Maressa J. Z. Bradshaw scite author profile

Maressa J. Z. Bradshaw

2Publications

54Citation Statements Received

262Citation Statements Given

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Affiliations

University of Ottawa

Publications

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Chalcogen-Bonded Cocrystals of Substituted Pyridine N-Oxides and Chalcogenodiazoles: An X-ray Diffraction and Solid-State NMR Investigation

Kumar

Bradshaw

et al. 2020

Crystal Growth & Design

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We introduce methyl, methoxy, and phenyl substituents at the para-, meta-, and ortho-positions of pyridine N-oxide to investigate the effect of chemical substitution on the resulting nine chalcogen-bonded structures formed upon cocrystallization with 3,4dicyano-1,2,5-selenodiazole and 3,4-dicyano-1,2,5-telluradiazole. Single-crystal X-ray diffraction studies reveal the presence of double chalcogen bonding interactions in the cocrystals and demonstrate the impact of the substitution on the geometric features of the chalcogen bonds. 77 Se and 125 Te solid-state NMR spectroscopy is employed to measure selenium and tellurium chemical shift tensors of the products, and various trends are described. The smallest component of the 77 Se chemical shift tensor (δ 33 ) provides the strongest correlation with the chalcogen bond distance. Solution NMR provides qualitative evidence for the persistence of the chalcogen bonds in solution. Finally, 1 J( 77 Se, 14 N) coupling constants in 3,4-dicyano-1,2,5-selenodiazole and its chalcogen-bonded cocrystals are measured after accounting for residual dipolar coupling between 77 Se and 14 N; however, changes in 1 J( 77 Se, 14 N) attributable to chalcogen bonding upon cocrystallization are comparable to the experimental uncertainties. This systematic study of chalcogenbonded cocrystals demonstrates the potential utility of the substitution effect for applications of chalcogen bonds in crystal engineering and demonstrates the value of solid-state NMR in characterizing such systems.

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Experimental ¹³C and ¹H Solid-State NMR Response in Weakly Tetrel-Bonded Methyl Groups

et al. 2021

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Like halogens, pnictogens, and chalcogens, group 14 tetrel atoms have the ability to exhibit areas of elevated electrostatic potential on their surfaces (σ-holes) which can engage in noncovalent interactions with electron donors. Evidence for tetrel bonds involving spin-1/2 nuclei, such as 13C, may be found by careful observation of the isotropic chemical shift in solid-state NMR experiments. Here, we study the 13C and 1H solid-state NMR spectroscopic responses to weak tetrel bond formation by examining a series of eight caffeine and theophylline cocrystals along with similar compounds not featuring tetrel bonds. Overall, we observe a moderate increase in the methyl 13C chemical shift on the order of ppm in cocrystals featuring tetrel bonds as compared to their nonbonded counterparts. The value of δ(13C) shows a weak inverse correlation with the tetrel bond length, while no strong correlation with the tetrel bond angle is observed experimentally. Methyl proton chemical shifts are also influenced by the presence of a tetrel bond, but no strong correlations with structural features are noted based on the experimental data. With the aid of DFT calculations, we explore the relationship between the tetrel bond and the 13C chemical shift tensor, furthering our understanding of how tetrel bonds and potentially competing weak CH···O hydrogen bonds affect the NMR response, which is of importance in NMR crystallography applications. While computations generally show clear correlations between chemical shifts and structural features, this experimental work demonstrates that other interactions and crystal packing effects can weaken and even obscure the expected correlations.

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