Exploring Chemical Bonding in Phase‐Change Materials with Orbital‐Based Indicators

Konze, Philipp M.; Dronskowski, Richard; Deringer, Volker L.

doi:10.1002/pssr.201800579

Cited by 29 publications

(27 citation statements)

References 121 publications

(106 reference statements)

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“…Figure 6 shows the COHP analyses of Ge-Sb-Te phase change materials which can also be good thermoelectrics. [59,61] By assuming a fully occupied sublattice, i.e., Ge 2 Sb 2 Te 4 , the COHP analysis shows strong antibonding interactions at the Fermi level, as indicated by the red arrow. This is not surprising, since in Ge 2 Sb 2 Te 4 an average of 3.25 p-electrons occupies the lattice sites, leading to a population of antibonding states.…”

Section: Intrinsic Defects and Carrier Concentrationmentioning

confidence: 99%

See 1 more Smart Citation

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

179

214

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Thermoelectric materials have attracted significant research interest in recent decades due to their promising application potential in interconverting heat and electricity. Unfortunately, the strong coupling between the material parameters that determine thermoelectric efficiency, i.e., the Seebeck coefficient, electrical conductivity, and thermal conductivity, complicates the optimization of thermoelectric energy converters. Main‐group chalcogenides provide a rich playground to alleviate the interdependence of these parameters. Interestingly, only a subgroup of octahedrally coordinated chalcogenides possesses good thermoelectric properties. This subgroup is also characterized by other outstanding characteristics suggestive of an exceptional bonding mechanism, which has been coined metavalent bonding. This conclusion is further supported by a map that separates different bonding mechanisms. In this map, all octahedrally coordinated chalcogenides with good performance as thermoelectrics are located in a well‐defined region, implying that the map can be utilized to identify novel thermoelectrics. To unravel the correlation between chemical bonding mechanism and good thermoelectric properties, the consequences of this unusual bonding mechanism on the band structure are analyzed. It is shown that features such as band degeneracy and band anisotropy are typical for this bonding mechanism, as is the low lattice thermal conductivity. This fundamental understanding, in turn, guides the rational materials design for improved thermoelectric performance by tailoring the chemical bonding mechanism.

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Section: Intrinsic Defects and Carrier Concentrationmentioning

confidence: 99%

Section: Band Degeneracymentioning

confidence: 99%

Chalcogenide Thermoelectrics Empowered by an Unconventional Bonding Mechanism

Cagnoni

Cojocaru‐Mirédin

et al. 2019

Adv Funct Materials

179

214

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show abstract

“…Recent development has also added two major features, namely atomic charges and related populations directly from the wavefunction as well as the -dependent COHP. The former is useful for examining ionic bonding in suchlike (or polar) compounds, for example simple salts, Zintl phases, intermetallics, thermoelectrics, or even phase-change materials, [22][23] [23], [37]- [39] whereas the latter serves useful for detailed band-wise and -point-wise chemical bonding analysis.…”

Section: Discussionmentioning

confidence: 99%

LOBSTER: Local Orbital Projections, Atomic Charges, and Chemical Bonding Analysis from Projector-Augmented-Wave-Based DFT

Nelson¹,

Ertural²,

George

et al. 2020

Preprint

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We present an update on recently developed methodology and functionality in the computer program LOBSTER (Local Orbital Basis Suite Towards Electronic-Structure Reconstruction) for chemical-bonding analysis in periodic systems. LOBSTER is based on an analytic projection from projector-augmented wave (PAW) densityfunctional theory (DFT) computations [J. Comput. Chem. 2013, 34, 2557], reconstructing chemical information in terms of local, auxiliary atomic orbitals and thereby opening the output of PAW-based DFT codes to chemical interpretation. We demonstrate how LOBSTER has been improved by taking into account time reversal symmetry, thereby speeding up the DFT and LOBSTER calculations by a factor of 2. Over the recent years, the functionalities have also been continually expanded, including accurate projected densities of states (DOS), crystal orbital Hamilton population (COHP) analysis, atomic and orbital charges, gross populations, and the recently introduced 𝒌-dependent COHP. The software is offered free-of-charge for non-commercial research.

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“…Philipp Konze et al focused on the chemical‐bonding properties of PCMs. The bonding analyses reviewed in this article were primarily made by the crystal orbital Hamilton population (COHP) method.…”

Section: Ab Initio Simulationsmentioning

confidence: 99%