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Article

Enhanced Room-Temperature Thermoelectric Performance of 2D-SnSe Alloys via Electric-Current-Assisted Sintering

Department of Materials Science and Engineering, National Yang Ming Chiao Tung University, Hsinchu 30010, Taiwan
*
Authors to whom correspondence should be addressed.
These authors contributed equally to this work.
Materials 2023, 16(2), 509; https://doi.org/10.3390/ma16020509
Submission received: 1 December 2022 / Revised: 30 December 2022 / Accepted: 2 January 2023 / Published: 5 January 2023
(This article belongs to the Special Issue Recent Progresses in Thermoelectric Materials)

Abstract

:
Single-crystalline tin-selenide (SnSe) has emerged as a high-performance and eco-friendly alternative to the lead-chalcogens often used in mid-temperature thermoelectric (TE) generators. At high temperature >800 K, the phase transition from Pnma to Cmcm causes a significant rise in the TE figure-of-merit (zT) curve. Conversely, the SnSe TE requires a booster at low temperatures, which allows broader applicability from a device perspective. Herein, a synergy of Cu alloy and Ag-coating is realized through a sequential multi-step synthesis, designed to combine different metal deposition effects. Single-crystalline (Cu2Se)x(SnSe)1−x alloys grown by the Bridgman method were then coated with a thin Ag layer by radio frequency (RF) sputtering, and the interlayer epitaxial film was observed via electric-current assisted sintering (ECAS). Consequently, the thin Ag-coating improves the electrical conductivity (σ) and reduces the thermal conductivity (κ) for (Cu2Se)0.005(SnSe)0.995+Ag alloy, increasing the zT curve at close to room temperature (373 K). The incorporation of multistep addition by ECAS enables tuning of the overall solubility of the alloy, which opens a new avenue to optimize TE performance in anisotropic 2D materials.

1. Introduction

The emerging low-carbon economy is promoting high-performance renewable energy aimed at reducing the carbon footprint of energy production and consumption. A thermoelectric (TE) material converts unused waste heat into electricity through the Seebeck effect [1], evolving as a promising low-carbon energy resource. TE materials produce electricity that can be measured by a dimensionless “figure of merit”, (zT) = (S2/ρκ) T, where S, ρ, and κ are Seebeck coefficient, electrical conductivity, and thermal conductivity, respectively. The zT formula describes the interplay between electrical transport and thermal conduction. The correlation of S, ρ, and κ leads to a complex decoupling of the power factor (PF) = S2/ρ from κ. Recently, anisotropic two-dimensional (2D) materials have arisen as promising TE candidates, because they exhibit high efficiency in PF-κ cleavage [2]. The reported SnSe single crystal reaches zT index > 2 above 800 K for its Cmcm phase that performs a high in-plane PF of 8 μWcm−1K−2 with an intrinsically low κ of 0.4 Wm−1K−1 [3,4]. Although the out-of-plane κ (along the a-axis) can reach the amorphous limit of SnSe [5], the layered structure hinders electrical transport and PF [6]. The low-temperature Pnma SnSe phase displays a relatively low-lying σ (high ρ) with a high S, reflecting its intrinsically low hole carrier density (nH) of 1017 cm−3 [7].
Alkali metals are added to SnSe single crystals, which improves the zT values in the 300–800 K temperature range [8]. Despite their excellent TE performance, hole-reduced SnSe single crystals have a narrow optimization window and reproducibility. Aside from that, the layered structure of SnSe single crystals poses an obstacle to the mass production and assembly of TE due to weakly confined inter-plane cleavage [9]. Contrary to the SnSe polycrystals, the rapid and inexpensive synthesis increases their mechanical strength [10,11]. Nevertheless, SnSe polycrystals generate lower zT due to the reduced σ. Texturing and doping SnSe polycrystals with Cu [12,13], Ag [14,15], Al [16], and Pb [17], etc., leads to enhanced σ and reduced κ, inducing SnSe-based high-performance alloys with adequate mechanical strength. Particularly when Cu2Se is used, superionic Cu+ can be kinetically disordered by Se sublattices’ elicit liquid-like behavior, which eliminates shear stress vibrations, resulting in low lattice thermal conductivity (κL) and high PF. As a heavier element, Ag has both a larger atomic radius (134 Å) and atomic mass (108) than Cu (117 Å, 63.5), suggesting that Ag addition can cause extra point defects, leading to mass and strain field fluctuations that promote a further decrease in κ and increase in PF. The performance improvements resulting from the incorporation of Cu and Ag into SnSe crystals have significant implications for the development of new alloys [14,15,18].
Following the benefit of metal incorporation in improving SnSe TE performance, this work sequentially incorporates Cu and Ag into SnSe single crystal alloys. The Bridgman method is used to alloy SnSe and Cu2Se. Thin layer Ag-coating is then performed by RF sputtering, followed by the ECAS process. A two-step approach is used to deposit Cu and Ag that accommodate different metal insertion solubility. Notably, at near room temperature, co-deposited (Cu2Se)0.005(SnSe)0.995 + Ag alloys have a higher zT value than pristine SnSe single crystals [4] and polycrystals [13]. As a result, the synergy of incorporating co-metals via multi-step synthesis improves SnSe TE performance, transforming the 2D material applicability into a green and cost-effective TE coolant.

2. Experimental

2.1. Bridgman Crystal Growth

High purity elements, Sn (99.99%), Se (99.99%), and Cu (99.99%), were used. Three important stoichiometric proportions were weighed, as indicated in Table 1, then they were placed in a conical bottom quartz ampoule (Ø12.5 mm) and sealed after evacuation (∼10−3 Pa). The ampoule was then inserted into a Bridgman reactor, heated to 1373 K for 5 h, and annealed at 1223 K for 10 h (reduction rate 1.5 mmh−1). After cooling, the obtained (Cu2Se)x(SnSe)1−x bulk ingot was cut into pieces for further use.

2.2. Ag Sputtering

RF sputtering was processed using a homemade Rex 300 instrument. The sputtered samples were then sintered by the ECAS method. In detail, the target was mounted on a metal plate, then fixed into the evacuation chamber and evacuated (10−3 Torr). After that, a cryogenic vacuum (10−3 torr) was provided for 1 h under Ar flow (15 SCCM). After heating to 100 °C, Ag sputtering (35W) was supplied for 1 h, resulting in Ag-sputtered (Cu2Se)0.005(SnSe)0.995 + Ag with a thickness of ~0.5 mm. The samples were cut and polished in a specific direction (Figure 1a) to measure the in-plane electrical and thermal transport properties of the samples.

2.3. Characterization

The crystal structure was examined by in-house powder X-ray diffraction (Bruker D2-Phaser, Ettlingen, Germany) with Cu Kα radiation (λ = 1.5406 Å). X-ray photoelectron spectroscopy (XPS, ESCA, PHI 5000 Versaprobe II, ULVAC, Chigasaki, Japan) was used to determine the valence states of the (Cu2Se)0.005(SnSe)0.995 + Ag alloy. Morphological analysis was studied with a high-resolution transmission electron microscope (HR-TEM, JEOL JEM-F200, Tokyo, Japan), and EDS mapping was conducted using a Super X EDS detector.

2.4. TE Measurement

The S and σ were measured from 300 to 575 K in a thin helium atmosphere using a ZEM instrument (ULVAC-RIKO, ZEM-3, Yokohama, Japan). The relation of κ = DCpd, density (d) was measured by the Archimedes method, and thermal diffusivity (D) was measured using laser flash instruments (LFA 467, Netzsch, Berlin, Germany). Specific heat (Cp) was calculated by the Dulong–Petit law Cp (3R/M). Hall coefficient RH, nH, and carrier mobility (μH) of the (Cu2Se)x(SnSe)1-x + Ag alloy were measured with a Hall measurement system (HMS-3000) under a reversible magnetic field (0.49T) with 10 mA current.

3. Results and Discussion

The extremely mobile Cu ions in Cu2Se [19] and the SnSe lone pair electrons [7] induce an innately low κL with better TE performance. An alloying strategy with dilute Cu2Se emerges rationally to enhance the SnSe TE efficiency in the low-temperature range [19]. For this purpose, three SnSe alloys were grown with dilute Cu2Se by the Bridgman method according to the stoichiometric composition (Cu2Se)x(SnSe)1−x (x = 0.005, 0.01, and 0.02). The X-ray diffraction patterns of the best-performing control alloy and its nominal Ag-coating of (Cu2Se)0.005(SnSe)0.995 and (Cu2Se)0.005(SnSe)0.995 +Ag at low temperature were indexed (Figure S1). According to previously observed patterns [13,20] Cu doped SnSe formed an intrinsic Cu2Se secondary phase with sharp intensity peaks at 25°, 27°, 29°, 31°, 47°, and 65°, correlating to (201), (111), (011), (400), (511), and (800) as (Cu2Se)0.005(SnSe)0.995 alloy (Figure S1a,c). In the interim, a secondary phase of AgSnSe2 emerged during Ag sputtered in the (Cu2Se)x(SnSe)1−x matrix during the SPS process, indicating the Ag presents in the bulk matrix based on preexisting models. Hence, Ag addition to (Cu2Se)0.005(SnSe)0.995 alloy, AgSnSe2, leads to impurity peaks at 43–44°, 55–56°, and 59°, attributed to (501), (312), and (420) crystal planes as (Cu2Se)0.005(SnSe)0.995 + Ag alloy (Figure S1b,d). This peak fit the XRD pattern of the previously reported impurity peak formation of the AgSnSe2 phase [21,22], demonstrating the sample’s purity. For SnSe-based alloys cut from the grown bulks (Figure 1b), transport characteristics along the in-plane direction (bc plane) were measured (Figure 1c). A custom thin film stage was employed to evaluate the in-plane PF of the alloy (Figure 1d). A disk-shaped pellet (Figure 1b) was also cut from the grown bulk to assess the in-plane κ over the temperature range of 300 K to 575 K. All x-series temperature-dependent zT curves can be computed from the average PF and κ values in triplicate (Figure 1a). The x = 0.005 performed relatively better than the other x-series alloys, reaching a zT of ~0.03 at 575 K (Figure 1a). To further improve the TE performance, the x = 0.005 alloy was incorporated with Ag via RF-sputtering, followed by ECAS. It can be seen that ECAS accelerates the epitaxial interlayer growth between sputtered Ag and the (Cu2Se)0.005(SnSe)0.995 matrix, and this enables Ag deposition in the (Cu2Se)0.005(SnSe)0.995+Ag alloy. As a result, the previously reported SnSe single crystals [4] and SnSe polycrystals [13] were greatly outperformed, with the zT curve rising to 0.0483 at 373 K.
The temperature-dependent S, σ, PF, and κ curves with the average of three repeated analysis for all bare alloys and the Ag-coated (Cu2Se)0.005(SnSe)0.995 alloy are summarized in Figure 2. For bare alloys, both the S and σ curves exhibit a descending trend with increasing x (Figure 2a,b). According to theory, an optimum nH value shall bring an increase in S and a decrease in σ, because acoustic phonons dominate the scattering in a metal or degenerate semiconductor [17,18]. The addition of Cu2Se in SnSe leads to superionic kinetic Cu+ diffusion into the Se sublattice, which can eliminate shear stress vibrations and achieve good TE properties. High Cu solubility in the SnSe alloy would stabilize the high nH, implying fewer cation vacancies. As a result of approaching x = 0.005, the maximum solubility resulted in average κ (1.76 W m−1 K−1) and PF (0.0231mW m−1 K−2), and high S (741 μV K−1) when compared to pure SnSe. However, due to the increased band gap, the nH was reduced ( 9.31 × 10 15 c m - 3 ) below the ideal range, which requires further optimization. After this, as the quantity of Cu2Se (x = 0.01, 0.02) increases, its effective mass also increases, resulting in a modest rise in nH ((1 . 31 × 10 16 c m - 3 , x = 0.01 ) and ( 1.11 × 10 16 c m - 3 , x = 0.02 ) ) , and exhibits almost identical κ (1.62 W m−1 K−1, x = 0.01 and 1.74 W m−1 K−1, x = 0.02). Due to the disordered Cu atoms during the α/β phase transition, its PF, S, and σ exhibit disordered TE competence. The superionic Cu+ atoms can be used to strengthen the Cu2Se lattices, and their additional mobility (μH) affects the overall TE properties (Table 1). The best performing sample (x = 0.005) shows an optimal nH-x (carrier-cation) exchange, resulting in higher μH transport. The highly-mobile Cu ion presumably produces a high μH that enhances σ without affecting S. Accordingly, x = 0.005 shows an improved PF curve (Figure 2c) compared to the other alloys in the x-series, allowing further incorporation of metal (Ag).
As mentioned earlier, with a heavier element of Ag with a larger atomic radius and mass (134 Å, 108) than Cu (117 Å, 63.5), Ag-coating can lead to additional point defects and mass and strain-field fluctuations that further reduce κ and increase PF. Accordingly, a significant increase in the zT curve for the Ag-coated (Cu2Se)0.005(SnSe)0.995 alloy was obtained compared to the Ag-free alloy, and this augmentation was attributed to an optimally high nH ( 3.65 × 10 17 c m - 3 ) and μH (149 cm2 V−1 s−1) that accounted for a larger σ (Figure 2b). In addition, the PF rises to ~0.149 mW/mK2 at 303 K and reaches a maximum of 0.154 mW/mK2 at 373 K, which is 15 times higher than the sample without an Ag-coating. Aside from the improved PF, the thin layer Ag-coating lowers the curve slightly (Figure 2d) due to enhanced phonon scattering, whereas high concentration causes irregularities and poor performance (x = 0.01, 0.02). If the same amount of Ag is added as in these systems, it may have a similar effect. Thus, coupling Ag with (Cu2Se)0.005(SnSe)0.995 leads to rational tuning of the band gap, nH, grain boundary, and μH, which is more likely to contribute to high TE efficiency than TE pre-Ag coated samples. Therefore, the successive suppression of holes by the ECAS process realizes improved PF and reduced κ in 2D materials, opening a new pathway for PF-κ decoupling and zT optimization. Furthermore, the Ag layer is much thinner than the (Cu2Se)0.005(SnSe)0.995 alloy, and the accuracy of the measurement and coating effect on both sides of the alloy surface was confirmed using similar test conditions. Here, the S measurement was performed on the opposite side of the alloy (free of Ag film). Temperature dependent σ exhibits unequal values on both sides (top and bottom of the alloy) because the top part (top side) of the alloy is completely covered by the Ag layer, whereas the bottom part (bottom side) of the alloy cannot be covered by the Ag layer (Figure 3). Meanwhile, uncovered Ag layer of (Cu2Se)0.005(SnSe)0.995 disk κ measurement was not performed (bottom side), because Ag coated and uncoated (Cu2Se)0.005(SnSe)0.995 alloy may have produced nearly the same κ value (Table 1); thus, we decided to discontinue further investigation of the Ag uncovered portion of the alloy.
The XPS study reveals the mechanism behind the enhanced TE performance. To confirm the coexistence of incorporated Cu and Ag, the valence states of the (Cu2Se)0.005(SnSe)0.995 + Ag alloys were analyzed by XPS. The spectra show the entire binding energy range, indicating the occurrence of Sn, Se, Cu, and Ag energy states (Figure 4a). The XPS depth profile analysis revealed atomic composition ranges of Sn & Se > 45% and Cu & Ag < 5% (Figure 4b). The XPS spectra revealed spin-orbit doublet coupling of Sn 3d5/2 and Sn 3d3/2 appearing at the binding energies of 486.5 eV and 495.0 eV, respectively, stating the existence of Sn2+ ions in the alloy (Figure 4c). The spin-orbit coupling of Se 3d splitting shows a broad peak at 54.0 eV; this remains the same for both samples, indicating that Se2− maintains its oxidation state. The substitution of Cu at the Sn site was verified by the occurrence of the 2p peaks at 933 eV. In addition, the coating of Ag doublet peaks at 367.5 eV and 374 eV is consistent with binding energies of 3d5/2 and 3d3/2, which is decisive in SnSe electronic properties and is in good agreement with the earlier report [13]. Thus, the measured atomic weights and concentrations of SnSe and deposited elements match well for ~0.3% of Sn vacancies.
To understand the mechanism and origin of the low κL, TEM analysis was performed on the best-performing (Cu2Se)0.005(SnSe)0.995 + Ag alloy. A bright field (BF) image shows the modular nanostructure of the sample (Figure 5a) with an epilayer-like Ag film topping feature on a (Cu2Se)0.005(SnSe)0.995 alloy. The dark contrasted areas are the Ag deposition, whereas the faint gray contrast corresponds to the (Cu2Se)0.005(SnSe)0.995 alloy. The high-resolution inverse FFT image displays the lattice arrangements of the (Cu2Se)0.005(SnSe)0.995 alloy (Figure 5b) and the sputtered Ag film (Figure 5e), while the corresponding selected area electron diffraction (SAED) patterns (Figure 5c,d) confirm an identical zone axis of (110) of both the Ag film and (Cu2Se)0.005(SnSe)0.995 substrate. The lattice spacing between the two apparent planes along the lateral dimension is estimated to be 1.15 nm, which reveals that a set of (110) planes stabilizes nanodomains (Figure 5e). Furthermore, the EDX elemental mapping performed during STEM imaging revealed several contrasting grain domains with a random distribution, confirming the presence of Ag, Cu, Sn, and Se within the (Cu2Se)0.005(SnSe)0.995 + Ag alloy (Figure 5f–j). From the results of TEM and STEM, the interface between the Ag film and (Cu2Se)0.005(SnSe)0.995 is semi-coherent and full of line dislocations as the lattice parameters between the matrix and the Ag film differ from each other. The interfacial mismatch and imperfections cause a significant reduction in κL and a substantial increase in the point defect scattering of the resulting alloy (Table 1). Although the (Cu2Se)0.005(SnSe)0.995+Ag alloy has a bilayer structure, note that a trace of Ag can be seen from both the EDX element mapping (Figure 5i, Figures S2 and S3) and the XPS depth profile (Figure 4b). Sputtering between the Ag film and the SnSe substrate provides another way to attenuate holes and vacancies. Note that the (Cu2Se)0.005(SnSe)0.995+Ag alloy still exhibits interfacial inhomogeneity. The contact between the adjacent layers affects the accuracy of the reported TE transport properties. Therefore, future study will focus on each side of the uniform coating and explore them systematically. For comparison, the bilayer/interface layer-based SnSe alloy TE properties were tabulated (Table S1) and correlated to this present study, and the data revealed a relatively better TE performance than the previously reported method, which encourages further establishment.

4. Conclusions

In conclusion, a low-cost, low-temperature working green route TE alloy, (Cu2Se)x(SnSe)1-x + Ag (x = 0, 0.005, 0.01, and 0.02), was synthesized by the Bridgman method, followed by the ECAS method. The in-plane nH of (Cu2Se)x(SnSe)1-x was found to be 9.31×1015 after dilute addition of Cu2Se to SnSe (x = 0.005), despite its role contributing to a high PF with a modest zT of 0.03 at 573K. Excessive hole suppression and interlayer deposition were achieved by successful Ag-coating on the (Cu2Se)0.005(SnSe)0.995 alloy, which further promotes in-plane nH of 3.65 × 1017 with good TE performance. TEM analysis of the (Cu2Se)0.005(SnSe)0.995 + Ag alloy suggests a bilayer 2D nanostructured modular feature with an interlayer between the SnSe matrix and the sputtered Ag film. This interlayer accretion optimally scatters the heat-carrying phonons and results in a lower κ. Hence, the zT of (Cu2Se)0.005(SnSe)0.995 + Ag alloy at near room-temperature is 15 times higher than that of pristine SnSe (zT = 0.0483 at 373K). The incorporation of Cu and Ag in dilute form can be considered as an effective strategy for both PF enhancement and κL reduction, thereby presenting a new key to improving zT of 2D TE materials.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ma16020509/s1. Refs. [23,24,25,26,27,28] are cited in the supplementary materials.

Author Contributions

Conceptualization, M.-Y.H. and H.-J.W.; Software, H.-W.C.; Formal analysis, Y.-C.D. and H.-W.C.; Investigation, M.-Y.H. and H.-W.C.; Data curation, M.-Y.H. and Y.-C.D.; Writing—original draft, K.M.; Writing—review & editing, H.-J.W.; Supervision, H.-J.W.; Project administration, H.-J.W.; Funding acquisition, H.-J.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Young Scholar Fellowship Program by Ministry of Science and Technology (MOST) in Taiwan, under Grant MOST 111-2628-E-A49-012 and 111-2628-E-A49-017-MY4.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

We acknowledged the financial support from the Young Scholar Fellowship Program by Ministry of Science and Technology (MOST) in Taiwan, under Grant MOST 111-2628-E-A49-012 and 111-2628-E-A49-017-MY4.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. (a) Temperature-dependent zT profiles for (Cu2Se)x(SnSe)1−x (x = 0.005, 0.01 and 0.02) and Ag-coating. The (Cu2Se)0.005(SnSe)0.995 + Ag alloy is denoted as a solid curve, and reported SnSe single-crystal [4] and polycrystal [13] are added for comparison. Inset: Pictographic of TE properties measurement along the in-plane direction (bc plane). (b) Left to right: Crystalline image for κ measurement (left, disk-shaped pellet), PF measurement (middle), cleavage plane from the as-grown bulk SnSe (right). (c) Plate-shaped SnSe alloys are sliced up to measure transport properties. (d) SnSe alloys were placed on a ZEM thin-film stage commercial apparatus for S and σ measurement.
Figure 1. (a) Temperature-dependent zT profiles for (Cu2Se)x(SnSe)1−x (x = 0.005, 0.01 and 0.02) and Ag-coating. The (Cu2Se)0.005(SnSe)0.995 + Ag alloy is denoted as a solid curve, and reported SnSe single-crystal [4] and polycrystal [13] are added for comparison. Inset: Pictographic of TE properties measurement along the in-plane direction (bc plane). (b) Left to right: Crystalline image for κ measurement (left, disk-shaped pellet), PF measurement (middle), cleavage plane from the as-grown bulk SnSe (right). (c) Plate-shaped SnSe alloys are sliced up to measure transport properties. (d) SnSe alloys were placed on a ZEM thin-film stage commercial apparatus for S and σ measurement.
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Figure 2. Temperature-dependent (a) Seebeck coefficient, S, (b) electrical conductivity, σ, (c) power factor, S2σ, (d) thermal conductivity, κ of (Cu2Se)x(SnSe)1x+Ag (x = 0.005, 0.01, and 0.02) alloys.
Figure 2. Temperature-dependent (a) Seebeck coefficient, S, (b) electrical conductivity, σ, (c) power factor, S2σ, (d) thermal conductivity, κ of (Cu2Se)x(SnSe)1x+Ag (x = 0.005, 0.01, and 0.02) alloys.
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Figure 3. The electrical conductivity measured from both sides of the (Cu2Se)0.005(SnSe)0.995+Ag alloy (top and back/bottom sides).
Figure 3. The electrical conductivity measured from both sides of the (Cu2Se)0.005(SnSe)0.995+Ag alloy (top and back/bottom sides).
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Figure 4. XPS analysis of (Cu2Se)0.005(SnSe)0.995 + Ag alloy. (a) Full surface survey spectrum, (b) depth profile, (c) high-resolution scan.
Figure 4. XPS analysis of (Cu2Se)0.005(SnSe)0.995 + Ag alloy. (a) Full surface survey spectrum, (b) depth profile, (c) high-resolution scan.
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Figure 5. TEM analysis of (Cu2Se)0.005(SnSe)0.995+Ag alloy: (a) A cross-sectional BF image, (b) IFFT image of magnified Ag layer region (c,d) SAED pattern, (e) IIFT image of selected area lattice spacing’s, (fj) Elemental mapping taken by EDX-STEM.
Figure 5. TEM analysis of (Cu2Se)0.005(SnSe)0.995+Ag alloy: (a) A cross-sectional BF image, (b) IFFT image of magnified Ag layer region (c,d) SAED pattern, (e) IIFT image of selected area lattice spacing’s, (fj) Elemental mapping taken by EDX-STEM.
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Table 1. Measured properties of (Cu2Se)x(SnSe)1−x and Ag-doped alloy at 303 K.
Table 1. Measured properties of (Cu2Se)x(SnSe)1−x and Ag-doped alloy at 303 K.
(Cu2Se)x(SnSe)1−xS
(μV K−1)
σ (S m−1)PF (mW m−1 K−2)κ (W m−1 K−1)n (cm−3)μ (cm2 V−1 s−1)
x = 0.005741150.02311.769.31 × 101591.6
x = 0.01596410.013841.621.31 × 101677.6
x = 0.02549170.002241.741.11 × 1016102.2
Ag-coated
x = 0.005
5544940.14871.433.65 × 1017149
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Manibalan, K.; Ho, M.-Y.; Du, Y.-C.; Chen, H.-W.; Wu, H.-J. Enhanced Room-Temperature Thermoelectric Performance of 2D-SnSe Alloys via Electric-Current-Assisted Sintering. Materials 2023, 16, 509. https://doi.org/10.3390/ma16020509

AMA Style

Manibalan K, Ho M-Y, Du Y-C, Chen H-W, Wu H-J. Enhanced Room-Temperature Thermoelectric Performance of 2D-SnSe Alloys via Electric-Current-Assisted Sintering. Materials. 2023; 16(2):509. https://doi.org/10.3390/ma16020509

Chicago/Turabian Style

Manibalan, Kesavan, Meng-Yuan Ho, You-Cheng Du, Hung-Wei Chen, and Hsin-Jay Wu. 2023. "Enhanced Room-Temperature Thermoelectric Performance of 2D-SnSe Alloys via Electric-Current-Assisted Sintering" Materials 16, no. 2: 509. https://doi.org/10.3390/ma16020509

APA Style

Manibalan, K., Ho, M. -Y., Du, Y. -C., Chen, H. -W., & Wu, H. -J. (2023). Enhanced Room-Temperature Thermoelectric Performance of 2D-SnSe Alloys via Electric-Current-Assisted Sintering. Materials, 16(2), 509. https://doi.org/10.3390/ma16020509

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