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Adsorption

Erschienen in:

26.09.2018

NBO, AIM, HOMO–LUMO and thermodynamic investigation of the nitrate ion adsorption on the surface of pristine, Al and Ga doped BNNTs: A DFT study

verfasst von: M. Rezaei-Sameti, P. Zarei

Erschienen in: Adsorption | Ausgabe 8/2018

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Abstract

A density function theory (DFT) is applied to investigate the interaction and adsorption of nitrate ion on the exterior and interior surface of the pristine, Al and Ga-doped BNNTs. The calculated results indicate that the values of adsorption energy and enthalpy of the NO₃⁻@ Al-doped BNNTs complex is more negative than pristine and Ga-doped. The adsorption energy nitrate ion on the surface of BNNTs is in order Al-doped > Ga-doped > pristine. This result demonstrates that the adsorption of nitrate ion on the surface of Al-doped BNNTs is stronger than Ga doped and pristine states. The chemical potential (µ) values for nitrate ion adsorption on the pristine, Al and Ga doped BNNTs are negative and is in order µ_pristine > µ_Al-doped > µ_Ga-doped, it means that these compounds are stable. The values of ▽²ρ_(BCP) and H_(BCP) for [(NO3)O…B(BNNTs)] at the all adsorption models are positive and the |V/G| ratio for all models is > 2, it denotes the strong electrostatic interaction between nitrate ion with nanotube. In addition, the results of natural bonding orbital (NBO) and maximum charge transfer parameters (∆N) indicate that at all adsorption models, the charge transfer occurs from nitrate ion toward nanotube and nanotube acts as p-type semiconductor.

Vorheriger Artikel Co-adsorption of Albumin and Immunoglobulin G from Human Serum onto a cation exchanger mixed mode adsorbent

Nächster Artikel On the computer simulations of carbon nanoparticles porosity: statistical mechanics model for CO2 and N2 adsorption isotherms

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Titel: NBO, AIM, HOMO–LUMO and thermodynamic investigation of the nitrate ion adsorption on the surface of pristine, Al and Ga doped BNNTs: A DFT study
verfasst von: M. Rezaei-Sameti
P. Zarei
Publikationsdatum: 26.09.2018
Verlag: Springer US
Erschienen in: Adsorption / Ausgabe 8/2018
Print ISSN: 0929-5607
Elektronische ISSN: 1572-8757
DOI: https://doi.org/10.1007/s10450-018-9977-7

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