unreported cross-correlation DNP (CCDNP) mechanism was identified for the 2e1n system, involving multiple relaxation interference effects and inter-electron exchange coupling. Using simulations, we found realistic spin Hamiltonian parameters that yield stronger nuclear polarisation at high magnetic fields than dipolar cross-relaxation.

Published
2020
Full Text
View/download PDF

7. The 103Rh NMR spectroscopy and relaxometry of the rhodium formate paddlewheel complex.

Author

Harbor-Collins, Harry, Sabba, Mohamed, Moustafa, Gamal, Legrady, Bonifac, Soundararajan, Murari, Leutzsch, Markus, and Levitt, Malcolm H.

Subjects
RHODIUM, GYROMAGNETIC ratio, NUCLEAR magnetic resonance, NUCLEAR magnetic resonance spectroscopy, DENSITY functional theory
Abstract

The nuclear magnetic resonance (NMR) spectroscopy of spin-1/2 nuclei with low gyromagnetic ratio is challenging due to the low NMR signal strength. Methodology for the rapid acquisition of 103Rh NMR parameters is demonstrated for the case of the rhodium formate "paddlewheel" complex R h 2 (H C O 2 ) 4 . A scheme is described for enhancing the 103Rh signal strength by polarization transfer from 1H nuclei, which also greatly reduces the interference from ringing artifacts, a common hurdle for the direct observation of low-γ nuclei. The 103Rh relaxation time constants T1 and T2 are measured within 20 min by using 1H-detected experiments. The field dependence of the 103Rh T1 is measured. The high-field relaxation is dominated by the chemical shift anisotropy mechanism. The 103Rh shielding anisotropy is found to be very large: |Δσ| = 9900 ± 540 ppm. This estimate is compared with density functional theory calculations. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

8. Enormous sample scale-up from nanoliter to microliter in high field liquid state dynamic nuclear polarization

Author

Yoon, Dongyoung, Dimitriadis, Alexandros I., Soundararajan, Murari, Caspers, Christian, Genoud, Jeremy, Alberti, Stefano, de Rijk, Emile, and Ansermet, Jean-Philippe

Subjects
Physics - Applied Physics
Abstract

Dynamic nuclear polarization (DNP) enhances nuclear magnetic resonance (NMR) signals by transferring electron spin polarization to nuclei. As DNP requires microwave magnetic fields B1 strong enough to saturate electron spins, microwave resonators are generally used to achieve a sufficient B1, at the expense of restricting the sample size. Higher fields improve NMR sensitivity and resolution. However, resonators at 9 T for example can only hold nano-liters (nL). Larger volumes are possible by avoiding resonators, but the higher power needed to reach B1 is likely to evaporate the sample. Here, we demonstrate a breakthrough in liquid state DNP at 9 T, boosting the sample size to the microliter range. We could use high-power (70 W) microwaves thanks to a planar probe designed to alleviate dielectric heating. We enhanced the 1H NMR signal intensity of 2 uL of liquid water by a factor of 14, while maintaining the water temperature below 40 degree Celsius.

Published
2017

12. Squeezing formaldehyde into C60 fullerene.

Author

Vyas, Vijyesh K., Bacanu, George R., Soundararajan, Murari, Marsden, Elizabeth S., Jafari, Tanzeeha, Shugai, Anna, Light, Mark E., Nagel, Urmas, Rõõm, Toomas, Levitt, Malcolm H., and Whitby, Richard J.

Abstract

The cavity inside fullerene C60 provides a highly symmetric and inert environment for housing atoms and small molecules. Here we report the encapsulation of formaldehyde inside C60 by molecular surgery, yielding the supermolecular complex CH2O@C60, despite the 4.4 Å van der Waals length of CH2O exceeding the 3.7 Å internal diameter of C60. The presence of CH2O significantly reduces the cage HOMO-LUMO gap. Nuclear spin-spin couplings are observed between the fullerene host and the formaldehyde guest. The rapid spin-lattice relaxation of the formaldehyde 13C nuclei is attributed to a dominant spin-rotation mechanism. Despite being squeezed so tightly, the encapsulated formaldehyde molecules rotate freely about their long axes even at cryogenic temperatures, allowing observation of the ortho-to-para spin isomer conversion by infrared spectroscopy. The particle in a box nature of the system is demonstrated by the observation of two quantised translational modes in the cryogenic THz spectra.The interconversion of the two spin isomers of formaldehyd has been studied in the gas phase but has never been observed experimentally in the condensed phase. Here the authors report the encapsulation of formaldehyde inside C60 cages and observe spin-isomer conversion of the formaldehyde guest molecules in the cryogenic solid state. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

13. Solid-State 3He NMR of the Superconducting Rubidium Endofulleride Rb3(3He@C60).

Author

Soundararajan, Murari, Bacanu, George R., Giustiniano, Francesco, Walkey, Mark C., Hoffman, Gabriela, Carravetta, Marina, Lees, Martin R., Whitby, Richard J., and Levitt, Malcolm H.

Abstract

A new variant of the superconducting fulleride Rb 3 C 60 is presented, with 3 He atoms encapsulated in the C 60 cages. The 3 He nuclei act as sensitive NMR probes embedded in the material. The superconducting and normal states are characterized by 3 He NMR. Evidence is found for coexisting vortex liquid and vortex solid phases below the superconducting transition temperature. A strong dependence of the spin–lattice relaxation time constant on spectral frequency is observed in the superconducting state, as revealed by two-dimensional NMR utilizing an inverse Laplace transform. Surprisingly, this phenomenon persists, in attenuated form, at temperatures well above the superconducting transition. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

17. High‐field solution state DNP using cross‐correlations

Author

Concilio, Maria G, Soundararajan, Murari, Frydman, Lucio, and Kuprov, Ilya

Abstract

At the magnetic fields of common NMR instruments, electron Zeeman frequencies are too high for efficient electron-nuclear dipolar cross-relaxation to occur in solution. The rate of that process fades with the electron Zeeman frequency as ω -2 – in the absence of isotropic hyperfine couplings, liquid state dynamic nuclear polarisation (DNP) in high-field magnets is therefore impractical. However, contact coupling and dipolar cross-relaxation are not the only mechanisms that can move electron magnetisation to nuclei in liquids: multiple cross-correlated (CC) relaxation processes also exist, involving various combinations of interaction tensor anisotropies. The rates of some of those processes have more favourable high-field behaviour than dipolar cross-relaxation, but due to the difficulty of their numerical – and particularly analytical – treatment, they remain largely uncharted. In this communication, we report analytical evaluation of every rotationally driven relaxation process in liquid state for 1e1n and 2e1n spin systems, as well as numerical optimisations of the steady-state DNP with respect to spin Hamiltonian parameters. A previously unreported cross-correlated DNP (CCDNP) mechanism was identified for the 2e1n system, involving multiple relaxation interference effects and inter-electron exchange coupling. Using simulations, we found realistic spin Hamiltonian parameters that yield stronger nuclear polarisation at high magnetic fields than dipolar cross-relaxation.

Published
2021

24. Development and characterisation of gyrotron-based Dynamic Nuclear Polarisation and Electron Paramagnetic Resonance spectroscopy at 9 Tesla

Author

Soundararajan, Murari and Ansermet, Jean-Philippe

Subjects
Gyrotron based DNP, DNP-NMR, High-field EPR, Titanium dioxide, Hyperpolarisation, Tunable gyrotrons
Abstract

The Dynamic nuclear polarisation (DNP) enhanced nuclear magnetic resonance (NMR) results presented in this thesis demonstrate the functionality of a tunable and switchable gyrotron operating at 260 GHz with a 9 T spectrometer. This gyrotron was designed at the Swiss Plasma Center. Millimeter wave passive components were built by the startup company SwissTo12. Monochromatic as well as frequency swept cross effect DNP experiments validate the basic functioning and frequency tunability of the gyrotron. High power operation is tested on systems exhibiting the Overhauser and solid effects with the aid of a novel planar probe designed to mitigate dielectric heating. Microwave polarisation control using a Matching Optics Unit is verified using cross effect DNP. Continuous wave electron paramagnetic resonance (EPR) measurements performed on a home built quasi-optical spectrometer operating at 260 GHz on the same sample space as the NMR spectrometer are also presented. EPR spectra of hyperpolarising agents measured on this spectrometer are used to prepare for and subsequently analyse the DNP experiments. Preliminary studies on surface modified titanium dioxide nanopowders using EPR at 9 GHz, displaying significant g-factor shifts are reported.

Catalog

Books, media, physical & digital resources
See catalog results