Jianying Cui scite author profile

The ability of solid-state 13 C NMR to detect and quantify small amounts of sp 2 -hybridized carbon on the surface of ∼5 nm diameter nanodiamond particles is demonstrated. The CC carbon fraction is only 1.1 ± 0.4% in pristine purified detonation nanodiamond, while a full single-layer graphitic or "bucky diamond" shell would contain ca. 25% of all C in a 5 nm diameter particle. Instead of large aromatic patches repeatedly proposed in the recent literature, sp 3 -hybridized CH and COH carbons cover most of the nanodiamond particle surface, accounting for ∼5% each. CO and COO groups also seen in X-ray absorption near-edge structure spectroscopy (XANES) but not detected in previous NMR studies make up ca. 1.5% of all C. They are removed by heat treatment at 800 °C, which increases the aromatic fraction. 13 C{ 1 H} NMR demonstrates that the various sp 2 -hybridized carbons are mostly not protonated, but cross-polarization shows that they are separated from 1 H by only a few bond lengths, which proves that they are near the protonated surface. Together, the observed C−H, C−OH, CO, and CC groups account for 12−14% of all C, which matches the surface fraction expected for bulkterminated 5 nm diameter diamond particles.

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Magnetic fluctuations and superconducting properties of CaKFe4As4 studied by As75 NMR

Cui

Ding

Meier

et al. 2017

Phys. Rev. B

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We report 75 As nuclear magnetic resonance (NMR) studies on a new iron-based superconductor CaKFe4As4 with Tc = 35 K. 75 As NMR spectra show two distinct lines corresponding to the As(1) and As(2) sites close to the K and Ca layers, respectively, revealing that K and Ca layers are well ordered without site inversions. We found that nuclear quadrupole frequencies νQ of the As(1) and As(2) sites show an opposite temperature (T ) dependence. Nearly T independent behavior of the Knight shifts K are observed in the normal state, and a sudden decrease in K in the superconducting (SC) state suggests spin-singlet Cooper pairs. 75 As spin-lattice relaxation rates 1/T1 show a power law T dependence with different exponents for the two As sites. The isotropic antiferromagnetic spin fluctuations characterized by the wavevector q = (π, 0) or (0, π) in the single-iron Brillouin zone notation are revealed by 1/T1T and K measurements. Such magnetic fluctuations are necessary to explain the observed temperature dependence of the 75 As quadrupole frequencies, as evidenced by our first-principles calculations. In the SC state, 1/T1 shows a rapid decrease below Tc without a Hebel-Slichter peak and decreases exponentially at low T , consistent with an s ± nodeless two-gap superconductor.PACS numbers:

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Thermal stability of MnBi magnetic materials

Cui

Choi

et al. 2014

J. Phys.: Condens. Matter

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MnBi has attracted much attention in recent years due to its potential as a rare-earth-free permanent magnet material. It is unique because its coercivity increases with increasing temperature, which makes it a good hard phase material for exchange coupling nanocomposite magnets. MnBi phase is difficult to obtain, partly because the reaction between Mn and Bi is peritectic, and partly because Mn reacts readily with oxygen. MnO formation is irreversible and harmful to magnet performance. In this paper, we report our efforts toward developing MnBi permanent magnets. To date, high purity MnBi (>90%) can be routinely produced in large quantities. The produced powder exhibits 74.6?emu?g?1 saturation magnetization at room temperature with 9?T applied field. After proper alignment, the maximum energy product (BH)max of the powder reached 11.9?MGOe, and that of the sintered bulk magnet reached 7.8?MGOe at room temperature. A comprehensive study of thermal stability shows that MnBi powder is stable up to 473?K in air. RightsWorks produced by employees of the U.S. Government as part of their official duties are not copyrighted within the U.S. The content of this document is not copyrighted. AbstractMnBi has attracted much attention in recent years due to its potential as a rare-earth-free permanent magnet material. It is unique because its coercivity increases with increasing temperature, which makes it a good hard phase material for exchange coupling nanocomposite magnets. MnBi phase is difficult to obtain, partly because the reaction between Mn and Bi is peritectic, and partly because Mn reacts readily with oxygen. MnO formation is irreversible and harmful to magnet performance. In this paper, we report our efforts toward developing MnBi permanent magnets. To date, high purity MnBi (>90%) can be routinely produced in large quantities. The produced powder exhibits 74.6 emu g −1 saturation magnetization at room temperature with 9 T applied field. After proper alignment, the maximum energy product (BH) max of the powder reached 11.9 MGOe, and that of the sintered bulk magnet reached 7.8 MGOe at room temperature. A comprehensive study of thermal stability shows that MnBi powder is stable up to 473 K in air.

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Jianying Cui

Quantification of C═C and C═O Surface Carbons in Detonation Nanodiamond by NMR

Magnetic fluctuations and superconducting properties of CaKFe4As4 studied by As75 NMR

Thermal stability of MnBi magnetic materials

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