Density-Functional-Theory Calculations of Formation Energy of the Nitrogen-Doped Diamond

Sholihun, Sholihun; Kadarisman, Hana Pratiwi; Nurwantoro, Pekik

doi:10.22146/ijc.26785

Cited by 19 publications

(11 citation statements)

References 23 publications

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“…In each supercell, one dopant atom was located at a substitutional lattice site in the outer layers. While B [53] and N [54,55] atoms are known from previous studies to favour substitutional sites, it is not clear whether this is also the case for O atoms. IR absorption spectra of O-containing DLC films often indicate the presence of carbonyl oxygens [20] (C=O), but other studies found O incorporation in bridge positions (two C-O bonds) to be more stable [46], or have suggested the presence of epoxy groups [6,50].…”

Section: Methodsmentioning

confidence: 97%

Ab initio insights into the interaction mechanisms between boron, nitrogen and oxygen doped diamond surfaces and water molecules

Latorre

Ewen

Dini

et al. 2021

Carbon

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Section: Methodsmentioning

confidence: 97%

Ab initio insights into the interaction mechanisms between boron, nitrogen and oxygen doped diamond surfaces and water molecules

Latorre

Ewen

Dini

et al. 2021

Carbon

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“…Moreover, the defect volume is calculated before modification/pure diamond (𝑉 0 ) and after modification by carbon-vacancy-hydrogen (𝑉 𝑓 ). The volume changes before and after relaxation (∆𝑉) is calculated by the following equation [34]: We also calculate the formation energies for each defect structure by using equations as follows [26]:…”

Section: Methodsmentioning

confidence: 99%

Structural, Energetic, and Electronic Properties of H-Interstitial in C-Monovacancy: A First-Principles Density Functional Theory

Fajariah,

Fadlliyanai,

Purnawati

et al. 2024

Trends Sci

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We discover a unique structural-modified diamond that exhibits similar symmetry and band gap energy to that of the pure diamond. We study a complex carbon-vacancy-hydrogen in the diamond using the density-functional-theory method. The defective models are created by adding H-interstitial (Hi, where i = 1, 2, 3 and 4) in the 3D diamond C-monovacancy. The result shows that carbon-vacancy-hydrogen defects significantly decreased the symmetry from Td to C2V. Likewise, the volumetric size of the systems is widening up to 48.70 %, while the optimized band gap energies are narrowing. Additional states appeared in the C-monovacancy, H1-V, H2-V, and H3-V systems which further improved electron mobility. The Hi compensates the C-monovacancy which further serves as a deep donor. Interestingly, H4-V exhibits similar symmetry and band gap energy to that of the pure diamond, but its volumetric size is 48.70 % wider. HIGHLIGHTS Study of complex carbon-vacancy-hydrogen defects through density-functional-theory calculations Discover a unique structural-modified diamond that is 48.70 % wider than the pure diamond, but exhibits similar symmetry and band gap energy. Complex carbon-vacancy-hydrogen defects significantly lower the symmetries, widening the volumetric sizes, and narrowing the band gap energies. The H-interstitial acts as a deep donor. GRAPHICAL ABSTRACT

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“…We then calculate the formation energy Eform and charge transfer. The Eform is defined by using the following equation [27][28][29][30][31]:…”

Section: ■ Computational Methodsmentioning

confidence: 99%

Adsorption of Toxic Heavy Metal Methylmercury (MeHg) on Germanene in Aqueous Environment: A First-Principles Study

et al. 2021

Self Cite

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We perform ﬁrst-principles calculations to investigate the adsorption process of methyl mercury (MeHg) on germanene with the presence of water molecules. We calculate the formation energy and density of states to determine the effect of the adsorption of MeHg on the structural and electronic properties of germanene. Our results show that MeHg is chemisorbed on germanene through a spontaneous reaction. The calculated formation energy of the system is -1.61 eV. We also carry out charge distribution and charge transfer calculations based on the Mulliken model to understand the adsorption mechanism of MeHg.

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Density-Functional-Theory Calculations of Formation Energy of the Nitrogen-Doped Diamond

Cited by 19 publications

References 23 publications

Ab initio insights into the interaction mechanisms between boron, nitrogen and oxygen doped diamond surfaces and water molecules

Ab initio insights into the interaction mechanisms between boron, nitrogen and oxygen doped diamond surfaces and water molecules

Structural, Energetic, and Electronic Properties of H-Interstitial in C-Monovacancy: A First-Principles Density Functional Theory

Adsorption of Toxic Heavy Metal Methylmercury (MeHg) on Germanene in Aqueous Environment: A First-Principles Study

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