Hexagonal Boron Nitride/Blue Phosphorene Heterostructure as a Promising Anode Material for Li/Na-Ion Batteries

Bao, Jinna; Zhu, Linsheng; Wang, Haochi; Han, Song; Jin, Yuhang; Zhao, Guoqiang; Zhu, Yiheng; Guo, Xin; Hou, Jianhua; Li, Huaiyu; Jian, Tian

doi:10.1021/acs.jpcc.8b07062

Cited by 54 publications

(51 citation statements)

References 52 publications

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“…Recently, there are a few theoretical investigation proposals that blue phosphorene (blue‐P), an allotrope of BP, also has great potential for LIB anode and suffers the same degeneration problem with BP. Recent theoretical calculation studies suggested that heterostructure blue‐P, including blue‐P/borophene, [ 89 ] blue‐P/graphene, [ 90 ] blue‐P/g‐C 3 N, [ 91 ] blue‐P/BN, [ 92 ] blue‐P/NbS 2 , [ 93 ] and blue‐P/TaS 2 , [ 94 ] are also very auspicious candidates as anode materials for LIBs. Among, blue‐P/borophene heterostructure presented an impressive high theoretical capacity of 1019 mA h g −1 , demonstrating the great potential of heterostructure materials applied as anode for LIBs.…”

Section: The Electrochemical Performance Of Heterostructuresmentioning

confidence: 99%

“…[ 140 ] The recent theoretical studies also demonstrated the superiorities of h‐BN/phosphorene heterostructure and h‐BN/blue‐P heterostructure. [ 87,92 ] The design of heterostructure contained P‐based active materials will be inspirable to the development of anode materials for alkali metal ion batteries.…”

Section: The Electrochemical Performance Of Heterostructuresmentioning

confidence: 99%

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Emerging of Heterostructure Materials in Energy Storage: A Review

et al. 2021

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With the ever‐increasing adaption of large‐scale energy storage systems and electric devices, the energy storage capability of batteries and supercapacitors has faced increased demand and challenges. The electrodes of these devices have experienced radical change with the introduction of nano‐scale materials. As new generation materials, heterostructure materials have attracted increasing attention due to their unique interfaces, robust architectures, and synergistic effects, and thus, the ability to enhance the energy/power outputs as well as the lifespan of batteries. In this review, the recent progress in heterostructure from energy storage fields is summarized. Specifically, the fundamental natures of heterostructures, including charge redistribution, built‐in electric field, and associated energy storage mechanisms, are summarized and discussed in detail. Furthermore, various synthesis routes for heterostructures in energy storage fields are roundly reviewed, and their advantages and drawbacks are analyzed. The superiorities and current achievements of heterostructure materials in lithium‐ion batteries (LIBs), sodium‐ion batteries (SIBs), lithium‐sulfur batteries (Li‐S batteries), supercapacitors, and other energy storage devices are discussed. Finally, the authors conclude with the current challenges and perspectives of the heterostructure materials for the fields of energy storage.

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Section: The Electrochemical Performance Of Heterostructuresmentioning

confidence: 99%

Section: The Electrochemical Performance Of Heterostructuresmentioning

confidence: 99%

Emerging of Heterostructure Materials in Energy Storage: A Review

et al. 2021

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“…2 The effects of doping, [3][4][5] functionalization, [6][7][8][9] and heterostructure formation, [10][11][12][13][14][15] including external stimuli such as strain and electric field, on the electronic and magnetic properties of BlueP are known from first-principles calculations, indicating that it is a promising 2D material. Various investigations have explored the potential in nanoelectronic devices, 16 photodetectors, 17 energy storage, 15,[18][19][20][21] gas sensors, [22][23][24] and superconductors. 25 While BlueP can be grown by molecular beam epitaxy on the Au(111) surface, 26,27 defects are inevitable during synthesis of 2D materials.…”

Section: Introductionmentioning

confidence: 99%

Point Defects in Blue Phosphorene

Sun

Chou

et al. 2019

Chem. Mater.

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Using first-principles calculations, we investigate selected defects in blue phosphorene (BlueP). For a single vacancy (SV) defect a 5-9 structure is energetically favorable and for a double vacancy (DV) defect a 5-8-5 or 555-777 structure. A P adatom favors the top adsorption site. Scanning tunneling microscopy images are simulated to aid the experimental identification of the defects. Formation of a Stone-Wales defect is found to be most likely, but can be reverted by thermal annealing. Calculated migration and transformation barriers show that a SV defect can migrate easily. Both a SV defect and a P adatom induce a magnetic moment, thus turning BlueP into a magnetic semiconductor. It turns out that all the defects under investigation enhance the ability of BlueP to absorb sunlight.

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“…Other graphene‐like transition metal dichalcogenides (TMDCs) and transition metal dicarbides (MXenes) have also been widely studied in LIBs . Besides monolayer 2D materials, heterostructures consisting of vertically stacked bilayer different 2D materials, such as h‐BN/black phosphorene and h‐BN/blue phosphorene, can exhibit excellent anode performances for LIBs/NIBs as well, which expands the potential of 2D materials as anode for LIBs/NIBs. In short, it is highly desirable to search for new 2D anode materials for high‐performance LIBs/NIBs.…”

Section: Introductionmentioning

confidence: 99%

A First‐Principles Study of Boron‐Doped BC₂N Sheet as Potential Anode Material for Li/Na‐Ion Batteries

Duan

Jiang

et al. 2019

ChemElectroChem

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Two-dimensional materials have attracted a lot of attention in rechargeable batteries due to their unique physical and chemical properties. Here, we perform density functional theory calculations to evaluate the feasibility of using model-I, model-II, and model-III BC 2 N with B substitution of C (denoted as BC 2 NB C ) as an anode material for Li/Na-ion batteries (LIBs/NIBs). The results demonstrate that each of them has its advantages. Model-I BC 2 NB C has the highest theoretical capacity (1789.7 mAh/g for Li and 686.2 mAh/g for Na), model-II BC 2 NB C has the lowest diffusion barrier (0.39 eV for Li and 0.16 eV for Na) and model-III BC 2 NB C has the largest adsorption energies (3.81 eV for Li and 3.2 eV for Na), which can satisfy the requirement of energy storage devices to anode materials. Moreover, molecular dynamics simulations indicate that model-I/II/III BC 2 NB C and its lithiation/sodiation are stable at 300 and 400 K. Therefore, model-I/II/III BC 2 NB C monolayer can be a good candidate anode material for LIBs/NIBs.

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Hexagonal Boron Nitride/Blue Phosphorene Heterostructure as a Promising Anode Material for Li/Na-Ion Batteries

Cited by 54 publications

References 52 publications

Emerging of Heterostructure Materials in Energy Storage: A Review

Emerging of Heterostructure Materials in Energy Storage: A Review

Point Defects in Blue Phosphorene

A First‐Principles Study of Boron‐Doped BC₂N Sheet as Potential Anode Material for Li/Na‐Ion Batteries

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Hexagonal Boron Nitride/Blue Phosphorene Heterostructure as a Promising Anode Material for Li/Na-Ion Batteries

Cited by 54 publications

References 52 publications

Emerging of Heterostructure Materials in Energy Storage: A Review

Emerging of Heterostructure Materials in Energy Storage: A Review

Point Defects in Blue Phosphorene

A First‐Principles Study of Boron‐Doped BC2N Sheet as Potential Anode Material for Li/Na‐Ion Batteries

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A First‐Principles Study of Boron‐Doped BC₂N Sheet as Potential Anode Material for Li/Na‐Ion Batteries