194 research outputs found
Quasiparticle band alignment and stacking-independent exciton in MAZ (M = Mo, W, Ti; A= Si, Ge; Z = N, P, As)
Motivated by the recently synthesized two-dimensional semiconducting
MoSiN, we systematically investigate the quasiparticle band alignment
and exciton in monolayer MAZ (M = Mo, W, Ti; A= Si, Ge; Z = N, P, As)
using ab initio GW and Bethe-Salpeter equation calculations. Compared with the
results from density functional theory (DFT), our GW calculations reveal
substantially more significant band gaps and different absolute quasiparticle
energy but predict the same types of band alignments
Strain-induced semiconductor to metal transition in MA2Z4 bilayers
Very recently, a new type of two-dimensional layered material MoSi2N4 has
been fabricated, which is semiconducting with weak interlayer interaction, high
strength, and excellent stability. We systematically investigate theoretically
the effect of vertical strain on the electronic structure of MA2Z4 (M=Ti/Cr/Mo,
A=Si, Z=N/P) bilayers. Taking bilayer MoSi2N4 as an example, our first
principle calculations show that its indirect band gap decreases monotonically
as the vertical compressive strain increases. Under a critical strain around
22%, it undergoes a transition from semiconductor to metal. We attribute this
to the opposite energy shift of states in different layers, which originates
from the built-in electric field induced by the asymmetric charge transfer
between two inner sublayers near the interface. Similar semiconductor to metal
transitions are observed in other strained MA2Z4 bilayers, and the estimated
critical pressures to realize such transitions are within the same order as
semiconducting transition metal dichalcogenides. The semiconductor to metal
transitions observed in the family of MA2Z4 bilayers present interesting
possibilities for strain-induced engineering of their electronic properties
Interlayer Interactions in Anisotropic Atomically-thin Rhenium Diselenide
Recently, two-dimensional (2D) materials with strong in-plane anisotropic
properties such as black phosphorus have demonstrated great potential for
developing new devices that can take advantage of its reduced lattice symmetry
with potential applications in electronics, optoelectronics and
thermoelectrics. However, the selection of 2D material with strong in-plane
anisotropy has so far been very limited and only sporadic studies have been
devoted to transition metal dichalcogenides (TMDC) materials with reduced
lattice symmetry, which is yet to convey the full picture of their optical and
phonon properties, and the anisotropy in their interlayer interactions. Here,
we study the anisotropic interlayer interactions in an important TMDC 2D
material with reduced in-plane symmetry - atomically thin rhenium diselenide
(ReSe2) - by investigating its ultralow frequency interlayer phonon vibration
modes, the layer dependent optical bandgap, and the anisotropic
photoluminescence (PL) spectra for the first time. The ultralow frequency
interlayer Raman spectra combined with the first study of polarization-resolved
high frequency Raman spectra in mono- and bi-layer ReSe2 allows deterministic
identification of its layer number and crystal orientation. PL measurements
show anisotropic optical emission intensity with bandgap increasing from 1.26
eV in the bulk to 1.32 eV in monolayer, consistent with the theoretical results
based on first-principle calculations. The study of the layer-number dependence
of the Raman modes and the PL spectra reveals the relatively weak van der Waals
interaction and 2D quantum confinement in atomically-thin ReSe2.Comment: 17 pages, 5 figures, supplementary informatio
Interfacial Properties of Monolayer and Bilayer MoS2 Contacts with Metals: Beyond the Energy Band Calculations
Although many prototype devices based on two-dimensional (2D) MoS2 have been
fabricated and wafer scale growth of 2D MoS2 has been realized, the fundamental
nature of 2D MoS2-metal contacts has not been well understood yet. We provide a
comprehensive ab initio study of the interfacial properties of a series of
monolayer (ML) and bilayer (BL) MoS2-metal contacts (metal = Sc, Ti, Ag, Pt,
Ni, and Au). A comparison between the calculated and observed Schottky barrier
heights (SBHs) suggests that many-electron effects are strongly suppressed in
channel 2D MoS2 due to a charge transfer. The extensively adopted energy band
calculation scheme fails to reproduce the observed SBHs in 2D MoS2-Sc
interface. By contrast, an ab initio quantum transport device simulation better
reproduces the observed SBH in the two types of contacts and highlights the
importance of a higher level theoretical approach beyond the energy band
calculation in the interface study. BL MoS2-metal contacts have a reduced SBH
than ML MoS2-metal contacts due to the interlayer coupling and thus have a
higher electron injection efficiency.Comment: 36 pages, 13 figures, 3 table
Does P-type Ohmic Contact Exist in WSe2-metal Interfaces?
Formation of low-resistance metal contacts is the biggest challenge that
masks the intrinsic exceptional electronic properties of 2D WSe2 devices. We
present the first comparative study of the interfacial properties between ML/BL
WSe2 and Sc, Al, Ag, Au, Pd, and Pt contacts by using ab initio energy band
calculations with inclusion of the spin-orbital coupling (SOC) effects and
quantum transport simulations. The interlayer coupling tends to reduce both the
electron and hole Schottky barrier heights (SBHs) and alters the polarity for
WSe2-Au contact, while the SOC chiefly reduces the hole SBH. In the absence of
the SOC, Pd contact has the smallest hole SBH with a value no less than 0.22
eV. Dramatically, Pt contact surpasses Pd contact and becomes p-type Ohmic or
quasi-Ohmic contact with inclusion of the SOC. Our study provides a theoretical
foundation for the selection of favorable metal electrodes in ML/BL WSe2
devices
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