A Trigonal Prismatic Cobalt(II) Complex as a Single Molecule Magnet with a Reduced Contribution from Quantum Tunneling

Павлов, А. А.; Aleshin, Dmitry Yu.; Savkina, Svetlana A.; Belov, Alexander S.; Efimov, Nikolay N.; Nehrkorn, Joscha; Ozerov, Mykhaylo; Voloshin, Yan Z.; Nelyubina, Yulia V.; Novikov, Valentin V.

doi:10.1002/cphc.201900219

Cited by 39 publications

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References 55 publications

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“…These dependencies can be reproduced invoking quantum tunneling (B 1 /(1 + B 2 H 2 )), direct (AH n T), Raman (CT m ) and Orbach (τ 0 exp(-Δ/k B T)) relaxation processes (Table S5). The obtained values for the Orbach relaxation barrier (Δ) were significantly smaller than expected from dcmagnetometry and NMR data, which is consistent with the data obtained previously for other Co(II)-based SMMs, where the magnetic relaxation was described using a combination of Raman and direct relaxation pathways with no Orbach contribution, 25,[44][45] or where the Orbach barrier was smaller than predicted by other methods. [46][47][48] In conclusion, two new complexes are presented with Co (II) ions in a trigonal geometry intermediate between TP-TAP that reduces the large magnetic anisotropy observed in complexes with either of both geometries, verifying previously published predictions.…”

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Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation

et al. 2019

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The slow magnetic relaxation of Co(II) in the elusive intermediate geometry between trigonal prism and trigonal antiprism has been studied on the new [Co 2 L 3 ] 4+ and [CoZnL 3 ] 4+ coordination helicates (L is a bispyrazolylpyridine ligand). Solution paramagnetic 1 H-NMR and solid-state magnetization measurements unveil singlemolecule magnet behavior with small axial anisotropy, as predicted previously.

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confidence: 90%

Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation

et al. 2019

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“…Observation and qualitative analysis Following the experimental observation [60] of 1 H and 13 C NMR signals in [ tBu (PNP)Fe-H], our DFT estimates, augmented by contact and pseudocontact terms, predicted a 31 P chemical shift of about À11 000 ppm at room temperature [B3LYP/6-311G(d,p); def2-TZVP (Fe only)], close to where the signal was found experimentally (Figure 2) using 200, 400, and 600 MHz NMR spectrometers. In a 14.1 Tesla magnet, the 31 P NMR resonance was broad and barely visible.…”

Section: Resultsmentioning

confidence: 99%

“…Both factors may be the reason for the small disagreement between calculated and experimental H 12 shift (Figure 5). Calculated 13 C and other 1 H hyperfine tensors were largely unaffected by the spin-orbit coupling effects, which were neglected in the subsequent analysis.…”

Section: Analysis Of Paramagnetic Chemical Shiftsmentioning

confidence: 99%

“…[ 3 , 4 ] At the same time, there is a growing interest in the detection and analysis of paramagnetic intermediates in catalytic reaction cycles, particularly for the first‐row transition metals, where the reactive molecular fragments tend to be either directly bonded, or otherwise in close proximity to the metal. [ 5 , 6 , 7 , 8 , 9 , 10 , 11 ] Other areas of current interest are single‐molecule magnets (SMMs),[ 12 , 13 , 14 , 15 ] contrast agents in magnetic resonance imaging (MRI),[ 16 , 17 , 18 ] and pseudocontact shift (PCS) probes in structural biology. [ 19 , 20 , 21 , 22 ] Several recent studies used magneto‐structural correlations derived by multireference ab initio methods to refine chemical structures using paramagnetic NMR shifts.…”

Section: Introductionmentioning

confidence: 99%

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Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

et al. 2021

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We report an experimental observation of 31 P NMR resonances shifted by over 10 000 ppm (meaning percent range, and a new record for solutions), and similar 1 H chemical shifts, in an intermediate-spin square planar ferrous complex [ tBu (PNP)Fe-H], where PNP is a carbazole-based pincer ligand. Using a combination of electronic structure theory, nuclear magnetic resonance, magnetometry, and terahertz electron paramagnetic resonance, the influence of magnetic anisotropy and zero-field splitting on the paramagnetic shift and relaxation enhancement is investigated. Detailed spin dynamics simulations indicate that, even with relatively slow electron spin relaxation (T 1 % 10 À11 s), it remains possible to observe NMR signals of directly metal-bonded atoms because pronounced rhombicity in the electron zero-field splitting reduces nuclear paramagnetic relaxation enhancement.

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“…[3,4] At the same time, there is a growing interest in the detection and analysis of paramagnetic intermediates in catalytic reaction cycles, particularly for the first-row transition metals, where the reactive molecular fragments tend to be either directly bonded, or otherwise in close proximity to the metal. [5][6][7][8][9][10][11] Other areas of current interest are singlemolecule magnets (SMMs), [12][13][14][15] contrast agents in magnetic resonance imaging (MRI), [16][17][18] and pseudocontact shift (PCS) probes in structural biology. [19][20][21][22] Several recent studies used magneto-structural correlations derived by multireference ab initio methods to refine chemical structures using paramagnetic NMR shifts.…”

Section: Introductionmentioning

confidence: 99%

Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

et al. 2021

Self Cite

View full text Add to dashboard Cite

We report an experimental observation of 31P NMR resonances shifted by over 10 000 ppm (meaning percent range, and a new record for solutions), and similar 1H chemical shifts, in an intermediate‐spin square planar ferrous complex [tBu(PNP)Fe‐H], where PNP is a carbazole‐based pincer ligand. Using a combination of electronic structure theory, nuclear magnetic resonance, magnetometry, and terahertz electron paramagnetic resonance, the influence of magnetic anisotropy and zero‐field splitting on the paramagnetic shift and relaxation enhancement is investigated. Detailed spin dynamics simulations indicate that, even with relatively slow electron spin relaxation (T1 ≈10−11 s), it remains possible to observe NMR signals of directly metal‐bonded atoms because pronounced rhombicity in the electron zero‐field splitting reduces nuclear paramagnetic relaxation enhancement.

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A Trigonal Prismatic Cobalt(II) Complex as a Single Molecule Magnet with a Reduced Contribution from Quantum Tunneling

Cited by 39 publications

References 55 publications

Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation

Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation

Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

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A Trigonal Prismatic Cobalt(II) Complex as a Single Molecule Magnet with a Reduced Contribution from Quantum Tunneling

Cited by 39 publications

References 55 publications

Coordination [CoII2] and [CoIIZnII] Helicates Showing Slow Magnetic Relaxation

Coordination [CoII2] and [CoIIZnII] Helicates Showing Slow Magnetic Relaxation

Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

Observability of Paramagnetic NMR Signals at over 10 000 ppm Chemical Shifts

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Product

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Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation

Coordination [Co^II₂] and [Co^IIZn^II] Helicates Showing Slow Magnetic Relaxation