Structural Complexity and Tuned Thermoelectric Properties of a Polymorph of the Zintl Phase Ca<sub>2</sub>CdSb<sub>2</sub> with a Non-centrosymmetric Monoclinic Structure

Ogunbunmi, Michael O.; Baranets, Sviatoslav; Bobev, Svilen

doi:10.1021/acs.inorgchem.2c01354

Cited by 13 publications

(8 citation statements)

References 55 publications

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“…Although the value achieved at 600 K is close to that of Ca 10 SmCdSb 9 , a striking difference between these two phases lies in their electrical transport properties captured in Figure b,d. The degenerate semiconducting state in Ca 10 NdCdSb 9 makes it satisfy one of the important criteria of a good thermoelectric material candidate. − This observation also attests to the fact that the structural/elemental configuration in the present case has resulted in near-optimal tuning conditions. This line of thought is further supported by the Hall coefficient measurements, which yield the following Hall concentrations n H at 300 K: 1.23 × 10 16 cm –3 (Ca 10 LuCdSb 9 ), 4.04 × 10 17 cm –3 (Ca 10 CeCdSb 9 ), 1.45 × 10 18 cm –3 (Ca 10 SmCdSb 9 ), and 4.68 × 10 20 cm –3 (Ca 10 NdCdSb 9 ).…”

Section: Resultssupporting

confidence: 60%

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Ogunbunmi

Bobev

2022

Chem. Mater.

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This work reports the synthesis, structure, and thermoelectric transport properties of the hole-dominated semiconductors with a general formula Ca10 RECdSb9 (RE = Y, Ce, Nd, Sm, and Lu). These materials feature unexpectedly high Seebeck coefficients, up to 650 μV/K at 600 K, and electrical resistivities on the order of 1–1000 mΩ·cm, which is an indication of a degenerate semiconducting state. For example, the Seebeck coefficient observed in Ca10NdCdSb9 (309 μV/K at 600 K) is accompanied by low and metallic-like electrical resistivity (6 mΩ·cm) and a carrier concentration of n = 4.68 × 1020 cm–3. The calculated power factor PF in Ca10NdCdSb9 is 0.88 μW/cm·K2 at 300 K, and calculations based on the single parabolic band model indicate that an optimum PF opt of 1.68 μW/cm·K2 can be achieved at that temperature for a carrier concentration of n opt = 6.62 × 1019 cm–3. The estimated thermoelectric figure of merit zT in this material when properly tuned is expected to surpass zT = 1 at 600 K.

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Section: Resultssupporting

confidence: 60%

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Ogunbunmi

Bobev

2022

Chem. Mater.

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“…[36][37][38] This interest led to the rapid expansion of Zintl phases into the realm of transition and rare-earth elements; when such elements of open core-shells are incorporated, the attendant structural diversity and physical properties can reach new heights. 20,30,[39][40][41][42][43][44] The actualization of closed-shell electronic configuration in these materials brings about their characteristic features as semiconductors or insulators as well as the diamagnetic or temperature independent paramagnetic behavior. 26 The Zintl phases combine the features of narrow band gap, intricate atomic bonding and amenability to a high degree of disorder and present a fertile playground to explore the various electronic and transport properties of materials of interests ranging from the topological phases of matter 45,46 to applications in thermoelectrics 47 and photovoltaics.…”

Section: The Zintl Phasesmentioning

confidence: 99%

“…36–38 This interest led to the rapid expansion of Zintl phases into the realm of transition and rare-earth elements; when such elements of open core-shells are incorporated, the attendant structural diversity and physical properties can reach new heights. 20,30,39–44…”

Section: Introductionmentioning

confidence: 99%

Exploiting the fraternal twin nature of thermoelectrics and topological insulators in Zintl phases as a tool for engineering new efficient thermoelectric generators

Ogunbunmi

Bobev

2023

J. Mater. Chem. C

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“…Compounds with AM 2 Pn 2 and A 2 MPn 2 stoichiometry illustrate an example of the benefits and drawbacks of this generalized understanding of layered structures . Recent studies have emphasized the importance of cation bonding, identity, disorder, and defects in Yb 2 – x Ca x CdSb 2 , Ca 2 – x Eu x CdSb 2 , Yb 2– x Eu x CdSb 2 , Ca 2– x Lu x CdSb 2 , A 2 CdP 2 (A = Ba, Sr), and AZn 2 Sb 2 (A = Ca, Sr, Yb, Eu) in determining electronic properties and structure type. ,− In addition, studies on Mg 3 Sb 2 have revealed that the Zintl formalism does not adequately describe interactions between cations and [Mg 2 Sb 2 ] 2– slabs in AMg 2 Pn 2 compounds, which cannot be considered layered structures due to isotropic bonding networks, even though they adopt the CaAl 2 Si 2 structure type. , These examples highlight the need for better understanding of chemical bonding, defects, and local structure in each system to enable optimization of thermoelectric properties.…”

Section: Introductionmentioning

confidence: 99%

Deciphering Defects in Yb_2–xEu_xCdSb₂ and Their Impact on Thermoelectric Properties

et al. 2022

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Layered Zintl phases with A2MPn2 stoichiometry are an underexplored class of potential thermoelectric materials with complex and diverse chemistry. The solid solution Yb2–x Eu x CdSb2 is an example of the promise these compounds hold, as one composition, Yb1.64Eu0.36CdSb2, has reported one of the highest zTs of any Zintl phase material at 525 K. The present study examines changes in structure and bonding of this solid solution that impacts thermoelectric performance. Pair distribution function analysis is combined with electronic structure modeling to take a chemical bonding-based approach to deconvolute the impact of defects on thermal and electronic properties in Yb2–x Eu x CdSb2. Yb2–x Eu x CdSb2 (x = 0, 0.1, 0.2, 0.3, 0.4, 0.5) samples were synthesized, and thermoelectric properties and defect chemistry were investigated. Samples from the middle of the series x = 0.2 and 0.3 were found to be the most highly defected, exhibiting Yb and Sb vacancies, as well as distortions in the Yb–Sb coordination spheres that correlate with thermoelectric properties. The highest efficiency is reported for x = 0.4 (zT ≈ 0.9 at 525 K), and the thermoelectric quality factor predicts that x = 0.3 could achieve zT > 2 by synthetically tuning the defect structure and thereby carrier concentration. The strategy of investigating local structure outlined in this study can be applied to a variety of other thermoelectric materials to provide insight into the hidden role of defect chemistry in understanding the structure–property relationships in extended solids.

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Structural Complexity and Tuned Thermoelectric Properties of a Polymorph of the Zintl Phase Ca₂CdSb₂ with a Non-centrosymmetric Monoclinic Structure

Cited by 13 publications

References 55 publications

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Exploiting the fraternal twin nature of thermoelectrics and topological insulators in Zintl phases as a tool for engineering new efficient thermoelectric generators

Deciphering Defects in Yb_2–xEu_xCdSb₂ and Their Impact on Thermoelectric Properties

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Structural Complexity and Tuned Thermoelectric Properties of a Polymorph of the Zintl Phase Ca2CdSb2 with a Non-centrosymmetric Monoclinic Structure

Cited by 13 publications

References 55 publications

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca10RECdSb9 (RE = Rare-Earth Metal)

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca10RECdSb9 (RE = Rare-Earth Metal)

Exploiting the fraternal twin nature of thermoelectrics and topological insulators in Zintl phases as a tool for engineering new efficient thermoelectric generators

Deciphering Defects in Yb2–xEuxCdSb2 and Their Impact on Thermoelectric Properties

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Structural Complexity and Tuned Thermoelectric Properties of a Polymorph of the Zintl Phase Ca₂CdSb₂ with a Non-centrosymmetric Monoclinic Structure

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Observation of Anomalously High Seebeck Coefficients in the Family of Zintl Phase Semiconductors Ca₁₀RECdSb₉ (RE = Rare-Earth Metal)

Deciphering Defects in Yb_2–xEu_xCdSb₂ and Their Impact on Thermoelectric Properties