A Perspective on Recent Advances in 2D Stanene Nanosheets

Sahoo, Sumanta Kumar; Wei, Kung‐Hwa

doi:10.1002/admi.201900752

Cited by 64 publications

(31 citation statements)

References 235 publications

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“…Several TMDO heterostructure (HS) exhibit enhanced electrical and optical performances as compared to heterostructures consisting only of organic or inorganic materials . It is worth noting that by manipulating out‐of‐plane surface (i.e., replacing S atom by Se atom) in MoS 2 and other 2D material, such as stanene, can exhibit immense potential for future spintronic system . In addition, the key advantage of the HS lies in a complete freedom of material choice in the hetero‐stacks, due to the weak vdW interlayer interaction and each layer can be freestanding through “ideally” clean interface .…”

mentioning

confidence: 99%

MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

Obaidulla

Habib

Khan

et al. 2019

Adv Materials Inter

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2D transition metal dichalcogenides (TMDs) are a promising material system for optoelectronic applications. However, their key figure of merit, the room‐temperature photoluminescence (PL), is extremely low. To overcome this challenge, TMDs need interfacing with other semiconducting materials and discover the underlying physical phenomena. Herein, the optical properties and PL mechanisms of molybdenum disulfide‐organic perylene derivative (PDI/MoS2) based type‐II heterostructures, i.e., PTCDA/MoS2 and PTCDI‐Ph/MoS2, are studied experimentally and theoretically. The PL of MoS2 in PTCDA/MoS2 is enhanced, while a dramatic PL quenching of MoS2 is observed on PTCDI‐Ph/MoS2. The significant radiative PL enhancement of PTCDA/MoS2 is primarily due to the bandgap reduction, high exciton/trion ratio, and epitaxial growth of PTCDA. In contrast, “trap‐like” states in heterointerface, relatively low exciton/trion ratio, and less ordered morphology are responsible for PL quenching of PTCDI‐Ph/MoS2 heterostructure. These findings would provoke a new way to engineer the light‐matter interactions in organic/TMD hybrids, which enables light‐emitting, light‐harvesting applications, and neuromorphic devices.

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mentioning

confidence: 99%

MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

Obaidulla

Habib

Khan

et al. 2019

Adv Materials Inter

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“…As a typical topological 2D material, 2D Sn significantly differs from stannum-based materials such as stannum protoxide and stannum oxide, characterizing particular physicochemical properties such as tunable bandgaps, chiral phases, strong spin–orbit coupling, and quantum spin Hall effect via its stable buckled structures [ 22 ]. Until now, the main synthesis method of Sn material is to deposit Sn onto various substrates through physical vapor deposition (PVD) [ 22 ]. Zhu et al [ 23 ] reported the first successful preparation of 2D SnNSs on the surface of Bi 2 Te 3 (111) substrate via molecular beam epitaxy (MBE), paving the avenue for further experimental studies.…”

Section: Introductionmentioning

confidence: 99%

“…Zhu et al [ 23 ] reported the first successful preparation of 2D SnNSs on the surface of Bi 2 Te 3 (111) substrate via molecular beam epitaxy (MBE), paving the avenue for further experimental studies. Moreover, some other researches also have achieved Sn growth on semiconductor Si(111) and InSb(111) substrate [ 24 , 25 ], metal substrates (e.g., Pt, Au, Ag, Cu, Al, Ni, Pd, Ir) [ 22 ], and semimetallic Sb(111) substrate [ 26 ] under ultrahigh vacuum (UHV) ambiance. Nevertheless, these prepared 2D Sn materials through epitaxial growth approaches suffer from some drawbacks, such as vertical scale inhomogeneity and scalable synthesis limitation [ 27 ].…”

Section: Introductionmentioning

confidence: 99%

Cryogenic Exfoliation of 2D Stanene Nanosheets for Cancer Theranostics

Ouyang

Zhang

et al. 2021

Nano-Micro Lett.

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Stanene (Sn)-based materials have been extensively applied in industrial production and daily life, but their potential biomedical application remains largely unexplored, which is due to the absence of the appropriate and effective methods for fabricating Sn-based biomaterials. Herein, we explored a new approach combining cryogenic exfoliation and liquid-phase exfoliation to successfully manufacture two-dimensional (2D) Sn nanosheets (SnNSs). The obtained SnNSs exhibited a typical sheet-like structure with an average size of ~ 100 nm and a thickness of ~ 5.1 nm. After PEGylation, the resulting PEGylated SnNSs (SnNSs@PEG) exhibited good stability, superior biocompatibility, and excellent photothermal performance, which could serve as robust photothermal agents for multi-modal imaging (fluorescence/photoacoustic/photothermal imaging)-guided photothermal elimination of cancer. Furthermore, we also used first-principles density functional theory calculations to investigate the photothermal mechanism of SnNSs, revealing that the free electrons in upper and lower layers of SnNSs contribute to the conversion of the photo to thermal. This work not only introduces a new approach to fabricate 2D SnNSs but also establishes the SnNSs-based nanomedicines for photonic cancer theranostics. This new type of SnNSs with great potential in the field of nanomedicines may spur a wave of developing Sn-based biological materials to benefit biomedical applications.

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“…With the discovery of graphene and other two-dimensional atomic crystals, the search for new 2D nanomaterials with unusual electrophysical properties began, as well as the development of various electronic devices based on it [13]- [15]. Various technological methods for synthesizing two-dimensional monoatomic crystals based on elements of the fourth group of the periodic table are already known: germanene [16], silicene [17], borophene [18], stanene [19], phosphorene [20], etc., as well as 2D crystals based on carbides, oxides, chlorides, nitrides, transition metal dichalcogenides, etc. [21].…”

Section: Introductionmentioning

confidence: 99%

Computer Simulation of the Electric Transport Properties of the FeSe Monolayer

Sergeyev

Zhanturina

Myasnikova

et al. 2020

Latvian Journal of Physics and Technical Sciences

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The paper deals with the model research of electric transport characteristics of stressed and non-stressed FeSe monolayers. Transmission spectra, current-voltage characteristic (CVC) and differential conductivity spectra of two-dimensional FeSe nanostructure have been calculated within the framework of the density functional theory and non-equilibrium Green’s functions (DFT + NEGF). It has been shown that the electrophysical properties depend on the geometry of the sample, the substrate, and the lattice constant. On CVC of non-stressed sample in the range from −1.2 V to −1 and from 1.2 V to 1.4 V, a region of negative differential resistance (NDR) has been observed. NDR is at both signs of the applied voltage due to the symmetry of the nanostructure. d2I/dV2 is used to determine the nature of the electron-phonon interaction and the features of quasiparticle tunnelling in stressed and non-stressed samples. The results obtained can be useful for calculating new elements of 2D nanoelectronics.

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A Perspective on Recent Advances in 2D Stanene Nanosheets

Cited by 64 publications

References 235 publications

MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

Cryogenic Exfoliation of 2D Stanene Nanosheets for Cancer Theranostics

Computer Simulation of the Electric Transport Properties of the FeSe Monolayer

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A Perspective on Recent Advances in 2D Stanene Nanosheets

Cited by 64 publications

References 235 publications

MoS2 and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

MoS2 and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

Cryogenic Exfoliation of 2D Stanene Nanosheets for Cancer Theranostics

Computer Simulation of the Electric Transport Properties of the FeSe Monolayer

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MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement

MoS₂ and Perylene Derivative Based Type‐II Heterostructure: Bandgap Engineering and Giant Photoluminescence Enhancement