Kai Bin Yu scite author profile

Ao ne-dimensional nanotubularm etal-organic framework (MOF) [Ni(Cu-H 4 TPPA)]•2 (CH 3) 2 NH 2 + (H 8 TPPA = 5,10,15,20-tetrakis[p-phenylphosphonic acid] porphyrin) constructed by using the arylphosphonic acid H 8 TPPAi s reported. The structure of this MOF,k nown as GTUB-4, was solved by using single-crystal X-ray diffractiona nd its geometrica ccessible surfacea rea was calculated to be 1102 m 2 g À1 ,m aking it the phosphonate MOF with the highest reporteds urface area. Due to the extended conjugation of its porphyrin core, GTUB-4 possesses narrow indirect and direct bandgaps (1.9 eV and 2.16 eV,r espectively) in the semiconductor regime. Thermogravimetric analysis suggests that GTUB-4 is thermally stable up to 400 8C. Owing to its high surface area, low bandgap, and high thermal stability, GTUB-4 could find applications as electrodes in supercapacitors. Metal-organic frameworks (MOFs) are microporous materials that contain well-defined micropores composed of organic and inorganic surfaces. [1-9] They have been used in applications ranging from gas adsorption, sequestration of greenhouse gases, [10, 11] catalysis, [12, 13] magnetism, [14-17] drug delivery, [18, 19] [c] K.

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Does Confinement Enable Methane Hydrate Growth at Low Pressures? Insights from Molecular Dynamics Simulations

Yazaydın

2020

J. Phys. Chem. C

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Natural methane hydrates are estimated to be the largest source of unexploited hydrocarbon fuel. The ideal conditions for methane hydrate formation are low temperatures and high pressures. On the other hand, recent experimental studies suggest that porous materials, thanks to their confinement effects, can enable methane hydrate formation at milder conditions, although there has not been a consensus on this. A number of studies have investigated methane hydrate growth in confinement by employing molecular simulations; however, these were carried out at either very high pressures or very low temperatures. Therefore, the effects of confinement on methane hydrate growth at milder conditions have not yet been elaborated by molecular simulations. In order to address this, we carried out a systematic study by performing molecular dynamics (MD) simulations of methane water systems. Using a direct phase coexistence approach, microsecond-scale MD simulations in the isobaric−isothermal (NPT) ensemble were performed in order to study the behavior of methane hydrates in the bulk and in confined nanospaces of hydroxylated silica pores at external pressures ranging from 1 to 100 bar and a simulation temperature corresponding to a 2 °C experimental temperature. We validated the combination of the TIP4P/ice water and TraPPE-UA methane models in order to correctly predict the behavior of methane hydrates in accordance to their phase equilibria. We also demonstrated that the dispersion corrections applied to short-range interactions lead to artificially induced hydrate growth. We observed that in the confinement of a hydroxylated silica pore, a convex-shaped methane nanobuble forms, and methane hydrate growth primarily takes place in the center of the pore rather than the surfaces where a thin water layer exists. Most importantly, our study showed that in the nanopores methane hydrate growth can indeed take place at pressures which would be too low for the growth of methane hydrates in the bulk.

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Alkali Phosphonate Metal–Organic Frameworks

Maares

Ayhan

et al. 2019

Chemistry A European J

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An ew family of porousm etal-organic frameworks (MOFs), namely alkali phosphonate MOFs,i sr eported. [Na 2 Cu(H 4 TPPA)]·(NH 2 (CH 3 ) 2 ) 2 (GTUB-1)w as synthesized using the tetratopic 5,10,15,20-tetrakis[p-phenylphosphonic acid] porphyrin (H 8 -TPPA)l inker with planar X-shaped geometrical core. GTUB-1 is composed of rectangular void channels with BET surface area of 697 m 2 g À1 . GTUB-1 exhibits exceptional thermal stability.T he toxicitya nalysis of the (H 8 -TPPA)l inker indicatest hat it is well tolerated by an intestinal cell line, suggesting its suitability for creating phosphonate MOFs for biological applications.[a] M.Supporting information and the ORCID identification number(s) for the author(s) of this articlecan be found under: https://doi.

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A Semiconductive and Microporous One-Dimensional Tubular Metal-Organic Framework

Ayhan¹,

Bayraktar²,

Yu³

et al. 2020

Preprint

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<p>We report the first one-dimensional tubular metal-organic framework (MOF) [Ni(Cu-H6TPPA)]∙2DMA (H8TPPA = 5,10,15,20-tetrakis[p-phenylphosphonic acid] porphyrin) in the literature. The structure of this MOF, known as GTUB4, was solved using single crystal X-ray diffraction and its surface area was calculated to be 1102 m2/g, making it the phosphonate MOF with the highest reported surface area. GTUB4 also possesses a narrow indirect band gap of 1.9 eV and a direct band gap of 2.16 eV, making it a semiconducting MOF. Thermogravimetric analysis of GTUB4 suggests that it is thermally stable up to 400°C. Owing to its high surface area, low band gap, and thermal stability, GTUB4 could find applications as electrodes in supercapacitors.<br></p>

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Diffusion Behavior of Methane in 3D Kerogen Models

Bowers

Loganathan

et al. 2021

Energy Fuels

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As global energy demand increases, natural gas recovery from source rocks is attracting considerable attention since recent development in shale extraction techniques has made the recovery process economically viable. Kerogens are thought to play an important role in gas recovery; however, the interactions between trapped shale gas and kerogens remain poorly understood due to the complex, heterogeneous microporous structure of kerogens. This study examines the diffusive behavior of methane molecules in kerogen matrices of different types (Type I, II, and II) and maturity levels (A to D for Type II kerogens) on a molecular scale. Models of each kerogen type were developed using simulated annealing. We employed grand canonical Monte Carlo simulations to predict the methane loadings of the kerogen models and then used equilibrium molecular dynamics simulations to compute the mean square displacement of methane molecules within the kerogen matrices under reservoir-relevant conditions, that is, 365 K and 275 bar. Our results show that methane self-diffusivity exhibits some degree of anisotropy in all kerogen types examined here except for Type I-A kerogens, where diffusion is the fastest and isotropic diffusion is observed. Self-diffusivity appears to correlate positively with pore volume for Type II kerogens, where an increase in diffusivity is observed with increasing maturity. Swelling of the kerogen matrix up to a 3% volume change is also observed upon methane adsorption. The findings contribute to a better understanding of hydrocarbon transport mechanisms in shale and may lead to further development of extraction techniques, fracturing fluids, and recovery predictions.

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Kai Bin Yu

A Nanotubular Metal–Organic Framework with a Narrow Bandgap from Extended Conjugation**

Does Confinement Enable Methane Hydrate Growth at Low Pressures? Insights from Molecular Dynamics Simulations

Alkali Phosphonate Metal–Organic Frameworks

A Semiconductive and Microporous One-Dimensional Tubular Metal-Organic Framework

Diffusion Behavior of Methane in 3D Kerogen Models

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