Recent Progress on Germanene and Functionalized Germanene: Preparation, Characterizations, Applications, and Challenges

Liu, Nana; Bo, Guyue; Liu, Yani; Xu, Xun; Du, Yi; Dou, Shi Xue

doi:10.1002/smll.201805147

Cited by 130 publications

(107 citation statements)

References 100 publications

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“…This last one is obtained from the layered CaGe 2 in which the [Ge − ] Zintl ion allows the topotactic deintercalation of Ca 2+ while preserving the Ge backbone . This germanium‐based layered material was first reported in 2000 and presents several differences compared to its bulk counterpart, for instance it has a direct band gap and exhibit a strong photoluminescence (change in color from the gray‐metallic in CaGe 2 to red in germanane), which is directly related with the presence of −OH and −H groups . Hence the nature of the ligands has a repercussion in the physical and chemical properties.…”

Section: Introductionmentioning

confidence: 99%

Towards Germanium Layered Materials as Superior Negative Electrodes for Li‐, Na‐, and K‐Ion Batteries

Loaiza

Monconduit

Seznéc

2020

Batteries & Supercaps

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The germanium high theoretical capacity renders it as a promising anode material with 1384 mAh/g for Li (Li 15 Ge 4 ) and 369 mAh/g for Na (NaGe) and K (KGe). Nevertheless, Ge suffers from volume variations due to alkali insertion, to mitigate this issue several strategies have been proposed. Among them the use of layered Ge-based phases, obtained from the CaGe 2 Zintl phase by topotactic deintercalation of Ca 2 + to form the germanane (GeH) n. This last one has a particular morphology of Ge 6 rings interconnected to form planes that buffers the volume changes and shortens the diffusion pathways. Here, we have studied the germanane alkali storage properties and 2150, 495 and 205 mAh/g of reversible capacity were obtained for Li, Na and K, respectively. These results indicate that germanane can store more alkali ions than the predicted phases, perform well at high rates and maintain a good capacity retention.

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Section: Introductionmentioning

confidence: 99%

Towards Germanium Layered Materials as Superior Negative Electrodes for Li‐, Na‐, and K‐Ion Batteries

Loaiza

Monconduit

Seznéc

2020

Batteries & Supercaps

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“…The crystal structures of CaSi 2 [52] and CaGe 2 [53] consist of anionic [Si] n − and [Ge] n − layers similar to 2D-Xenes, inserted by a divalent cation. [54,55] For instance, substituting H-termination in GeH with methyl-terminated germanene can improve the thermal stability (250 °C) and enhance the band gap, and yields band edge fluorescence with a ≈0.2% quantum yield.…”

Section: Liquid Phase Exfoliationmentioning

confidence: 99%

Xenes as an Emerging 2D Monoelemental Family: Fundamental Electrochemistry and Energy Applications

Wang

Kou

et al. 2020

Adv Funct Materials

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As an emerging subclass of 2D materials, Xenes (e.g., borophene, silicene, germanene, stanene, phosphorene, arsenene, antimonene, and bismuthene) consist of one single element and have opened the door for various important applications. Benefiting from their impressive characteristics, including ultrathin folded structure, ultrahigh surface–volume ratio, excellent mechanical strength and flexibility, Xenes are considered as promising electrode materials in the field of electrochemical energy with large capacity, high rate, and high safety. This review provides a comprehensive summary of selected properties, synthetic challenges, and the latest theoretical and experimental advances in the energy‐related applications of Xenes, including Li/Na ion batteries, Li–S batteries, electrocatalysis, and supercapacitors. Finally, the challenges and outlook of this emerging field are discussed.

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“…There has been significant theoretical and computational research on these mechanically robust puckered 2D structure because their tunable properties such as tuning their bandgaps with strain engineering, inducing magnetization with hydrogenation and inducing high‐sensitive surfaces on the electronic structure modification with molecular adsorptions . As predicted by theoretical and computational research on these mechanically robust puckered 2D structure, substantial experimental progress on silicene as well as germanene elemental puckered structured 2D materials has been accessed as a promising potential candidate for use in field‐effect transistors, topology‐based electronics, magnetic‐, optical‐, and thermal‐based device applications . Herewith, the first successful fabrication of next elemental epitaxial tin (Sn) atomic layer (“stanene”) on a Bi 2 Te 3 substrate in 2015 was followed by the room‐temperature realization of its dissipationless conductivity in 2018, and that encourages for more widespread studies of its fundamental properties, as compared with those of other competitive elemental 2D analogue.…”

Section: Introductionmentioning

confidence: 99%

A Perspective on Recent Advances in 2D Stanene Nanosheets

Sahoo

Wei

2019

Adv Materials Inter

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for example, incompatibility with the semiconductor industry, [13] toxicity, [14] and susceptibility to oxidative environments. [7] Accordingly, researchers are on the lookout for other existing or synthetic 2D analogues.There have been numerous reports describing a wide variety of layered ultrathin 2D nanomaterials beyond graphene, with fascinating and technologydriven properties. These single-layer atomic crystals are classified in terms of their constituent elemental bonding states and structures. Most of them are transition metals bonded with chalcogenide groups (e.g., MoS 2 , MoSe 2 , WS 2 , TiS 2 ), [13,15] metal carbides and nitrides (MXenes), [16] metalorganic frameworks (MOFs), [17] covalent organic frameworks (COFs), [18] hexagonal boron nitrides, [19] and monoelemental 2D analogues (e.g., silicene, germanene, and phosphorene). [20] The emergence of new fascinating physical and chemical properties is encouraging the discovery of new classes of 2D nanomaterials, prepared either from 3D van der Waals bulk phases (through top-down techniques) or through self-assembly of elemental constituents from wet-chemical or vapor phase (bottom-up approaches). The former types of synthetic strategies are mostly exfoliation processes from 3D layered structures, including physical exfoliation (by forced delamination of layers), [21] liquid phase exfoliation (by the chemistry of matching with solute-solvent interface energy), [22] and ion intercalation and exfoliation (by electrochemical reactions). [23,24] These processes for preparing 2D nanosheets are widely followed because they are sufficiently simple and robust for scalable production; nevertheless, they can be challenging to use when synthesizing nanosheets with uniform thicknesses and lateral dimensions. The scalability of these processes for manufacturing nanosheets has, however, been exploited widely, for example, in energy storage devices, [25] sensors, [26] electronics and photonic devices, [27] as well as in biomedicine. [27] The bottom-up approaches involve growth and self-assembly from the atomic scale, mostly involving chemical vapor deposition, [28] pulsed laser deposition, [28] and epitaxial growth. [29] Although these processes for fabricating 2D nanosheets provide good control over the homogeneity of the structures, they occur with complex growth mechanisms and are not scalable. Interestingly, quantum confinement effects are prominent in fabricated atomic-layer structures, and suggest a new dimension for future nanoelectronics and many other advanced applications. [30][31][32][33] Advancements in 2D nanomaterials have been impacting a wide range of technology-driven applications. Here, the authors highlight stanene, a material that comprises a monolayer of elemental tin atoms, as a new addition to the monoelemental 2D family. Recent successes in the experimental realization of stanene in supported heterostructures and in free-standing form have expanded interest in exploring and unlocking its potential applications, as predicted from advanced theoreti...

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Recent Progress on Germanene and Functionalized Germanene: Preparation, Characterizations, Applications, and Challenges

Cited by 130 publications

References 100 publications

Towards Germanium Layered Materials as Superior Negative Electrodes for Li‐, Na‐, and K‐Ion Batteries

Towards Germanium Layered Materials as Superior Negative Electrodes for Li‐, Na‐, and K‐Ion Batteries

Xenes as an Emerging 2D Monoelemental Family: Fundamental Electrochemistry and Energy Applications

A Perspective on Recent Advances in 2D Stanene Nanosheets

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