High Bipolar Conductivity and Robust In‐Plane Spontaneous Electric Polarization in Selenene

Chai

2020

Small

to micrometers or wafer scale. With different compositions and crystal structures, these 2D materials differ from each other in properties, offering wide range of material choices for diverse functionalities, including electronics, optoelectronics, sensors, energy conversion, and storage. [14-21] As Si transistors approach their scaling limit, the loss of gate electrostatic control on the nanoscale channel and the direct source-to-drain tunneling increase the off-state leakage currents, raise power dissipation, and thus severely degrade the performance of Si transistors. [22-25] Because of this scaling limit of Si transistors, exploration of new channel materials is of vital importance for future nanoelectronics. Due to the ultrathin thickness and dangling-bond-free surface, the emerging 2D materials are promising candidates for continuously downward scaling. [26] The diversity of 2D materials provides broad choices of semimetals (e.g., graphene), insulators (e.g., h-BN), and semiconductors (e.g., TMDs, BP, Se, Te). [8-13] The 2D semiconductors with thickness-dependent bandgaps have been regarded as potential channel materials for replacing Si. [26] The layered nature of 2D semiconductors allows consistent thickness control with atomic precision down to the monolayer limit, leading to enhanced electrostatic control of the gate and further scaling of transistors. Also, the pristine surfaces of 2D semiconductors are free of dangling bonds even down to monolayer limit. The pristine surfaces can give rise to low density of interface trap states and consequently reduce the charge scattering. Taking TMDs as an example, molybdenum disulfide (MoS 2), one of the most widely studied 2D semiconductors is a potential replacement for Si. [27-29] Based on theoretical calculation, 2D MoS 2 is predicted to have a direct source-to-drain tunneling leakage current two orders of magnitude smaller than that of Si. [22] For monolayer MoS 2 , the leakage current will not limit the scaling of transistors down to 1 nm gate length, which is superior to Si with a sub-5 nm scaling limit. [22] With the unique layer nature, 2D semiconductors alleviate the severe short channel effect. Therefore, 2D semiconductors have been regarded as potential options for transistors with ultimate thin channel. After realizing advantages of 2D semiconductors over Si, numerous research studies focus on searching for 2D semiconductors with high carrier mobility and an appropriate bandgap and exploring their usage in future nanoelectronics. Due to the ultrathin thickness and dangling-bond-free surface, 2D materials have been regarded as promising candidates for future nanoelectronics. In recent years, group-VI elemental 2D materials have been rediscovered and found superior in electrical properties (e.g., high carrier mobility, high photoconductivity, and thermoelectric response). The outstanding semiconducting properties of group-VI elemental 2D materials enable device applications including high-performance field-effect transistors and optoelectronic devices. ...

Section: Fetsmentioning

confidence: 74%

Section: Electrical Properties Of Group-vi Elemental 2d Materialsmentioning

confidence: 99%

See 1 more Smart Citation

Emerging Group‐VI Elemental 2D Materials: Preparations, Properties, and Device Applications

Lin

Chai

2020

Small

“…the δ and ε phases [157]. Here, the nomenclature of allotropes is the same with tellurene from the aspect of structural feature, which should be noticed when reading references such as references [157,161,162]. Similar to α-Te, the α-selenene (α-Se) is composed of parallel-aligned independent one-dimensional helical chains, which has been synthesized experimentally [163,164].…”

Section: Selenenementioning

confidence: 99%

“…Similar to α-Te, the α-selenene (α-Se) is composed of parallel-aligned independent one-dimensional helical chains, which has been synthesized experimentally [163,164]. In terms of β phase, there is a disagreement on the existence of monolayer β-selenene in references [157,161,162] from theoretical prediction. It is reported in reference [162] that the β-Se is thermodynamically metastable and dynamically stable with the lattice constants of a = 4.20 Å and b = 4.99 Å, but its existence is negative in the other two references.…”

Section: Selenenementioning

confidence: 99%

Advances in photonics of recently developed Xenes

Fan

et al. 2020

Nanophotonics

Abstract Monoelemental two-dimensional materials are well known as Xenes. The representatives graphene and phosphorene have received considerable attention because of their outstanding physical properties. In recent years, the family members of Xenes have greatly increased, and the emerging ones are gaining more and more interest. In this review, we mainly focus on the recently developed Xenes in groups IIIA, VA, and VI. Comprehensive discussions of the latest progress are given in the aspects of basic physical properties and intriguing applications in photonics, optoelectronics, energy, and biomedicines.

Engineering 2D Multifunctional Ultrathin Bismuthene for Multiple Photonic Nanomedicine

Feng

Chang

et al. 2020

Adv Funct Materials

2D monoelemental nanomaterials (Xenes) have shown tremendous potential for versatile biomedical applications. Bismuth, as a heavy element in pnictogens, has acquired massive research interest due to its unique optical performance, high biocompatibility, stability, and relatively low cost. However, the utilization of 2D bismuthene in nanomedicine has not been achieved because of the difficulty in engineering bismuthene with crucial structural/compositional characteristics for satisfying strict biomedical requirements. Herein, to address this Gordian knot, a facile strategy to intercalate and delaminate Bi bulk for generating mass few‐layered 2D bismuthene with high yield by employing a water molecule mediated freezing–thawing process and sodium borohydride‐triggered reduction treatment is proposed. The resulting 2D bismuthene displays good optical performance in the near‐infrared (NIR) biowindow and can be excited via red light for reactive oxygen species generation, enabling applications in multiple photonic cancer nanomedicine settings, including photothermal hyperthermia and photodynamic therapy. Utilizing the intrinsic desirable optical absorbance and strong X‐ray attenuation of bismuthene, dual photonic therapy can be conducted under the supervision of photoacoustic/computed tomography guided multimodal imaging. This research not only offers a potential mass‐production ready, cost‐effective, and eco‐efficient methodology for engineering 2D Xenes, but also exploits an innovative 2D bismuthene based photonic cancer nanomedicine.