Spatial conductivity mapping of unprotected and capped black phosphorus using microwave microscopy

Visser, Pieter de; Chua, Rebekah; Island, Joshua O.; Finkel, Matvey; Katan, Allard J.; Thierschmann, Holger; Zant, Herre S. J. van der; Klapwijk, T. M.

doi:10.1088/2053-1583/3/2/021002

Cited by 32 publications

(21 citation statements)

References 36 publications

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“…Following this idea, capping by 2D material layers, such as hexagonal boron nitride and graphene, has been tested using a "flake to flake" transfer technique. 4,8,[13][14][15][16][17][18][19] However, particular care must be taken to ensure both a clean and dry interface and a complete coating by the BP flake to avoid edgeand grain boundary-dominated degradation. Furthermore, this technique is hardly transferrable to a large scale manufacturing technology up to now.…”

mentioning

confidence: 99%

“…4,7,20 Aiming at the same result, thick oxide layers grown on BP have been probed [e.g., 100 nm of SiO 2 grown by inductively coupled plasma chemical vapor deposition 21 or 10 nm of HfO 2 grown by atomic layer deposition (ALD) 19 ] and found to secure the environmental stability of BP at a week scale. Also, numerous attempts have focused on the passivation via a relatively thick (10 nm or above) Al 2 O 3 layer grown on top of the BP flakes by ALD.…”

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confidence: 99%

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Stabilizing ultra-thin black phosphorus with in-situ-grown 1 nm-Al2O3 barrier

Galceran

Gaufrès

Loiseau

et al. 2017

Applied Physics Letters

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Exfoliated black phosphorus is a 2D semiconductor with promising properties for electronics, spintronics, and optoelectronics. Nevertheless, its rapid degradation in air renders its integration and use in devices particularly challenging—even more so for smaller thicknesses for which the degradation rate is tremendously enhanced. In order to effectively protect the thinnest flakes, we present here an approach based on an in-situ dielectric capping to avoid all contact with air. Optical microscopy, Raman spectroscopy, and atomic force microscopy studies confirm that 1 nm of Al2O3 efficiently passivates exfoliated black phosphorus (below 5 layers) on Si/SiO2 substrates. Such an ultrathin and transparent passivation layer can act as a tunnel barrier allowing for black phosphorus devices processing without passivation layer removal.

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confidence: 99%

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confidence: 99%

Stabilizing ultra-thin black phosphorus with in-situ-grown 1 nm-Al2O3 barrier

Galceran

Gaufrès

Loiseau

et al. 2017

Applied Physics Letters

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“…Previous reports have proved that the BP degradation process can be slowed down considerably by covering the material with appropriate passivation layers, and it is stable for more than a week [17, 18]. Here we passivated the device with h -BN and then fabricated a top-gate.…”

Section: Resultsmentioning

confidence: 99%

The Role of Air Adsorption in Inverted Ultrathin Black Phosphorus Field-Effect Transistors

Chen

Feng

et al. 2016

Nanoscale Res Lett

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Few-layer black phosphorus (BP) attracts much attention owing to its high mobility and thickness-tunable band gap; however, compared with the commonly studied transition metal dichalcogenides (TMDCs), BP has the unfavorable property of degrading in ambient conditions. Here, we propose an inverted dual gates structure of ultrathin BP FET to research the air adsorption on BP. In fabrication process of back-gate BP FET, BP was transferred directly onto a wafer covered with electrodes. Thus, we can exclude the BP degradation during the process of electrodes fabrication, such as electron beam lithography (EBL) and thermal evaporation process. Furthermore, without any electrode covering BP, BP could be in full contact with the air; then the accurate effect of the air adsorption on BP can be researched in detail. The results clearly show that annealing can remove the p-doping resulted from the metastable oxygen adsorbed on the surface of BP, but the adsorption can be restored in a few hours exposure. In addition, both back and top gate inverted BP FETs exhibit a favorable performance. Therefore, this inverted structure is also an optional structure to reduce the influence of the instability of BP devices.

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“…The combined trilayer builds the type-II heterojunction alignment and PCE is predicted to be around 18%. In addition to managing recombination rate, heterostructures of the black phosphorus with particular materials such as HfO 2 can slow down the degradation of black phosphorus [70]. …”

Section: Black Phosphorus-based Heterostructure and Its Potential mentioning

confidence: 99%

Black Phosphorus: Critical Review and Potential for Water Splitting Photocatalyst

2016

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A century after its first synthesis in 1914, black phosphorus has been attracting significant attention as a promising two-dimensional material in recent years due to its unique properties. Nowadays, with the development of its exfoliation method, there are extensive applications of black phosphorus in transistors, batteries and optoelectronics. Though, because of its hardship in mass production and stability problems, the potential of the black phosphorus in various fields is left unexplored. Here, we provide a comprehensive review of crystal structure, electronic, optical properties and synthesis of black phosphorus. Recent research works about the applications of black phosphorus is summarized. Among them, the possibility of black phosphorous as a solar water splitting photocatalyst is mainly discussed and the feasible novel structure of photocatalysts based on black phosphorous is proposed.

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Spatial conductivity mapping of unprotected and capped black phosphorus using microwave microscopy

Cited by 32 publications

References 36 publications

Stabilizing ultra-thin black phosphorus with in-situ-grown 1 nm-Al2O3 barrier

Stabilizing ultra-thin black phosphorus with in-situ-grown 1 nm-Al2O3 barrier

The Role of Air Adsorption in Inverted Ultrathin Black Phosphorus Field-Effect Transistors

Black Phosphorus: Critical Review and Potential for Water Splitting Photocatalyst

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