Overlapped Gate-Source/Drain H-shaped TFET: Proposal, Design and Linearity Analysis

In this paper, the proposed design of H-shaped TFET has been discussed. This design is providing a high Ion/Ioff ratio with better Ion. HfO2 is used for better tunneling current. With this device, Different parameters such as unit parameter, analogue parameter, and linearity parameter have been studied and investigated the output of the H-TFET. As unit parameters, the electric field, electric potential, energy band diagram, and non-local band-to-band tunneling rate (BTBT) have all been observed. Second and third-order harmonics distortion (HD2, HD3), third-order current intercept point (IIP3), third-order intermodulation distortions (IMD3), and second and third-order voltage intercept point (VIP2, VIP3) are evaluated as linearity parameters that characterize the device's distortions and linearity. We obtained Ion\({\text{=1.6×}10}^{-4}\) A/µm, Ioff=2.1\({\text{×}10}^{-19}\) A/µm, Ion /Ioff=7.6\({\text{×}10}^{14}\),threshold voltage Vt=0.3449 V. © 2017 Elsevier Inc. All rights reserved.

Optical Management of CQD/AgNP@SiNW Arrays with Highly Efficient Capability of Dye Degradation

The facile synthetic method for the preparation of incorporated carbon quantum dots (CQDs)/Ag nanoparticles (AgNPs) with well-aligned silicon nanowire (SiNW) arrays is demonstrated, offering the superior photodegradation capabilities covering UV to visible wavelength regions. By examining the morphology, microstructure, crystallinity, chemical feature, surface groups, light-emitting, and reflection characteristics, these hybrid heterostructures are systematically identified. Moreover, the involving degradation kinetics, band diagram, cycling capability, and underlying mechanism of photodegradation are investigated, validating their remarkable and reliable photocatalytic performances contributed from the strongly reduced light reflectivity, superior capability of charge separation, and sound wettability with dye solutions.

Natural sonic crystal absorber constituted of seagrass (Posidonia Oceanica) fibrous spheres

We present a 3-dimensional fully natural sonic crystal composed of spherical aggregates of fibers (called Aegagropilae) resulting from the decomposition of Posidonia Oceanica. The fiber network is first acoustically characterized, providing insights on this natural fiber entanglement due to turbulent flow. The Aegagropilae are then arranged on a principal cubic lattice. The band diagram and topology of this structure are analyzed, notably via Argand representation of its scattering elements. This fully natural sonic crystal exhibits excellent sound absorbing properties and thus represents a sustainable alternative that could outperform conventional acoustic materials.

Determination of the band structure diagram of semiconductor heterostructures applied in photovoltaics

Recently it has been found that the heterostructures of n-ZnO/p-Si are promising photovoltaic alternatives to silicon homojunctions. It is well known that the energy band diagram of a heterostructure is crucial for the understanding of its operation. This paper analyzes the ZnO/p-Si heterostructure band by using free AMPS-1D computer program simulations. The obtained numerical results are compared with theoretical calculations based on the depletion region approximation model and the Poisson’s equation for electric potential. The results of the simulation are also compared with the experimental C-V characteristics of the test n-ZnO/p-Si heterostructure. The simulated C-V characteristics is qualitatively consistent with the experimental C-V curve, which confirms the correctness of the determined band diagram of the n-ZnO/p-Si heterostructure.