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TABLE I. Details of Ag2Se1+δ samples studied in this work.
Nameδρm (%)Extra phaseAS10∼100NilAS20.005∼100NilAS30.025∼100Minor SeAS40.025∼100Minor SeAS50.05∼100SeAS6−0.01∼100AgThe powder x-ray diffraction (XRD) patterns are shown in Fig. 1. All samples formed in the previously reported orthorhombic structure (space group P212121).3030. R. Dalven and R. Gill, “ Energy gap in β-Ag2Se,” Phys. Rev. 159, 645 (1967). https://doi.org/10.1103/PhysRev.159.645 The stoichiometric (AS1) and 0.5% Se-excess samples (AS2) are found to be phase pure. However, in Ag-excess sample (AS6) and in the higher Se-excess (δ≥0.025) samples, small extra peaks are observed. These are due to unreacted Ag in the Ag-excess and unreacted Se in the Se-excess samples. The Rietveld refinement for a representative sample (AS1) is shown in Fig. S1. The lattice parameters (see the supplementary material) are in good agreement with the previous literature.22,31,3222. M. Ferhat and J. Nagao, “ Thermoelectric and transport properties of β-Ag2Se compounds,” J. Appl. Phys. 88, 813–816 (2000). https://doi.org/10.1063/1.37374131. J. Yu and H. Yun, “ Reinvestigation of the low-temperature form of Ag2Se (naumannite) based on single-crystal data,” Acta Crystallogr. E 67, i45 (2011). https://doi.org/10.1107/S160053681102853432. H. Billetter and U. Ruschewitz, “ Structural phase transitions in Ag2Se (naumannite),” Z. Anorg. Allg. Chem. 634, 241–246 (2008). https://doi.org/10.1002/zaac.200700452 The Se off-stoichiometry did not show any appreciable effect on the lattice parameters.The chemical maps for our samples are shown in Fig. S2 of the supplementary material. In stoichiometric (AS1) and 0.5% Se-excess (AS2) samples, a uniform distribution of Ag and Se is seen. In AS6, Ag metal precipitates are visible, and in AS5, Se precipitation is observed. In AS3 and AS4, small Se precipitation is seen occasionally. These observations corroborate the XRD results. This suggests that the homogeneity field δ is extremely narrow in the Ag-rich side (δ≪ −0.01), but in the Se-rich side, the solubility limit is higher than 0.005 but less than 0.025. These observations are in agreement with previous studies where δ in the Se-rich side was estimated to be ∼0.01,5,265. P. Jood, R. Chetty, and M. Ohta, “ Structural stability enables high thermoelectric performance in room temperature Ag2Se,” J. Mater. Chem. A 8, 13024–13037 (2020). https://doi.org/10.1039/D0TA02614J26. R. Simon, R. Bourke, and E. Lougher, “ Preparation and thermoelectric properties of β-Ag2Se,” Adv. Energy Convers. 3, 481–505 (1963). https://doi.org/10.1016/0365-1789(63)90064-X and, in the Ag-rich side, the solubility limit is reported to be practically nil.3333. F. Grønvold, S. Stølen, and Y. Semenov, “ Heat capacity and thermodynamic properties of silver (I) selenide, oP-Ag2Se from 300 to 406 K and of cI-Ag2Se from 406 to 900 K: Transitional behavior and formation properties,” Thermochim. Acta 399, 213–224 (2003). https://doi.org/10.1016/S0040-6031(02)00470-7In Fig. 2(a), the FESEM micrographs for a representative cold-pressed sample (AS1) is shown. For comparison, the corresponding microstructure for a SSM sample is shown in Fig. 2(b). While both the methods yield ∼100% sample density, in SSM, the grains are macroscopic with lateral dimensions exceeding 1 μm, but in AS1, large number grains varying in size from a few nanometers to several hundreds of nanometers can be seen. This is also depicted in the inset. The AS1 sample was reexamined after heating it up to 380 K, but this has no detectable effect on the morphology (see Fig. S3 of the supplementary material). A representative high-resolution TEM micrograph of sample AS1 showing highly crystalline grains with well-resolved atomic planes is shown in Fig. 2(c). The inverse fast Fourier transform (IFFT) image of the area enclosed within the white box is shown in panel (d). The interplanar spacing for the 112 family of planes is also shown.The thermoelectric properties of our samples are shown in Fig. 3. The highest temperature was kept low (∼380 K), well below the superionic transition temperature to prevent possible changes in the microstructure due to Ag migration in the superionic phase. Also, the zT of Ag2Se decreases significantly in the superionic phase; the normal phase around room temperature is, therefore, of primary interest. As shown in Fig. 3(a), in all the studied samples, σ shows an increasing trend upon heating but significant variations are observed due to Se excess. Depending on the slope dσ/dT, we can group our samples as X = (i.e., stoichiometric and slightly Ag excess) and Y = (Se-excess samples). For group X, both σ and dσ/dT are higher than for Y. In AS1, for example, σ ranges from ∼1600 S cm− 1 at 310 K to ∼2850 S cm− 1 at 370 K, whereas in AS2, the corresponding values are ∼1000 S cm− 1 (310 K) and ∼1300 S cm− 1 (380 K). The same behavior, i.e., higher σ, dσ/dT for stoichiometric and slightly Ag doped samples compared to the anion excess sample, has been found in some previous studies (see, for example, Ref. 55. P. Jood, R. Chetty, and M. Ohta, “ Structural stability enables high thermoelectric performance in room temperature Ag2Se,” J. Mater. Chem. A 8, 13024–13037 (2020). https://doi.org/10.1039/D0TA02614J). This is due to the presence of a larger concentration of Ag interstitials in samples of group X as compared to Y. Upon Se doping, Ag interstitials (Ag∗) decrease, resulting in a decrease in the carrier concentration, and hence, σ decreases.2626. R. Simon, R. Bourke, and E. Lougher, “ Preparation and thermoelectric properties of β-Ag2Se,” Adv. Energy Convers. 3, 481–505 (1963). https://doi.org/10.1016/0365-1789(63)90064-X The increasing behavior of σ is due to the minority carrier excitations. Fits using the Arrhenius relation, σ∝e−Δ/2kBT, where kB is Boltzmann constant and Δ is the activation energy, yields Δ≈0.19 eV for AS1 (representing X) and 0.05 eV for AS2 (representing Y). These values are in good agreement with previous reports.5,345. P. Jood, R. Chetty, and M. Ohta, “ Structural stability enables high thermoelectric performance in room temperature Ag2Se,” J. Mater. Chem. A 8, 13024–13037 (2020). https://doi.org/10.1039/D0TA02614J34. A. Epstein, S. Kulifay, and R. Stearns, “ Energy gap of β silver selenide,” Nature 203, 856–856 (1964). https://doi.org/10.1038/203856b0 Due to a small bandgap (Eg ≈ 0.025 eV66. M. Jin, J. Liang, P. Qiu, H. Huang, Z. Yue, L. Zhou, R. Li, L. Chen, and X. Shi, “ Investigation on low-temperature thermoelectric properties of Ag2Se polycrystal fabricated by using zone-melting method,” J. Phys. Chem. Lett. 12, 8246–8255 (2021). https://doi.org/10.1021/acs.jpclett.1c02139) and high self-doping (∼1018 cm3), the activation energy Δ in these samples is essentially Δ=Eg+εF, where εF is the Fermi energy measured from the bottom of the conduction band. The number density of Ag∗ determines εF. εF (hence Δ) is accordingly higher for the samples in group X compared to the samples in Y, which explains why dσ/dT is higher for X compared to Y. A naive estimation of εF using the free electron model, εF=(3πℏ2n)2/3/2m∗ (where symbols have their usual meaning), gives the correct order of magnitude by taking the experimentally observed carrier densities and m∗=0.18me (vide infra). Before moving on, we note that σ of our two different 2.5% Se-excess samples (AS3 and AS4) exhibit a good overlap over the whole temperature range.The temperature variation of Hall carrier concentration (nH) is shown in Fig. 3(b). The sign of Hall coefficient is negative in all cases, indicating n-type behavior. For samples in group X, nH and dnH/dT are higher than for the samples in group Y. In AS2, for example, nH at 370 K is ∼6 ×1018 cm−3, but it is as high as ∼14 ×1018 cm−3 for AS1. Due to its small bandgap, the intrinsic regime (i.e., carrier excitation across the bandgap) in Ag2Se sets in well below 300 K,66. M. Jin, J. Liang, P. Qiu, H. Huang, Z. Yue, L. Zhou, R. Li, L. Chen, and X. Shi, “ Investigation on low-temperature thermoelectric properties of Ag2Se polycrystal fabricated by using zone-melting method,” J. Phys. Chem. Lett. 12, 8246–8255 (2021). https://doi.org/10.1021/acs.jpclett.1c02139 resulting in an increasing nH(T) above room temperature. To confirm this, we measured σ for two representative samples, AS1 (higher Δ) and AS3 (lower Δ), down to 77 K. The results are shown in Fig. S4 of the supplementary material. Upon heating above 77 K, for AS1, σ remains nearly constant up to about 100 K, above which it increases slowly due to the onset of intrinsic regime. On the other hand, in AS3, due to its low activation energy, σ starts increasing upon heating above 77 K itself.The temperature dependence of Hall mobility (μH) is shown in Fig. 3(c). AS1 has a mobility of ∼1690 cm2 V−1 s−1 at 310 K, which is the highest among all the cold-pressed samples investigated here. Upon heating, μH decreases following approximately a T−α dependence with α ≈ 1.5, suggesting that the electron–phonon scattering is dominant in the pristine Ag2Se. This temperature dependence, however, gradually weakens as the off-stoichiometric increases with α → 0.6 in AS5, indicating the role of increasing defect scattering contribution. Interestingly, while nH is highest for the sample AS6, μH is highest for AS1. The decrease in μH on both sides of δ = 0 suggests that Ag or Se doping introduces additional scattering centers (point defects) leading to a mixed scattering decreasing α below the electron– phonon limit. In a recent paper by Jood et al., a similar behavior is reported but with μH peaking at 1% Se doping and nH at 0%.55. P. Jood, R. Chetty, and M. Ohta, “ Structural stability enables high thermoelectric performance in room temperature Ag2Se,” J. Mater. Chem. A 8, 13024–13037 (2020). https://doi.org/10.1039/D0TA02614J They argued that the lower mobility of their stoichiometric sample is due to the presence of a minor metastable monoclinic phase which coexists with the main orthorhombic phase and contributes to the electron scattering. They further claimed that the metastable phase can be completely suppressed by 1% Se doping, which, therefore, has the highest mobility. In our samples, however, we do not evidence any metastable phase. This may be due to the different synthesis procedures used in the two studies.The temperature variation of S is shown in Fig. 3(d). Near 300 K, S varies from −108 μV K–1 (AS6) to −144 μV K–1 (AS2). With further increase in Se doping, S decreases to −132 μV K–1 in AS5. This decrease can be attributed to the presence of Se precipitates in the higher doped sample. The elemental Se is a p-type semiconductor with very low mobility (0.12 cm2 V–1 s−1) and high value of S (∼103μV K–1 at 300 K).3535. H. W. Henkels, “ Thermoelectric power and mobility of carriers in selenium,” Phys. Rev. 77, 734 (1950). https://doi.org/10.1103/PhysRev.77.734 The thermal excitation of minority holes may also contribute to decrease in S upon heating above 300 K. Overall, the temperature variation of S follows the expected inverse correlation with the temperature variation of nH. The plot S vs nH is shown in Fig. S5 of the supplementary material. The data from several previous studies are also included. The Pisarenko plots (shown in SI) fits the (nH, S) data points for m∗ (effective mass) between 0.18me and 0.23me, where me is the free electron mass in good agreement with the literature.99. P. Wang, J.-L. Chen, Q. Zhou, Y. T. Liao, Y. Peng, J. S. Liang, and L. Miao, “ Enhancing the thermoelectric performance of Ag2Se by non-stoichiometric defects,” Appl. Phys. Lett. 120, 193902 (2022). https://doi.org/10.1063/5.0085550 This shows that excess Se does not affect either the band structure or the carrier effective mass significantly, confirming that the higher activation energy for samples AS1 and AS6 is not due to the bandgap widening but rather due to self-doping from interstitial Ag. Noteworthy is the fact that m* for Ag2Se is considerably low compared to, for example, Bi2Te3 (m* = 1.8me).44. B. Zhu, X. Liu, Q. Wang, Y. Qiu, Z. Shu, Z. Guo, Y. Tong, J. Cui, M. Gu, and J. He, “ Realizing record high performance in n-type Bi2Te3-based thermoelectric materials,” Energy Environ. Sci. 13, 2106–2114 (2020). https://doi.org/10.1039/D0EE01349H This, in turn, explains the relatively high carrier mobility of Ag2Se as compared to the other well-investigated thermoelectrics.4,36–384. B. Zhu, X. Liu, Q. Wang, Y. Qiu, Z. Shu, Z. Guo, Y. Tong, J. Cui, M. Gu, and J. He, “ Realizing record high performance in n-type Bi2Te3-based thermoelectric materials,” Energy Environ. Sci. 13, 2106–2114 (2020). https://doi.org/10.1039/D0EE01349H36. M. Saleemi, M. S. Toprak, S. Li, M. Johnsson, and M. Muhammed, “ Synthesis, processing, and thermoelectric properties of bulk nanostructured bismuth telluride (Bi2Te3),” J. Mater. Chem. 22, 725–730 (2012). https://doi.org/10.1039/C1JM13880D37. S. Roychowdhury, T. Ghosh, R. Arora, M. Samanta, L. Xie, N. K. Singh, A. Soni, J. He, U. V. Waghmare, and K. Biswas, “ Enhanced atomic ordering leads to high thermoelectric performance in AgSbTe2,” Science 371, 722–727 (2021). https://doi.org/10.1126/science.abb351738. K. Biswas, J. He, I. D. Blum, C.-I. Wu, T. P. Hogan, D. N. Seidman, V. P. Dravid, and M. G. Kanatzidis, “ High-performance bulk thermoelectrics with all-scale hierarchical architectures,” Nature 489, 414–418 (2012). https://doi.org/10.1038/nature11439 The combination of high σ and S results in high power factor (PF). The highest PF is recorded for AS2. The PF for this sample ranges from 22.2 μW cm−1 K–2 (310 K) to 24.3 μW cm−1 K–2 (370 K) (see Fig. S6 of the supplementary material). Comparable values of PF are reported in previous studies: for example, 26.6 μW cm−1 K–2 at 380 K was reported in a recent study on a very well characterized, zone-melted Ag2Se sample.66. M. Jin, J. Liang, P. Qiu, H. Huang, Z. Yue, L. Zhou, R. Li, L. Chen, and X. Shi, “ Investigation on low-temperature thermoelectric properties of Ag2Se polycrystal fabricated by using zone-melting method,” J. Phys. Chem. Lett. 12, 8246–8255 (2021). https://doi.org/10.1021/acs.jpclett.1c02139Temperature dependence of κ is shown in Fig. 4(a). κ near 300 K decreases from ∼1.4 W m−1 K–1 (AS1) to 0.8 W m−1 K–1 (AS3 and AS4). Overall, a good agreement is seen with the previous literature.5,7,10,14,405. P. Jood, R. Chetty, and M. Ohta, “ Structural stability enables high thermoelectric performance in room temperature Ag2Se,” J. Mater. Chem. A 8, 13024–13037 (2020). https://doi.org/10.1039/D0TA02614J7. S. Huang, T.-R. Wei, H. Chen, J. Xiao, M. Zhu, K. Zhao, and X. Shi, “ Thermoelectric Ag2Se: Imperfection, homogeneity, and reproducibility,” ACS Appl. Mater. Interfaces 13, 60192–60199 (2021). https://doi.org/10.1021/acsami.1c1848310. D. Yang, X. Su, F. Meng, S. Wang, Y. Yan, J. Yang, J. He, Q. Zhang, C. Uher, M. G. Kanatzidis et al., “ Facile room temperature solventless synthesis of high thermoelectric performance Ag2Se via a dissociative adsorption reaction,” J. Mater. Chem. A 5, 23243–23251 (2017). https://doi.org/10.1039/C7TA08726H14. W. Mi, P. Qiu, T. Zhang, Y. Lv, X. Shi, and L. Chen, “ Thermoelectric transport of Se-rich Ag2Se in normal phases and phase transitions,” Appl. Phys. Lett. 104, 133903 (2014). https://doi.org/10.1063/1.487050940. T. Day, F. Drymiotis, T. Zhang, D. Rhodes, X. Shi, L. Chen, and G. J. Snyder, “ Evaluating the potential for high thermoelectric efficiency of silver selenide,” J. Mater. Chem. C 1
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