scholarly journals Conduction Band Engineering of Half-Heusler Thermoelectrics Using Orbital Chemistry

2021 ◽  
Author(s):  
Shuping Guo ◽  
Shashwat Anand ◽  
Madison K. Brod ◽  
Yongsheng Zhang ◽  
G. Jeffrey Snyder
Keyword(s):  
Valence Band ◽  
Conduction Band ◽  
High Symmetry ◽  
Electron Configuration ◽  
Band Engineering ◽  
Conduction Bands ◽  
Orbital Phase ◽  
The Difference ◽  
P Type ◽  
Orbital Character

Semiconducting half-Heusler (HH, XYZ) phases are promising thermoelectric materials owing to their versatile electronic properties. Because the valence band of half-Heusler phases benefit from the valence band extrema at several high-symmetry points in the Brillouin zone (BZ), it is possible to engineer better p-type HH materials through band convergence. However, the thermoelectric studies of n-type HH phases have been lagging behind since the conduction band minimum is always at the same high-symmetry point (X) in the BZ, giving the impression that there is little opportunity for band engineering. Here we study the n-type orbital diagram of 69 HHs, and show that there are two competing conduction bands with very different effective masses actually at the same X point in the BZ, which can be engineered to be converged. The two conduction bands are dominated by the d orbitals of X and Y atoms, respectively. The energy offset between the two bands depends on the difference in electron configuration and electronegativity of the X and Y atoms. Based on the orbital phase diagram, we provide the strategy to engineer the conduction band convergence by mixing the HH compounds with the reverse band offsets. We demonstrate the strategy by alloying VCoSn and TaCoSn. The V0.5Ta0.5CoSn mixture presents the high conduction band convergence and corresponding significantly larger density-of-states effective mass than either VCoSn or TaCoSn. Our work indicates that analyzing the orbital character of band edges provides new insight into engineering thermoelectric performance of HH compounds.

scholarly journals Electric Field Induced Twisted Bilayer Graphene Infrared Plasmon Spectrum

Nanomaterials ◽  
2021 ◽  
Vol 11 (9) ◽  
pp. 2433
Author(s):  
Jizhe Song ◽  
Zhongyuan Zhang ◽  
Naixing Feng ◽  
Jingang Wang
Keyword(s):  
Electric Field ◽  
External Electric Field ◽  
Valence Band ◽  
Conduction Band ◽  
Bilayer Graphene ◽  
Physical Mechanisms ◽  
Conduction Bands ◽  
Twisted Bilayer Graphene ◽  
The Difference ◽  
Plasmon Spectrum

In this work, we investigate the role of an external electric field in modulating the spectrum and electronic structure behavior of twisted bilayer graphene (TBG) and its physical mechanisms. Through theoretical studies, it is found that the external electric field can drive the relative positions of the conduction band and valence band to some extent. The difference of electric field strength and direction can reduce the original conduction band, and through the Fermi energy level, the band is significantly influenced by the tunable electric field and also increases the density of states of the valence band passing through the Fermi level. Under these two effects, the valence and conduction bands can alternately fold, causing drastic changes in spectrum behavior. In turn, the plasmon spectrum of TBG varies from semiconductor to metal. The dielectric function of TBG can exhibit plasmon resonance in a certain range of infrared.

scholarly journals Conduction Band Engineering of Half-Heusler Thermoelectrics Using Orbital Chemistry

2022 ◽  
Author(s):  
Shuping Guo ◽  
Shashwat Anand ◽  
Madison K. Brod ◽  
Yongsheng Zhang ◽  
G. Jeffrey Snyder
Keyword(s):  
Electronic Properties ◽  
Valence Band ◽  
Conduction Band ◽  
Thermoelectric Materials ◽  
Band Engineering

Semiconducting half-Heusler (HH, XYZ) phases are promising thermoelectric materials owing to their versatile electronic properties. Because the valence band of half-Heusler phases benefits from the valence band extrema at several...

Bulk and Surface Electronic Structure of GaN Measured Using Angle-Resolved Photoemission, Soft X-ray Emission and Soft X-ray Absorption

1996 ◽  
Vol 449 ◽  
Author(s):  
Kevin E. Smith ◽  
Sarnjeet S Dhesi ◽  
Laurent-C. Duda ◽  
Cristian B Stagarescu ◽  
J. H. Guo ◽  
...  
Keyword(s):  
Electronic Structure ◽  
Valence Band ◽  
Absorption Spectra ◽  
Conduction Band ◽  
Brillouin Zone ◽  
Emission Spectra ◽  
Partial Density ◽  
High Symmetry ◽  
X Ray ◽  
X Ray Absorption

ABSTRACTThe electronic structure of thin film wurtzite GaN has been studied using a combination of angle resolved photoemission, soft x-ray absorption and soft x-ray emission spectroscopies. We have measured the bulk valence and conduction band partial density of states by recording Ga L- and N K- x-ray emission and absorption spectra. We compare the x-ray spectra to a recent ab initio calculation and find good overall agreement. The x-ray emission spectra reveal that the top of the valence band is dominated by N 2p states, while the x-ray absorption spectra show the bottom of the conduction band as a mixture of Ga 4s and N 2p states, again in good agreement with theory. However, due to strong dipole selection rules we can also identify weak hybridization between Ga 4s- and N 2p-states in the valence band. Furthermore, a component to the N K-emission appears at approximately 19.5 eV below the valence band maximum and can be identified as due to hybridization between N 2p and Ga 3d states. We report preliminary results of a study of the full dispersion of the bulk valence band states along high symmetry directions of the bulk Brillouin zone as measured using angle resolved photoemission. Finally, we tentatively identify a non-dispersive state at the top of the valence band in parts of the Brillouin zone as a surface state.

scholarly journals Параметры зонной структуры тонких пленок Bi-=SUB=-1-x-=/SUB=-Sb-=SUB=-x-=/SUB=- (0≤ x≤ 0.15) на подложках с различным температурным расширением

2019 ◽  
Vol 53 (5) ◽  
pp. 616
Author(s):  
А.В. Суслов ◽  
В.М. Грабов ◽  
В.А. Комаров ◽  
Е.В. Демидов ◽  
С.В. Сенкевич ◽  
...  
Keyword(s):  
Thin Films ◽  
Thermal Expansion ◽  
Valence Band ◽  
Conduction Band ◽  
Chemical Potential ◽  
Plane Deformation ◽  
Charge Carriers ◽  
Galvanomagnetic Properties ◽  
Bismuth Antimony ◽  
The Difference

The report presents the positions of the conductance and valence band extremes in relation to the chemical potential of the thin bismuth–antimony films (from 0 to 15 at% Sb) on substrates with different thermal expansion. The results are based on the galvanomagnetic properties study of thermal deposited thin films. A significant increase in the concentration of charge carriers in films on substrates with a large thermal expansion was found. The results of calculating the valence band and the conduction band positions at 77 K, depending on the thermal expansion coefficient of the substrate used, are presented. The thin films plane deformation caused by the difference in the film and substrate materials thermal expansion leads to a change in the positions of the conduction band and the valence band of the films relative to their positions in a single crystal with corresponding composition

Asymmetric Interface Densities on n and p Type GaN MOS Capacitors

2006 ◽  
Vol 527-529 ◽  
pp. 1525-1528
Author(s):  
W. Huang ◽  
T. Khan ◽  
T. Paul Chow
Keyword(s):  
Density Distribution ◽  
Valence Band ◽  
Conduction Band ◽  
Interface State ◽  
State Density ◽  
Interface State Density ◽  
Mos Capacitors ◽  
Mos Capacitor ◽  
Plasma Enhanced Cvd ◽  
P Type

Both n-type and p-type GaN MOS capacitors with plasma-enhanced CVD-SiO2 as the gate oxide were characterized using both capacitance and conductance techniques. From a n type MOS capacitor, an interface state density of 3.8×1010/cm2-eV was estimated at 0.19eV near the conduction band and decreases deeper into the bandgap while from a p type MOS capacitor, an interface state density of 1.4×1011/cm2-eV 0.61eV above the valence band was estimated and decreases deeper into the bandgap. Unlike the symmetric interface state density distribution in Si, an asymmetric interface state density distribution with lower density near the conduction band and higher density near the valence band has been determined.

Conduction bands of GaxIn1−xAs and InAsxSb1−xalloys

1970 ◽  
Vol 48 (4) ◽  
pp. 463-469 ◽  
Author(s):  
William M. Coderre ◽  
John C. Woolley
Keyword(s):  
Electrical Conductivity ◽  
Band Structure ◽  
Valence Band ◽  
Conduction Band ◽  
High Temperatures ◽  
Hall Coefficient ◽  
Solidus Temperature ◽  
Energy Separation ◽  
Conduction Bands ◽  
Valence Bands

Measurements of Hall coefficient and electrical conductivity have been made on alloys of the systems GaxIn1−xAs and InAsxSb1−xover a range of temperature from 200 up to 950 °K or to 20° below the solidus temperature of the particular specimen, whichever was lower. These data have then been analyzed in terms of equations involving all the occupied conduction and valence bands in the manner described previously by Coderre and Woolley. The results give the variation of the energy separation from the valence band of the (000) conduction-band minimum as a function of the composition and temperature for both alloy systems. For a certain range of x in the InAsxSb1−x alloys, a transition to the gray-tin band structure is observed at high temperatures.

Material Design of New p-Type Tin Oxyselenide Semiconductor through Valence Band Engineering and Its Device Application

2019 ◽  
Vol 11 (43) ◽  
pp. 40214-40221 ◽  
Author(s):  
Taikyu Kim ◽  
Baekeun Yoo ◽  
Yong Youn ◽  
Miso Lee ◽  
Aeran Song ◽  
...  
Keyword(s):  
Valence Band ◽  
Material Design ◽  
Device Application ◽  
Band Engineering ◽  
P Type

scholarly journals Моделирование туннельного переноса электронов в системе полупроводник-кристаллический диэлектрик-Si(111)

2018 ◽  
Vol 52 (8) ◽  
pp. 900
Author(s):  
М.И. Векслер
Keyword(s):  
Energy Distribution ◽  
Valence Band ◽  
Conduction Band ◽  
Wave Vector ◽  
Transverse Wave ◽  
Carrier Transport ◽  
Metal Gate ◽  
Analogous Structure ◽  
Conduction Bands ◽  
Account Due

AbstractTunneling carrier transport through a thin insulator (e.g., CaF_2) layer between a Si(111) substrate and a semiconductor gate is theoretically investigated. Along with the conservation of a large transverse wave vector of tunneling particles, the limitation imposed on the availability of states in the gate is taken into account. Due to this limitation, the tunneling currents at low insulator bias are weaker than in an analogous structure with a metal gate electrode. The same feature leads to a change in the shape of the energy distribution of tunneling electrons, both in transport between the substrate and gate conduction bands and during the Si(111) conduction band–gate valence band transfer.

scholarly journals Machine Learning Chemical Guidelines for Engineering Electronic Structures in Half-Heusler Thermoelectric Materials

Research ◽  
2020 ◽  
Vol 2020 ◽  
pp. 1-8 ◽  
Author(s):  
Maxwell T. Dylla ◽  
Alexander Dunn ◽  
Shashwat Anand ◽  
Anubhav Jain ◽  
G. Jeffrey Snyder
Keyword(s):  
Machine Learning ◽  
Valence Band ◽  
Electronic Structures ◽  
Electronic Band Structure ◽  
Valence Band Maximum ◽  
Electronic Band ◽  
Band Maximum ◽  
Orbital Phase ◽  
Valence Bands ◽  
P Type

Half-Heusler materials are strong candidates for thermoelectric applications due to their high weighted mobilities and power factors, which is known to be correlated to valley degeneracy in the electronic band structure. However, there are over 50 known semiconducting half-Heusler phases, and it is not clear how the chemical composition affects the electronic structure. While all the n-type electronic structures have their conduction band minimum at either the Γ- or X-point, there is more diversity in the p-type electronic structures, and the valence band maximum can be at either the Γ-, L-, or W-point. Here, we use high throughput computation and machine learning to compare the valence bands of known half-Heusler compounds and discover new chemical guidelines for promoting the highly degenerate W-point to the valence band maximum. We do this by constructing an “orbital phase diagram” to cluster the variety of electronic structures expressed by these phases into groups, based on the atomic orbitals that contribute most to their valence bands. Then, with the aid of machine learning, we develop new chemical rules that predict the location of the valence band maximum in each of the phases. These rules can be used to engineer band structures with band convergence and high valley degeneracy.

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