Flat borophene films as anode materials for Mg, Na or Li-ion batteries with ultra high capacities: A first-principles study

Mortazavi, Bohayra; Rahaman, Obaidur; Ahzi, Saı̈d; Rabczuk, Timon

doi:10.1016/j.apmt.2017.04.010

Cited by 135 publications

(70 citation statements)

References 57 publications

(85 reference statements)

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“…52 Moreover, for the application in rechargeable batteries, borophene films have to be producible in large content and low-cost. 36 Interestingly, a recently fabricated hydrogenated borophene structure, hydrogen boride 49 , was in multi-layer form and more importantly the nanomembranes were not grown on a substrate, which accordingly can serve as promising signs toward their real application in commercial ion batteries.…”

Section: Introductionmentioning

confidence: 99%

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

Makaremi

Mortazavi

Singh

2018

Materials Today Energy

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Fast-growing electronics industry and future energy storage needs have encouraged the design of rechargeable batteries with higher storage capacities, and longer life times. In this regard, two-dimensional (2D) materials, specifically boron and carbon nanosheets, have garnered enthusiasm due to their fascinating electronic, optical, mechanical and chemical properties. Recently, a hydrogen boride (HB) nanosheet was successfully fabricated showing remarkable stability and superior physical properties. Motivated by this experimental study, we used first principle electronic structure calculations to study the feasibility of this nanosheet to serve as an anode material for Li/Na/Ca/Mg/Al ion batteries. Most active adsorption sites for single adatoms were evaluated and next adatoms were gradually inserted into the anode surface accordingly.The charge transfer, electronic density of sates, storage capacity, structural stability, open-circuit potential and diffusion energy barriers were explored. Our theoretical study predicts that HB shows outstanding electrode properties for Li and Na ion batteries. The intercalation of both Li and Na adatoms into the HB monolayer can lead to a high identical storage capacity of 1133.8 mAh/g which is promising compared to the capacities of the traditional anode materials; such as graphite (372 mAh/g) and TiO2 (200 mAh/g), and other 2D materials; such as germanene (369 mAh/g), stanene (226 mAh/g), and phosphorene (432.8 mAh/g) nanosheets.These results may open a new horizon for the design of rechargeable batteries with higher storage capacitates.

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Section: Introductionmentioning

confidence: 99%

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

Makaremi

Mortazavi

Singh

2018

Materials Today Energy

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“…Additionally, these polymorphs have shown phonon meditated superconductivity [31], and because of the light weight, diverse electronic properties and mechanical stability, they have been reported as high capacity electrode for electrochemical applications [32][33][34] and as catalyst for hydrogen evolution reaction [35].…”

Section: Introductionmentioning

confidence: 99%

“…These borophene structures have been reported as unstable in isolated form, but this instability could be overcome with vacancy defect and deposition on some non-reactive surface [28]. Existence of massless Dirac fermions in these two polymorphs makes them even more compelling towards the nano-electronic applications [29,30].Additionally, these polymorphs have shown phonon meditated superconductivity [31], and because of the light weight, diverse electronic properties and mechanical stability, they have been reported as high capacity electrode for electrochemical applications [32][33][34] and as catalyst for hydrogen evolution reaction [35].Typically, several approaches can be applied to engineer the electronic structure of 2D materials, like electrostatic gating and molecular adsorption, that have been used for graphene, phosphorene and others [36][37][38][39]. Moreover, electronic, transport and optical properties are considerably determined by atomic geometry, and it follows that strain is the most suitable way to tune intrinsic properties of these 2D materials.…”

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confidence: 99%

Strain controlled electronic and transport anisotropies in two-dimensional borophene sheets

Shukla

Grigoriev

Jena

et al. 2018

Phys. Chem. Chem. Phys.

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Two recent reports on realization of an elemental 2D analogue of graphene:borophene (Science, 2015, 350, 1513-1516; Nat. Chem., 2016, 8, 563-568) focus on the inherent anisotropy and directional dependence of the electronic properties of borophene polymorphs. Achieving stable 2D borophene structures may lead to some degree of strain in the system because of the substrate-lattice mismatch. We use first principles density functional theory (DFT) calculations to study the structural, electronic and transport properties of β12 and χ-borophene polymorphs. We verified the directional dependency and found the tunable anisotropic behavior of the transport properties in these two polymorphs. We find that strain as low as 6% brings remarkable changes in the properties of these two structures. We further investigate current-voltage (I-V) characteristics in the low bias regime after applying a strain to see how the anisotropy of the current is affected. Such observations like the sizeable tuning of transport and I-V characteristics at the expense of minimal strain suggest the suitability of 2D borophene for futuristic device applications.

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“…Very recently, micron‐sized 2D boron sheet (up to 100 μm 2 ) has been obtained in experiment, indicating the enormous potential of the fabrication of 2D‐boron‐based devices in many fields . For example, borophene and borophene based anodes are both expected to be used as excellent lithium‐ion batteries or other rechargeable metal ion batteries . Moreover, some electrocatalysts comprising borophene subunits possess high activity in hydrogen evolution (HER), nitrogen reduction reaction (NRR) and carbon dioxide reduction .…”

Section: Introductionmentioning

confidence: 99%

“…[36] For example, borophene and borophene based anodes are both expected to be used as excellent lithium-ion batteries or other rechargeable metal ion batteries. [37][38][39][40][41][42] Moreover, some electrocatalysts comprising borophene subunits possess high activity in hydrogen evolution (HER), nitrogen reduction reaction (NRR) and carbon dioxide reduction. [43][44][45][46] Some hydrogenated 2D boron sheets are all proved to be dynamically stable, and importantly, they exhibit Dirac cones with massless Dirac fermions.…”

Section: Introductionmentioning

confidence: 99%

Borophene: A Metal‐free and Metallic Electrocatalyst for Efficient Converting CO₂ into CH₄

Qin

Cui

et al. 2020

ChemCatChem

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Exploring novel and metal‐free electrocatalysts for CO2 reduction is of great significance not only for reducing of CO2 emission but also for energy storage. However, searching metal‐free and highly efficient electrocatalysts for CO2 reduction is still challenging. Here, we report that a metal‐free and metallic borophene can be used as an efficient electrocatalyst for CO2 reduction. Through a comprehensive DFT investigation of CO2 activation and conversion on newly fabricated metallic 2D boron sheets (borophene, β12 or χ3 boron sheets), our calculational results indicate that electron deficient borophene can provide electrons to CO2 and effectively activate the inserted CO2 by breaking π bond of CO2. Moreover, the study demonstrates that the most feasible product of CO2 reduction on the borophene is CH4 with a limiting potential of −0.27 V and the largest activation barrier of 0.98 eV along the minimum energy pathway. The very small values of the limiting potential and activation barrier indicate that CO2 reduction reaction on borophene is both thermodynamically and kinetically feasible. Overall, our work provides insight that the metal free and metallic borophene can be used as an excellent electrocatalyst for CO2 reduction.

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Flat borophene films as anode materials for Mg, Na or Li-ion batteries with ultra high capacities: A first-principles study

Cited by 135 publications

References 57 publications

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

Strain controlled electronic and transport anisotropies in two-dimensional borophene sheets

Borophene: A Metal‐free and Metallic Electrocatalyst for Efficient Converting CO₂ into CH₄

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Flat borophene films as anode materials for Mg, Na or Li-ion batteries with ultra high capacities: A first-principles study

Cited by 135 publications

References 57 publications

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

2D Hydrogenated graphene-like borophene as a high capacity anode material for improved Li/Na ion batteries: A first principles study

Strain controlled electronic and transport anisotropies in two-dimensional borophene sheets

Borophene: A Metal‐free and Metallic Electrocatalyst for Efficient Converting CO2 into CH4

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Borophene: A Metal‐free and Metallic Electrocatalyst for Efficient Converting CO₂ into CH₄