CO<sub>2</sub> activation and dissociation on the low miller index surfaces of pure and Ni-coated iron metal: a DFT study

Kwawu, Caroline R.; Tia, Richard; Adei, Evans; Dzade, Nelson Y.; Catlow, C. Richard A.; Leeuw, Nora H. de

doi:10.1039/c7cp03466k

Cited by 21 publications

(14 citation statements)

References 41 publications

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“…The obtained vibrational frequencies for the adsorbed H 2 S, HCN and HF gas molecules were lower than that of the isolated gas-phase molecule, which shows that the asymmetric and symmetric stretches were shifted to a lower vibrational frequency. The significant shifts in the vibrational modes show that the H 2 S, HCN and HF gas molecules are activated [66]. Moreover, the computed vibrational frequencies agreed with experimental results [67,68].…”

Section: Full Papersupporting

confidence: 80%

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation

Opoku

Govender

2020

Electroanalysis

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Using density functional theory, we have systematically investigate the room temperature gassensing performance of two-dimensional delafossite cobalt oxyhydroxide (CoOOH) sheets as H 2 S, HCN and HF detection. Our findings show that CoOOH is sensitive to H 2 S, HCN and HF gas by a physisorption interaction. The CoOOH sheets exhibit significant changes after the gas molecules adsorption, particularly its electrical conductivity. The suitable adsorption energy, which guarantees short recovery time, remarkable high sensitivity and selectivity, appreciable work function change and sharply enhanced electrical conductivity make CoOOH sheets as an effective nanosensor for toxic H 2 S, HCN and HF gases detection.

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Section: Full Papersupporting

confidence: 80%

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation

Opoku

Govender

2020

Electroanalysis

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“…CO 2 adsorption on Fe (111) is seen to require an energy barrier of − 4.6 kJ mol −1 [38]. In this study, hydrogenation of the Fe (111) surface is also seen to be barrier less and dissociative; hence, atomic hydrogen co-adsorption is explored in each elementary step via the Langmuir-Hinshelwood-type reaction.…”

Section: Reaction Energies For Co 2 Hydrogenationmentioning

confidence: 84%

“…Each slab is made up of the 36 atoms whereby there are 6 layers and 6 atoms in each layer. In all calculations, the top 3 layers and adsorbate are allowed to relax and bottom 3 layers fixed to mimic the bulk material as employed in earlier computations [37,38]. The Climbing Image Nudged Elastic Band (CI-NEB) method was used to determine all transition-state structures along the reaction coordinate.…”

Section: Computational Detailsmentioning

confidence: 99%

A DFT investigation of the mechanisms of CO2 and CO methanation on Fe (111)

Kwawu

Aniagyei

Tia

et al. 2020

Mater Renew Sustain Energy

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Insight into the detailed mechanism of the Sabatier reaction on iron is essential for the design of cheap, environmentally benign, efficient and selective catalytic surfaces for CO 2 reduction. Earlier attempts to unravel the mechanism of CO 2 reduction on pure metals including inexpensive metals focused on Ni and Cu; however, the detailed mechanism of CO 2 reduction on iron is not yet known. We have, thus, explored with spin-polarized density functional theory calculations the relative stabilities of intermediates and kinetic barriers associated with methanation of CO 2 via the CO and non-CO pathways on the Fe (111) surface. Through the non-CO (formate) pathway, a dihydride CO 2 species (H 2 CO 2), which decomposes to aldehyde (CHO), is further hydrogenated into methoxy, methanol and then methane. Through the CO pathway, it is observed that the CO species formed from dihydroxycarbene is not favorably decomposed into carbide (both thermodynamically and kinetically challenging) but CO undergoes associative hydrogenation to form CH 2 OH which decomposes into CH 2 , leading to methane formation. Our results show that the transformation of CO 2 to methane proceeds via the CO pathway, since the barriers leading to alkoxy transformation into methane are high via the non-CO pathway. Methanol formation is more favored via the non-CO pathway. Iron (111) shows selectivity towards CO methanation over CO 2 methanation due to differences in the rate-determining steps, i.e., 91.6 kJ mol −1 and 146.2 kJ mol −1 , respectively. Keywords Spin-polarized DFT-GGA • CO 2 methanation • CO methanation • Methanol formation • Reaction mechanism CO 2 + 4 H 2 → CH 4 + 2 H 2 O ΔH 298K = −252.9 kJ mol −1 .

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“…The preferred CO 2 adsorption site on the clean Fe (100) surface has been reported to be the hollow site [24]. At the hollow site, we considered CO 2 binding through the carbon and the two oxygen atoms in the 3 possible configurations (see Fig.…”

Section: Co 2 Adsorptionmentioning

confidence: 99%

“…DFT investigations of the rWGS reaction mechanism on nickel (211) indicated the redox path to be favoured both kinetically and thermodynamically [21]. Despite earlier DFT calculations [22][23][24] have reported the spontaneous formation of anionic CO 2 δ− species on all the low-Miller indices of iron surfaces, to the best of our knowledge, no systematic theoretical study has been conducted to understand the mechanism of the rWGS reaction on iron. In the present study, the catalytic CO 2 hydrogenation intermediates and reaction barriers leading to carbon monoxide and formic acid production on iron (100) have been studied.…”

Section: Introductionmentioning

confidence: 99%

Mechanisms of CO2 reduction into CO and formic acid on Fe (100): a DFT study

Kwawu

Aniagyei

Konadu

et al. 2021

Mater Renew Sustain Energy

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Understanding the mechanism of CO2 reduction on iron is crucial for the design of more efficient and cheaper iron electrocatalyst for CO2 conversion. In the present study, we have employed spin-polarized density functional theory calculations within the generalized gradient approximation (DFT-GGA) to elucidate the mechanism of CO2 reduction into carbon monoxide and formic acid on the Fe (100) facet. We also sort to understand the transformations of the other isomers of adsorbed CO2 on iron as earlier mechanistic studies are centred on the transformations of the C2v geometry alone and not the other possible conformations i.e., flip-C2v and Cs modes. Two alternative reduction routes were considered i.e., the direct CO2 dissociation against the hydrogen-assisted CO2 transformation through formate and carboxylate into CO and formic acid. Our results show that CO2 in the C2v mode is the precursor to the formation of both products i.e., CO and formic acid. Both the formation and transformation of CO2 in the Cs and flip-C2v is challenging kinetically and thermodynamically compared to the C2v mode. The formic acid formation is favoured over CO via the reverse water gas shift reaction mechanism on Fe (100). Both formic acid formation and CO formation will proceed via the carboxylate intermediate since formate is a stable intermediate whose transformation into formic acid is challenging both kinetically and thermodynamically. Graphic abstract

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CO₂ activation and dissociation on the low miller index surfaces of pure and Ni-coated iron metal: a DFT study

Cited by 21 publications

References 41 publications

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation

A DFT investigation of the mechanisms of CO2 and CO methanation on Fe (111)

Mechanisms of CO2 reduction into CO and formic acid on Fe (100): a DFT study

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CO2 activation and dissociation on the low miller index surfaces of pure and Ni-coated iron metal: a DFT study

Cited by 21 publications

References 41 publications

Two‐dimensional CoOOH as a Highly Sensitive and Selective H2S, HCN and HF Gas Sensor: A Computational Investigation

Two‐dimensional CoOOH as a Highly Sensitive and Selective H2S, HCN and HF Gas Sensor: A Computational Investigation

A DFT investigation of the mechanisms of CO2 and CO methanation on Fe (111)

Mechanisms of CO2 reduction into CO and formic acid on Fe (100): a DFT study

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CO₂ activation and dissociation on the low miller index surfaces of pure and Ni-coated iron metal: a DFT study

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation

Two‐dimensional CoOOH as a Highly Sensitive and Selective H₂S, HCN and HF Gas Sensor: A Computational Investigation