Enhanced Charge-Modulated Switchable CO<sub>2</sub> Capture on Graphene-like BeN<sub>4</sub> with Beryllium Vacancy

Mahmoudi, Mohsen; Tan, Xin; Smith, Sean C.

doi:10.1021/acs.jpcc.2c04416

Cited by 5 publications

(1 citation statement)

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“…For example., Li-doped BeN 4 for the capture of CO 2 was reported by Pu et al The pristine BeN 4 monolayer was incapable of CO 2 capturing due to low adsorption energy, but the Li doping could enhance it [39]. Similarly, Mahmoudi et al also showed that the vacancy created in the BeN 4 monolayer could modulate the CO 2 adsorption capability [40]. The study of ammonia sensing by defective 2D BeN 4 monolayer is unknown to the authors' knowledge.…”

Section: Introductionmentioning

confidence: 97%

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation

Lakshmy,

Sanyal,

Kalarikkal

et al. 2023

Nanotechnology

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Two-dimensional (2D) materials have attracted a great deal of interest in developing nanodevices for gas-sensing applications over the years. The 2D BeN4 monolayer, a recently synthesized single-layered Dirac semimetal, has the potential to function as a gas sensor. This study analyses the ammonia (NH3) sensing capacity of the pristine and vacancy-induced BeN4 monolayers using first-principle density functional theory (DFT) calculations. As per the obtained results, the NH3molecule is adsorbed on pristine BeN4 via weak Van der Waals interaction (vdW) with a poor adsorption energy of -0.41 eV and negligible charge transfer. Introducing Be vacancy in BeN4 increases the NH3 adsorption energy to -0.83 eV due to improved charge transfer (0.044e) from defective monolayer to the NH3 molecule. The structural stability, suitable recovery time (74 s) at room temperature, and superior work function sensitivity promise the potential application of defective BeN4 as an NH3 sensor. This research will be a theoretical groundwork for creating innovative BeN4-based NH3 gas sensors.

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Section: Introductionmentioning

confidence: 97%

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation

Lakshmy,

Sanyal,

Kalarikkal

et al. 2023

Nanotechnology

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Stable two-dimensional Na decorated BeN4: a potential candidate for hydrogen storage

et al. 2023

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Hydrogen, being a powerful energy carrier, possesses the ability to transform the present carbon economy to green hydrogen economy. Since wide range of resources are available for its production, reversible hydrogen storage is the prevalent challenge. Surface activation by adsorption has been reported to increase the hydrogen uptake, thus boosting the storage capacity. In this work, Sodium (Na) decorated Beryllonitrene (BeN 4 ) monolayer has been identi ed as a hydrogen storage material using rst-principles calculations. Our results reveal that Na decorated BeN 4 has ability to adsorb upto 12 H 2 molecules, leading to high gravimetric density of 4.26 wt%. The adsorption energy per H 2 (adsorbate) is moderate i.e., between 0.13 and 0.298 eV, good enough for hydrogen storage in practical applications. AIMD simulations disclose that adsorbate experiences no kinetic hinderance in desorption. Moreover, the desorption temperature of H 2 molecule on NaBeN 4 monolayer (substrate) varies from 162.5 to 382 K, con rming the reversibility of substrate and thus ensuring its potential for hydrogen storage medium. The short recovery time predicts that the substrate responds rapidly in presence of H 2 molecules, which guarantees the fast kinetics of adsorbate. Our calculations predict Na-decorated BeN 4 monolayer as an excellent candidate for reversible and high-capacity hydrogen storage material.

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Vacancies and Stone–Wales type defects in monolayer BeN4

Ponvijayakanthan,

Jaiswal,

Ghosh

2024

Materials Today Communications

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Enhanced Charge-Modulated Switchable CO₂ Capture on Graphene-like BeN₄ with Beryllium Vacancy

Cited by 5 publications

References 62 publications

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation

Stable two-dimensional Na decorated BeN4: a potential candidate for hydrogen storage

Vacancies and Stone–Wales type defects in monolayer BeN4

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Enhanced Charge-Modulated Switchable CO2 Capture on Graphene-like BeN4 with Beryllium Vacancy

Cited by 5 publications

References 62 publications

Influence of vacancy defects on 2D BeN4 monolayer for NH3 adsorption: a density functional theory investigation

Influence of vacancy defects on 2D BeN4 monolayer for NH3 adsorption: a density functional theory investigation

Stable two-dimensional Na decorated BeN4: a potential candidate for hydrogen storage

Vacancies and Stone–Wales type defects in monolayer BeN4

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Product

Resources

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Enhanced Charge-Modulated Switchable CO₂ Capture on Graphene-like BeN₄ with Beryllium Vacancy

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation

Influence of vacancy defects on 2D BeN₄ monolayer for NH₃ adsorption: a density functional theory investigation