Comparative Study of Thermoelectric Properties of Sb2Si2Te6 and Bi2Si2Te6

Jang, Hanhwi; Abbey, Stanley; Frimpong, Brakowaa; Nguyen, Chien Viet; Ziółkowski, Pawel; Oppitz, Gregor; Kim, Moo-Hyun; Song, Jae Yong; Shin, Ho Sun; Jung, Yeon Sik

doi:10.1021/acsami.1c23351

Cited by 18 publications

(16 citation statements)

References 67 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The changes in electrical conductivity and Seebeck coefficient with temperature is driven by the carrier mobility and bipolar conduction. Additionally, the TE properties of Bi 2 Si 2 Te 6 NS/PEDOT:PSS composite film according to temperature is similar to that of other TE materials using Bi 2 Si 2 Te 6 . − …”

Section: Resultssupporting

confidence: 67%

“…The crystal structure of the Bi 2 Si 2 Te 6 is shown in Figure b. Thus, the as-fabricated Bi 2 Si 2 Te 6 crystallizes in a rhombohedral crystal structure belonging to the space group R 3̅. − The Bi 2 Si 2 Te 6 slabs are stacked along the c -axis via van der Waals interactions. The slabs consist of the Bi atoms at the center of the BiTe 6 octahedra and the ethane-like Si 2 Te 6 .…”

Section: Resultsmentioning

confidence: 99%

“…Recently, Bi 2 Si 2 Te 6 with a 2D layer structure has been studied as a potential high-performance p-type TE material. − Similar to Sb 2 Si 2 Te 6 , Bi 2 Si 2 Te 6 has a layered rhombohedral crystal structure (space group R 3̅) with three crystallographic positions. − Single crystalline Bi 2 Si 2 Te 6 has been reported to exhibit a large Seebeck coefficient and low lattice thermal conductivity. , However, pristine Bi 2 Si 2 Te 6 is not suitable for flexible TE materials due to the low flexibility of inorganic materials. Hence, in the present study, a design for improving the TE performance is proposed by incorporating Bi 2 Si 2 Te 6 NSs with the PEDOT:PSS conductive polymer matrix.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Park

Kim

2023

ACS Appl. Polym. Mater.

View full text Add to dashboard Cite

Herein, dimethyl sulfoxide (DMSO)-treated Bi 2 Si 2 Te 6 nanosheet (NS)/poly (3,4-ethylenedioxythiophene) polystyrene sulfonate (PE-DOT:PSS) composite films with enhanced thermoelectric (TE) properties and flexibility are prepared. First, the Bi 2 Si 2 Te 6 NSs for use as inorganic fillers are manufactured via a hydrothermal reaction to intercalate lithium, followed by exfoliation. The as-fabricated Bi 2 Si 2 Te 6 NS are then dispersed into the PEDOT:PSS, and Bi 2 Si 2 Te 6 NS/PEDOT:PSS composite films are fabricated via a drop-casting method. The as-synthesized Bi 2 Si 2 Te 6 NS/PEDOT:PSS composite shows an enhanced power factor due to the outstanding electrical conductivity and Seebeck coefficient of the Bi 2 Si 2 Te 6 NSs. Specifically, the composite film with 50 wt % Bi 2 Si 2 Te 6 NSs shows a maximum power factor of ∼140.4 μW/m•K 2 . Furthermore, the electrical conductivity of the Bi 2 Si 2 Te 6 NS/PEDOT:PSS composite was improved via post-synthetic treatment with DMSO. An enhanced power factor of ∼164.1 μW/m•K 2 was reached by using 50 wt % Bi 2 Si 2 Te 6 NS and 5 vol % of DMSO. The asprepared TE composite is expected to provide an important component for flexible organic/inorganic hybrid materials with enhanced TE performance.

show abstract

Section: Resultssupporting

confidence: 67%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Park

Kim

2023

ACS Appl. Polym. Mater.

View full text Add to dashboard Cite

show abstract

“…Consequently, it exhibits a power factor (PF) value as high as 19 μW cm –1 K –2 , which is much higher than those previously reported for chemically synthesized Bi 2 Te 3 (Figure c). ,, Compared with bulk Bi 2 Te 3 , the increase of the Seebeck coefficient as well as electrical conductivity with temperature strongly suggests that nanostructuring due to the solution synthesis induces a favorable change in the Fermi surface topology. Jang et al revealed that suppression of scattering at heterointerfaces does not degrade electronic properties, and therefore second phases with coherent interfaces with the matrix can limit the detrimental effects on charge carrier mobility . In our study, the established semicoherent interfaces and low-potential barriers at the conduction band of BT2 could result from the special nanostructured Bi 2 Te 3 with GBs decorated by Te nanoparticles; therefore, the unfavorable effect on electronic properties and mobility does not appear.…”

Section: Resultsmentioning

confidence: 51%

Development of Nanostructured Bi₂Te₃ with High Thermoelectric Performance by Scalable Synthesis and Microstructure Manipulations

Gayner

Menezes

Natanzon

et al. 2023

ACS Appl. Mater. Interfaces

View full text Add to dashboard Cite

Nanostructuring of thermoelectric (TE) materials leads to improved energy conversion performance; however, it requires a perfect fit between the nanoprecipitates’ chemistry and crystal structure and those of the matrix. We synthesize bulk Bi2Te3 from molecular precursors and characterize their structure and chemistry using electron microscopy and analyze their TE transport properties in the range of 300–500 K. We find that synthesis from Bi2O3 + Na2TeO3 precursors results in n-type Bi2Te3 containing a high number density (N v ∼ 2.45 × 1023 m–3) of Te-nanoprecipitates decorating the Bi2Te3 grain boundaries (GBs), which yield enhanced TE performance with a power factor (PF) of ∼19 μW cm–1 K–2 at 300 K. First-principles calculations validate the role of Te/Bi2Te3 interfaces in increasing the charge carrier concentration, density of states, and electrical conductivity. These optimized TE coefficients yield a promising TE figure of merit (zT) peak value of 1.30 at 450 K and an average zT of 1.14 from 300 to 500 K. This is one of the cutting-edge zT values recorded for n-type Bi2Te3 produced by chemical routes. We believe that this chemical synthesis strategy will be beneficial for future development of scalable n-type Bi2Te3 based devices.

show abstract

“…The speed of sound was measured by the pulse‐echo method, where an initial stress wave of ultrasonic pulse was sent and received by an identical piezoelectric transducer. [ 63 ] A longitudinal transducer with a center frequency of 5 MHz (CMR‐052, ndtXducer) and a normal incidence shear transducer with an identical frequency (SM‐052, ndtXducer) for measuring longitudinal and transverse sound velocities were used, respectively. The ultrasonic pulse signals were manipulated using an ultrasonic pulser/receiver (DPR 300, JSR Ultrasonics) and corresponding waveform was recorded using a digital oscilloscope (DSO‐X 2022A, Keysight).…”

Section: Methodsmentioning

confidence: 99%

Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe₂–SnSe Thermoelectrics

et al. 2022

Self Cite

View full text Add to dashboard Cite

figure-of-merit (zT) of a TE material, which is given by zT = S 2 σT/κ, where S, σ, T, and κ are the Seebeck coefficient, electrical conductivity, absolute temperature, and thermal conductivity, respectively. [3] Nevertheless, the competing interplay between electrical and thermal properties has stagnated the rise of zT for decades. [4] Ternary ABX 2 -type (A = group I, B = group V, X = group VI elements) compounds have gained considerable attention as promising candidates for TE applications. [5] Lone-pair electrons of B-site cations contribute to strong phonon-phonon interactions and lower the lattice thermal conductivity. [6] Therefore, several ABX 2 compounds show temperature-independent thermal conductivities unlike those of conventional TE materials. [7] This intriguing property provides a venue for modulating electronic properties with more degrees of freedom because ABX 2 compounds are relatively free from the complicated trade-off relationship between electrical and thermal properties. However, utilizing ABX 2 compounds has been limited by serious problems: an absence of rational design rules, complex phase stability, and poor reproducibility. [8,9] For example, an undoped hexagonal AgBiSe 2 shows a wide range of Seebeck coefficients from −450 to 250 µV K −1 depending on the synthesis condition (Figure 1a,b). In addition, the B-site cation determines the sign of the Seebeck coefficient, where most Sb-based ABX 2 compounds are intrinsically p-type and Bi-based Cation disordering is commonly found in multinary cubic compounds, but its effect on electronic properties has been neglected because of difficulties in determining the ordered structure and defect energetics. An absence of rational understanding of the point defects present has led to poor reproducibility and uncontrolled conduction type. AgBiSe 2 is a representative compound that suffers from poor reproducibility of thermoelectric properties, while the origins of its intrinsic n-type conductivity remain speculative. Here, it is demonstrated that cation disordering is facilitated by Bi Ag charged antisite defects in cubic AgBiSe 2 which also act as a principal donor defect that greatly controls the electronic properties. Using density functional theory calculations and in situ Raman spectroscopy, how saturation annealing with selenium vapor can stabilize p-type conductivity in cubic AgBiSe 2 alloyed with SnSe at high temperatures is elucidated. With stable and controlled hole concentration, a peak is observed in the weighted mobility and the density-ofstates effective mass in AgBiSnSe 3 , implying an increased valley degeneracy in this system. These findings corroborate the importance of considering the defect energetics for exploring the dopability of ternary thermoelectric chalcogenides and engineering electronic bands by controlling self-doping.

show abstract

Comparative Study of Thermoelectric Properties of Sb₂Si₂Te₆ and Bi₂Si₂Te₆

Cited by 18 publications

References 67 publications

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Development of Nanostructured Bi₂Te₃ with High Thermoelectric Performance by Scalable Synthesis and Microstructure Manipulations

Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe₂–SnSe Thermoelectrics

Contact Info

Product

Resources

About

Comparative Study of Thermoelectric Properties of Sb2Si2Te6 and Bi2Si2Te6

Cited by 18 publications

References 67 publications

Enhanced Thermoelectric Properties and Flexibility of 2D Bi2Si2Te6 Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Enhanced Thermoelectric Properties and Flexibility of 2D Bi2Si2Te6 Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Development of Nanostructured Bi2Te3 with High Thermoelectric Performance by Scalable Synthesis and Microstructure Manipulations

Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe2–SnSe Thermoelectrics

Contact Info

Product

Resources

About

Comparative Study of Thermoelectric Properties of Sb₂Si₂Te₆ and Bi₂Si₂Te₆

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Enhanced Thermoelectric Properties and Flexibility of 2D Bi₂Si₂Te₆ Nanosheets and PEDOT:PSS-Based Thermoelectric Composites

Development of Nanostructured Bi₂Te₃ with High Thermoelectric Performance by Scalable Synthesis and Microstructure Manipulations

Suppressing Charged Cation Antisites via Se Vapor Annealing Enables p‐Type Dopability in AgBiSe₂–SnSe Thermoelectrics