Tuning the electrical property <i>via</i> defect engineering of single layer MoS<sub>2</sub> by oxygen plasma

Islam, Muhammad R.; Kang, Narae; Bhanu, Udai; Paudel, Hari P.; Erementchouk, Mikhail; Tetard, Laurene; Khondaker, Saiful I.

doi:10.1039/c4nr02142h

Cited by 217 publications

(185 citation statements)

References 46 publications

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“…ÑÃÓÂÃÑÕÍË ÒÎÈÐÑÍ, ÏÑÅÖÕ ÔÐËÉÂÕßÔâ ÐÂ ÚÇÕÞÓÇ ÒÑÓâAEÍÂ [201].°ÃÐÂÓÖÉÇÐÂ ÚÈÕÍÂâ ÊÂÄËÔËÏÑÔÕß ËÊÏÇÐÇÐËâ ÒÎÑÕ-ÐÑÔÕË ÊÂÓâAEÑÄ ÑÕ ÕÇÏÒÇÓÂÕÖÓÞ. ±ÓË àÕÑÏ Ô ÖÄÇÎËÚÇÐËÇÏ ÕÇÏÒÇÓÂÕÖÓÞ ÖÄÇÎËÚËÄÂÇÕÔâ ÒÓÑÄÑAEËÏÑÔÕß ÒÎÈÐÑÍ [202].…”

Section: à2unclassified

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Чернозатонский

Artyukh

2017

Успехи физических наук

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³ ÒÑÏÑÜßá ÕÇÑÓËË ×ÖÐÍÙËÑÐÂÎÂ ÒÎÑÕÐÑÔÕË ÃÞÎË ÓÂÔÔÏÑÕÓÇÐÞ ÔÎÇAEÖáÜËÇ ÏÑÐÑØÂÎßÍÑÅÇÐËAEÞ: SnS, SnSe, GeS, GeSe, ÐÂÌAEÇÐÞ ËØ ÔÕÂÃËÎßÐÞÇ ÍÑÐ×ÑÓÏÂÙËË. ¿ÍÔÒÇ-ÓËÏÇÐÕÞ ÒÑÍÂÊÂÎË, ÚÕÑ AEÂÐÐÞÇ ÔÑÇAEËÐÇÐËâ ÖÔÕÑÌÚËÄÞ Í ÑÍËÔÎÇÐËá [52].³ÇÎÇÐËAE ÑÎÑÄÂ SnSe ì ÐÑÄÞÌ AEÄÖÏÇÓÐÞÌ ÏÂÕÇÓËÂÎ Ô ÐÇÒÓâÏÑÌ ÊÂÒÓÇÜÈÐÐÑÌ ÊÑÐÑÌ, ÓÂÄÐÑÌ 1Y45 à£, ÒÑAEÄËÉ-ÐÑÔÕßá 10000 ÔÏ 2 £ À1 Ô À1 , ÏÑAEÖÎÇÏ ÀÐÅÂ 20 ë 40 ¤±Â Ë ÔÄÇÓØÏÂÎÑÌ ÕÇÒÎÑÒÓÑÄÑAEÐÑÔÕßá (`3 £Õ Ï À1 ¬ À1 ÒÓË 300 ¬). Electronic states in quasi-two-dimensional (2D) metal and semiconductor crystals can have unusual characteristics and thus can exhibit unusual electronic and optical phenomena. In this paper, the results recently obtained for a new class of 2D compounds, transition metal dichalcogenides, are presented, including those on structure, preparation methods, electronic, mechanical and optical properties, defects and their inêuence on material properties, and conditions facilitating the formation of defects. The paper considers the unique properties of mono-and multilayer materials, examines their dependence on external factors, and discusses their further application prospects. Various applications of 2D transition metal dichalcogenides are described, ranging from nanolubricants, nanocomposites and biosensors to memory cells and supercapacitors to optoelectronic, spin and photovoltaic devices.

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Section: à2unclassified

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Чернозатонский

Artyukh

2017

Успехи физических наук

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“…However, the effect of N Ã 2 -and Ga-irradiation on the 2D layered-MoS 2 in high to ultra-high vacuum (UHV) environment has not been explored. Focusing on MoS 2 , the tunability of doping, [13][14][15][16][17] optical, [18][19][20] and structural, 21 properties of the layered-MoS 2 has been reported by employing the plasma (O Ã 2 or N Ã 2 ) irradiation. However, in most of these studies, $150 Torr of the background utilized during plasma irradiation, whereas in plasma-assisted MBE (PAMBE), low background $10 À6 Torr can be used for tuning the properties of layered-MoS 2 .…”

Section: Impact Of N-plasma and Ga-irradiation On Mos 2 Layer In Molementioning

confidence: 99%

Impact of N-plasma and Ga-irradiation on MoS2 layer in molecular beam epitaxy

Mishra

Tangi

et al. 2017

Applied Physics Letters

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Recent interest in two-dimensional materials has resulted in ultra-thin devices based on the transfer of transition metal dichalcogenides (TMDs) onto other TMDs or III-nitride materials. In this investigation, we realized p-type monolayer (ML) MoS2, and intrinsic GaN/p-type MoS2 heterojunction by the GaN overgrowth on ML-MoS2/c-sapphire using the plasma-assisted molecular beam epitaxy. A systematic nitrogen plasma (N2*) and gallium (Ga) irradiation studies are employed to understand the individual effect on the doping levels of ML-MoS2, which is evaluated by micro-Raman and high-resolution X-Ray photoelectron spectroscopy (HRXPS) measurements. With both methods, p-type doping was attained and was verified by softening and strengthening of characteristics phonon modes E2g1 and A1g from Raman spectroscopy. With adequate N2*-irradiation (3 min), respective shift of 1.79 cm−1 for A1g and 1.11 cm−1 for E2g1 are obtained while short term Ga-irradiated (30 s) exhibits the shift of 1.51 cm−1 for A1g and 0.93 cm−1 for E2g1. Moreover, in HRXPS valence band spectra analysis, the position of valence band maximum measured with respect to the Fermi level is determined to evaluate the type of doping levels in ML-MoS2. The observed values of valance band maximum are reduced to 0.5, and 0.2 eV from the intrinsic value of ≈1.0 eV for N2*- and Ga-irradiated MoS2 layers, which confirms the p-type doping of ML-MoS2. Further p-type doping is verified by Hall effect measurements. Thus, by GaN overgrowth, we attained the building block of intrinsic GaN/p-type MoS2 heterojunction. Through this work, we have provided the platform for the realization of dissimilar heterostructure via monolithic approach.

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“…Though various etching schemes have been explored, [19][20][21][22][23][24][25][26][27][28][29] a scalable and controllable thickness reduction down to the mono-or few-layer regimes starting from arbitrary thickness and area has not been demonstrated. Methods utilizing material chemistry exploit either harsh chemicals 19 or reactive plasma environment, are material specific.…”

mentioning

confidence: 99%

“…Methods utilizing material chemistry exploit either harsh chemicals 19 or reactive plasma environment, are material specific. [21][22][23]28 Physical etching involves high temperature annealing, 25,27 laser assisted thermal ablation 20 or plasma environments, 24,26,29 results in degraded electrical properties. Postetch electrical characterization has not been performed in most cases, except for a few.…”

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confidence: 99%

Topography preserved microwave plasma etching for top-down layer engineering in MoS₂and other van der Waals materials

2017

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A generic and universal layer engineering strategy for van der Waals (vW) materials, scalable and compatible with the current semiconductor technology is of paramout importance in realizing all-two-dimensional logic circuits and move beyond the silicon scaling limit. In this letter, we demonstrate a scalable and highly controllable microwave plasma based layer engineering strategy for MoS 2 and other vW materials. Using this technique we etch MoS 2 flakes layer-by-layer starting from arbitrary thickness and area down to the mono-or the few-layer limit. From Raman spectroscopy, atomic force microscopy, photoluminescence spectroscopy, scanning electron microscopy and transmission electron microscopy, we confirm that the structural and morphological properties of the material have not been compromised. The process preserves the pre-etch layer topography and yields a smooth and pristine-like surface. We explore the electrical properties utilising a field effect transistor geometry and find that the mobility values of our samples are comparable to those of the pristine ones. The layer removal does not involve any reactive gasses or chemical reactions and relies on breaking the weak inter-layer vW interaction making it a generic technique for a wide spectrum of layered materials and heterostructures. We demonstrate the wide applicability of the technique by extending it to other systems such as Graphene, h-BN and WSe 2 . In addition, using the microwave plasma in combination with standard lithography, we illustrate a lateral patterning scheme for device fabrication.All-two-dimensional devices consisting of semiconducting, metallic and insulating van der Waals (vW) materials offer a comprehensive-solution to overcome the current scaling limit of the micro-electronic industry. Successful demonstrations of heterostructures by stalking various two-dimensional (2D) systems

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Tuning the electrical property via defect engineering of single layer MoS₂ by oxygen plasma

Cited by 217 publications

References 46 publications

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Impact of N-plasma and Ga-irradiation on MoS2 layer in molecular beam epitaxy

Topography preserved microwave plasma etching for top-down layer engineering in MoS₂and other van der Waals materials

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Tuning the electrical property via defect engineering of single layer MoS2 by oxygen plasma

Cited by 217 publications

References 46 publications

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Quasi-two-dimensional transition metal dichalcogenides: structure, synthesis, properties and applications

Impact of N-plasma and Ga-irradiation on MoS2 layer in molecular beam epitaxy

Topography preserved microwave plasma etching for top-down layer engineering in MoS2and other van der Waals materials

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Tuning the electrical property via defect engineering of single layer MoS₂ by oxygen plasma

Topography preserved microwave plasma etching for top-down layer engineering in MoS₂and other van der Waals materials