Solubility of aminotriethylene glycol functionalized single wall carbon nanotubes: A density functional based tight binding molecular dynamics study

Mananghaya, Michael; Santos, Gil Nonato C.; Yu, Dennis

doi:10.1002/jcc.25776

Cited by 25 publications

(6 citation statements)

References 46 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…BNNTs are indeed not conductive irrespective of their morphological properties, 6,7 whereas CNTs are conductive and show band gap changes with the change in the nanotube diameter size. 8 Several nanostructured h-BN compounds with a lattice characterized by the hexagonal symmetry have been synthesized: nanosheets, 9,10 nanocones, 11 nanotubes, 12 nanohorns, 13 and nanorods 14 as well as several nanostructured objects, collectively named nanoflakes.…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

2019

View full text Add to dashboard Cite

Considering the ever-increasing interest in metal-free materials, some potential chemical applications of quasi-molecular boron nitride (BN) derivatives were tested. Specifically, the behavior of BN fragments was analyzed when given defects, producing local electron density changes, were introduced by using topological engineering approaches. The inserted structural faults were Schottky-like divacancy (BN-d) defects, assembled in the fragment frame by the subtraction of one pair of B and N atoms or Stone–Wales (SW) defects. This study is aimed at highlighting the role of these important classes of defects in BN materials hypothesizing their future use in H2-based processes, related to either (i) H2 activation or (ii) H2 production, from preadsorbed hydrogenated molecular species on BN sites. Here, it has been observed that BN species, embodying SW defects, are characterized by endothermic H2 adsorption and fragmentation phenomena in order to guess their potential use in processes based on the transformation or production of hydrogen. On the contrary, in the presence of BN-d defects, and for reasons strictly related to local structural changes occurring along with the hydrogen rearrangements on the defective BN fragments, a possible use can be inferred. Precautions must be however taken to decrease the material rigidity that could actually decrease the ability of the BN fragment to flatten. This conversely seems to be a necessary requirement to have strong exothermic effects, following the rearrangements of the H2 molecules.

show abstract

Section: Introductionmentioning

confidence: 99%

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

2019

View full text Add to dashboard Cite

show abstract

“…The correlation‐fitting def2‐TZVPP/C auxiliary basis set is used, along with the coulomb‐fitting def2/J basis set, to accelerate the DLPNO‐CCSD(T) calculations. For solvent corrections to coupled cluster electronic energies, the conductor‐like polarized continuum model (CPCM) (dielectric constant = 36.6, refractive index = 1.344 for acetonitrile) [ 26 ] as implemented in ORCA 4.1 [ 27 ] is utilized. Thermal (Temperature = 298.15 K) and nonthermal corrections were obtained from B3LYP frequency calculations.…”

Section: Methodsmentioning

confidence: 99%

Theoretical investigation of an acid catalyst for viable release of H₂ from BN nanotubes: A local pair natural orbital coupled cluster approach

Roy

2020

Int J of Quantum Chemistry

View full text Add to dashboard Cite

Catalytic removal of H2 from boron‐nitride (BN)‐based nanomaterials at ambient conditions is of paramount importance in order to develop lightweight hydrogen storage media. Here, the DLPNO‐CCSD(T) technique is used to calculate accurate relative energies and activation barriers of Brønsted acid‐initiated removal of H2 from hydrogenated BN nanotubes (HBNNTs) with six different acids. Three crucial steps are identified in the mechanism: first H2 release, catalyst regeneration via proton transfer, and second H2 release to ensure feasibility of the dehydrogenation proposal. Our computational studies reveal that sulfonic acids with appropriate electrophilicity can facilitate dehydrogenation of HBNNT at a low free energetic cost (∆G‡ = 17 kcal/mol). Importantly, these findings illustrate the possibility of H2 release from BN nanomaterials at ambient conditions and provides hope for a sustainable chemical hydrogen storage strategy.

show abstract

“…And graphenes with LD are semiconductors with a reduced band gap. , In our previous investigation, the electronic and mechanical properties of graphene with LD consisting of squares and octagons have been predicted . The LD could introduce defective states in the original forbidden band gap. , And the valance band maximum (VBM) and the conduction band minimum (CBM), which are usually relative to the chemical active sites, are also transferred from the edge sites to the LD atoms. − When the TM atoms adsorb on graphene, they intend to adsorb at these defective sites with high chemical active properties of the graphene. − ,, Salmeron found that water could split graphene and intercalates . Cheng investigated single TM atom adsorption on graphene. − Researchers have only recently focused on the single TM atom adsorption on graphene sheet in their work, but the topological, structural, magnetic, and electronic properties of the TM atom adsorption on graphene are still unknown.…”

Section: Introductionmentioning

confidence: 99%

First-Principles Study of 3d Transition-Metal-Atom Adsorption onto Graphene Embedded with the Extended Line Defect

Guan

2020

ACS Omega

View full text Add to dashboard Cite

A type of line defect (LD) composed of alternate squares and octagons (4−8) as the basic unit is currently an experimentally available topological defect in the graphene lattice, which brings some interesting modifications to the magnetic and electronic properties of graphene. The transitional-metal (TM) atoms adsorb on graphene with a line defect (4−8), and they show interesting and attractive structural, magnetic, and electronic properties. For different TMs such as Fe, Co, Mn, Ni, and V, the complex systems show different magnetic and electronic properties. The TM atoms can spontaneously adsorb at quadrangular sites, forming a metallic atomic chain along LD on graphene. The most stable configuration is the hollow site of a regular tangle. The TMs (TM = Co, Fe, Mn, Ni, V) tend to form extended metal lines, showing a ferromagnetic (FM) ground state. For the Co, Fe, and V atoms, the system is half-metal. The spin-α electron is insulating, while the spin-β electron is conductive. For the Mn and Ni atoms, Mn-LD and Ni-LD present a spin-polarized metal; for the Fe atom, Fe-LD shows a semimetal with Dirac cones. For Fe and V atoms, both Fe-LD and V-LD show spin-polarized half-metallic properties. And its spin-α electron is conducting, while the spin-β electron is insulating. Different TMs adsorbing on a graphene nanoribbon forming the same stable configurations of metal lines show different electronic properties. The adsorption of TMs induces magnetism and spin polarization. These metal lines have potential applications in spintronic devices and work as a quasi-one-dimensional metallic wire, which may form building blocks for atomic-scale electrons with well-controlled contacts at the atomic level.

show abstract

Solubility of aminotriethylene glycol functionalized single wall carbon nanotubes: A density functional based tight binding molecular dynamics study

Cited by 25 publications

References 46 publications

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

Theoretical investigation of an acid catalyst for viable release of H₂ from BN nanotubes: A local pair natural orbital coupled cluster approach

First-Principles Study of 3d Transition-Metal-Atom Adsorption onto Graphene Embedded with the Extended Line Defect

Contact Info

Product

Resources

About

Solubility of aminotriethylene glycol functionalized single wall carbon nanotubes: A density functional based tight binding molecular dynamics study

Cited by 25 publications

References 46 publications

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

Hydrogen Arrangements on Defective Quasi-Molecular BN Fragments

Theoretical investigation of an acid catalyst for viable release of H2 from BN nanotubes: A local pair natural orbital coupled cluster approach

First-Principles Study of 3d Transition-Metal-Atom Adsorption onto Graphene Embedded with the Extended Line Defect

Contact Info

Product

Resources

About

Theoretical investigation of an acid catalyst for viable release of H₂ from BN nanotubes: A local pair natural orbital coupled cluster approach