Constraining Carbon Nanothread Structures by Experimental and Calculated Nuclear Magnetic Resonance Spectra

Wang, Tao; Duan, Pu; Xu, En Shi; Vermilyea, Brian; Chen, Bo; Li, Xiang; Badding, John V.; Schmidt‐Rohr, Klaus; Crespi, Vincent H.

doi:10.1021/acs.nanolett.8b01736

Cited by 32 publications

(42 citation statements)

References 31 publications

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“…The interplanar spacings of the first-order reflections in SAED patterns are 5.7 ± 0.1 Å, which is consistent with the spacings predicted for several candidate degree-6 nanothread structures ( Figures S2-S5), when accounting for thermal expansion and beam-induced dilation of the lattice; these include the structures favored by a detailed solid-state NMR analysis. [26][27] The other reflections in Figure 4a index close to the Figure 1. Nanothread Carbon K-edge Electron Energy−Loss Spectrum.…”

Section: Resultsmentioning

confidence: 63%

Local Structure and Bonding of Carbon Nanothreads Probed by High-Resolution Transmission Electron Microscopy

et al. 2019

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Carbon nanothreads are a new one-dimensional sp 3-bonded nanomaterial of CH stoichiometry synthesized from benzene at high pressure and room temperature by slow solid-state polymerization. The resulting threads assume crystalline packing hundreds of microns across. We show high-resolution electron microscopy (HREM) images of hexagonal arrays of well-aligned thread columns that traverse the 80-100 nm thickness of the prepared sample. Diffuse scattering in electron diffraction reveals that nanothreads are packed with axial and/or azimuthal disregistry between them. Layer lines in diffraction from annealed nanothreads provide the first evidence of translational order along their length, indicating that this solid-state reaction proceeds with some regularity. HREM also reveals bends and defects in nanothread crystals that can contribute to the broadening of their diffraction spots, and electron energy-loss spectroscopy confirms them to be primarily sp 3 hybridized, with less than 27% sp 2 carbon, most likely associated with partially saturated "degree-4" threads.

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Section: Resultsmentioning

confidence: 63%

Local Structure and Bonding of Carbon Nanothreads Probed by High-Resolution Transmission Electron Microscopy

et al. 2019

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“…To date, more than 50 enumerated DNTs with the chemical formula ((CH)6) have been proposed, and some of them have been experimentally synthesized in lab-settings 4,30,31 . As a consequence of unique properties of DNTs, there are attempts to derivatize the DNTs.…”

Section: Atomic Models and Methodologymentioning

confidence: 99%

The effects of morphology and temperature on the tensile characteristics of carbon nitride nanothreads

et al. 2020

Nanoscale

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“…33 It takes advantage of structurally characteristic 13 C and 1 H chemical shifts, which are also amenable to ab initio quantum-chemical simulations. 34 Unlike in vibrational spectra, peak areas in NMR are quantitative if the experiment has been performed appropriately, which means that relative concentrations of different moieties can be determined. Modern NMR involves much more than just taking "the" 13 C NMR spectrum.…”

Section: Introductionmentioning

confidence: 99%

Perfect and Defective 13C-Furan-Derived Nanothreads from Modest-Pressure Synthesis Analyzed by 13C NMR

Matsuura¹,

Huss

zheng³

et al. 2021

Preprint

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13C-enrichment of furan by custom synthesis followed by modest-pressure synthesis of 13C-enriched nanothreads enabled a detailed characterization of the reaction products by a full complement of advanced solid-state NMR techniques, with validation by ab initio calculation of chemical shifts. The 13C NMR spectrum was complex, with more than a dozen distinct features, but almost all (> 95%) represented CH moieties are as expected in nanothreads, with only 2–4% CH2, 0.3% C=O, and 0.3% COO groups, according to spectral editing. Different components were quantified by integration of the fully equilibrated direct-polarization spectrum. Symmetric and asymmetric alkene-containing rings as well as trapped furan were identified by 13C-13C and 1H-13C NMR. The most intriguing component observed was fully saturated perfect anti furan-derived nanothread segments, with two distinct, sharp peaks, accounting for ca. 10% of the material. The bonding patterns in these periodic structures deduced from DQ/SQ NMR was that of a [4+2] cycloaddition product. While the small number of chemically inequivalent carbon sites eliminated low-symmetry syn/anti threads, the large number of magnetically inequivalent ones (i.e., distinct C-H orientations) in CODEX NMR was incompatible with the high-symmetry syn threads. Anti threads with two chemically and eight magnetically inequivalent sites provide the only consistent fit of the experimental data. These conclusions were convincingly corroborated by quantum-chemical simulations, which showed good agreement of isotropic chemical shifts only for the anti threads. This represents the first molecular-level identification of a specific type of nanothread. The typical length of the perfect, fully saturated thread segments was around 14 bonds and they accordingly constitute small clusters (according to 13C and 1H spin diffusion analyses) which likely reside within an overall hexagonal thread packing along with other, less-perfect or less-saturated brethren. The relatively slow T1C relaxation confirms the nanometer-scale length of the periodic perfect structure, indicates that the perfect threads are particularly rigid, and enables their selective observation in 13C NMR.

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Constraining Carbon Nanothread Structures by Experimental and Calculated Nuclear Magnetic Resonance Spectra

Cited by 32 publications

References 31 publications

Local Structure and Bonding of Carbon Nanothreads Probed by High-Resolution Transmission Electron Microscopy

Local Structure and Bonding of Carbon Nanothreads Probed by High-Resolution Transmission Electron Microscopy

The effects of morphology and temperature on the tensile characteristics of carbon nitride nanothreads

Perfect and Defective 13C-Furan-Derived Nanothreads from Modest-Pressure Synthesis Analyzed by 13C NMR

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