The ability to predict the likelihood of impurity incorporation and their electronic energy levels in semiconductors is crucial for controlling its conductivity, and thus the semiconductor's performance in solar cells, photodiodes, and optoelectronics. The difficulty and expense of experimental and computational determination of impurity levels makes a data-driven machine learning approach appropriate. In this work, we show that a density functional theory-generated dataset of impurities in Cd-based chalcogenides CdTe, CdSe, and CdS can lead to accurate and generalizable predictive models of defect properties. By converting any semiconductor + impurity system into a set of numerical descriptors, regression models are developed for the impurity formation enthalpy and charge transition levels. These regression models can subsequently predict impurity properties in mixed anion CdX compounds (where X is a combination of Te, Se and S) fairly accurately, proving that although trained only on the end points, they are applicable to intermediate compositions. We make machine-learned predictions of the Fermi-level-dependent formation energies of hundreds of possible impurities in 5 chalcogenide compounds, and we suggest a list of impurities which can shift the equilibrium Fermi level in the semiconductor as determined by the dominant intrinsic defects. These 'dominating' impurities as predicted by machine learning compare well with DFT predictions, revealing the power of machine-learned models in the quick screening of impurities likely to affect the optoelectronic behavior of semiconductors.
PbTe
is one of the highest-performing known thermoelectric materials.
Much of its promising thermoelectric performance can be attributed
to high valley degeneracy due to having a valence band minimum (VBM)
and conduction band maximum (CBM) at the L-point
in the first Brillouin zone, which has 4-fold degeneracy, instead
of at Γ, which has 1-fold degeneracy. The existence of the VBM
at L has been explained by the contribution of Pb-s
states that make up the valence band edge. However, the dominance
of Te-p states and the presence of Pb-p states near the VBM suggest
that the Pb-s orbitals may not be as crucial as previously thought.
The tight-binding (TB) or linear combination of atomic orbitals (LCAO)
method of calculating electronic structures is ideally suited to gain
qualitative insights to explain how simple chemistry and bonding principles
lead to complex electronic structures of materials. In this study,
we use a physically self-consistent TB model to understand the extent
to which various atomic orbital interactions contribute to having
a VBM at L instead of Γ. Based on the dominant
interactions at play, a simple molecular orbital (MO) picture is developed
that when extended into the periodic crystal explains the shape of
the valence band dispersion between L and Γ.
We find that there is sufficient interaction between Pb-p and Te-p
states to provide the MO with the proper s-type symmetry to place
the VBM at L rather than the usual p-type symmetry
of the VB in rocksalt structures, where the VBM is at Γ. Furthermore,
we show that the VBM would be at L even if the Pb-s
states were removed and that the Pb-p states are at least as critical
of a factor in dictating the position of the VBM in PbTe and in the
other lead chalcogenides.
The recent surge
of interest in K-ion batteries necessitates a
fundamental understanding of phase stability and K ordering tendencies
in common electrode materials. We report on a first-principles study
of phase stability in layered K
x
CoO2 (0 ≤ x ≤ 1) in the O1/P3/O3
family of host structures and identify K ordering preferences within
each host. We find that the P3 host is stable at intermediate K concentrations
and exhibits a multitude of hierarchical orderings characterized by
well-ordered domains separated by antiphase boundaries. We also predict
the stability of a new family of layered structures at high K concentrations
that are highly distorted and host both octahedrally and prismatically
coordinated K within each intercalation layer.
While p-type BiCuSeO is a well-known mid-temperature oxide thermoelectric (TE) material, computations predict that superior TE performance can be realized through n-type doping. In this study, we use first-principles defect...
Valley degeneracy is a key feature of the electronic structure that benefits the thermoelectric performance of a material. Despite recent studies which claim that high valley degeneracy can be achieved...
Yb10MgSb9 is a new Zintl compound (with a composition closer to Yb10.5MgSb9) and a promising thermoelectric material first reported in this work. Undoped Yb10MgSb9 has an ultralow thermal conductivity due to crystallographic complexity and exhibits a relatively high peak p‐type Seebeck coefficient and high electrical resistivity. This is consistent with Zintl counting and density functional theory (DFT) calculations that the composition Yb10.5MgSb9 should be a semiconductor. Na is found experimentally to be an effective p‐type dopant potentially due to the replacement of Na+ for Yb2+, allowing for a significant decrease in electrical resistivity. With doping, a dramatic improvement of electrical conductivity is observed and the glass‐like thermal conductivity remains low, allowing for a significant enhancement of the thermoelectric figure of merit, zT. Doping increases the zT from 0.23 in undoped Yb10MgSb9 to 1.06 in 7 at% Na‐doped Yb10MgSb9 at 873K. This high thermoelectric performance found through Na‐doping places this material amongst the leading p‐type Zintl thermoelectrics, making it a promising candidate for future studies and high‐temperature thermoelectric applications.
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