Achieving ZT=2.2 with Bi-doped n-type SnSe single crystals

Duong, Anh Tuan; Nguyễn, Văn Quảng; Duvjir, Ganbat; Duong, Van Thiet; Kwon, Suyong; Song, Jae Yong; Lee, Jae Ki; Lee, Ji Eun; Park, Su-Dong; Tong, Min; Lee, Jaekwang; Kim, Jungdae

doi:10.1038/ncomms13713

Cited by 366 publications

(279 citation statements)

References 17 publications

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“…Also, significant enhancements are observed in the whole temperature range, leading to the promotion of the calculated efficiency. Compared with other reported n-type SnSe crystals, [17,21] SnSe-xPbSe crystals also reveal the overall enhancement (Figure 8c). Compared with other reported n-type SnSe crystals, [17,21] SnSe-xPbSe crystals also reveal the overall enhancement (Figure 8c).…”

Section: Resultscontrasting

confidence: 47%

Realizing High‐Ranged Out‐of‐Plane ZTs in N‐Type SnSe Crystals through Promoting Continuous Phase Transition

Chang

Wang

et al. 2019

Advanced Energy Materials

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Thermoelectric technology enables direct conversion between heat and electricity. The conversion efficiency of a thermoelectric device is determined by the average dimensionless figure of merit ZTave. Here, a record high ZTave of ≈1.34 in the range of 300–723 K in n‐type SnSe based crystals is reported. The remarkable thermoelectric performance derives from the high power factor and the reduced thermal conductivity in the whole temperature range. The high power factor is realized by promoting the continuous phase transition in SnSe crystals through alloying PbSe, which results in a higher symmetry of the crystal structure and the correspondingly modified electronic band structure. Moreover, PbSe alloying induces mass and strain fluctuations, which enables the suppression of thermal transport. These findings provide a new strategy to enhance the thermoelectric performance for the continuous phase transition materials.

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Section: Resultscontrasting

confidence: 47%

Realizing High‐Ranged Out‐of‐Plane ZTs in N‐Type SnSe Crystals through Promoting Continuous Phase Transition

Chang

Wang

et al. 2019

Advanced Energy Materials

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“…The special structure also leads to ultralow thermal conductivities of 0.7 and 0.34 W m −1 K −1 for the SnSe crystal at room temperature and 773 K along the b axis and a axis, respectively. Combining the advantages of the relatively high power factor and low thermal conductivity, the ZT value, shown in Figure 3d, of the SnSe crystal reaches a high level, approaching 2.3 at 773 K for p type SnSe [11] and 2.2 at 723 K for n type SnSe [20] along the bc plane.…”

Section: Snsementioning

confidence: 98%

“…[80] According to solid state physical principles, the ZT value for bulk mate rials with a single parabolic band (SPB) along a certain direc tion can be given as: [4] The timeline for thermoelectric bulk materials with 2D structures, showing data from a superlattice, [8] SnSe, [11,[19][20][21] Bi 2 Te 3 , [12,14,16,17,[22][23][24][25][26][27][28][29][30][31][32][33][34][35][36][37][38][39][40][41] BiCuSeO, [12,[42][43][44][45][46][47][48][49][50][51][52][53][54][55][56] Na x CoO 2 , [57,58] Ca 3 Co 4 O 9 , [5...…”

Section: Strategies From Artificial Superlatticesmentioning

confidence: 99%

Promising Thermoelectric Bulk Materials with 2D Structures

2017

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Given that more than two thirds of all energy is lost, mostly as waste heat, in utilization processes worldwide, thermoelectric materials, which can directly convert waste heat to electricity, provide an alternative option for optimizing energy utilization processes. After the prediction that superlattices may show high thermoelectric performance, various methods based on quantum effects and superlattice theory have been adopted to analyze bulk materials, leading to the rapid development of thermoelectric materials. Bulk materials with two‐dimensional (2D) structures show outstanding properties, and their high performance originates from both their low thermal conductivity and high Seebeck coefficient due to their strong anisotropic features. Here, the advantages of superlattices for enhancing the thermoelectric performance, the transport mechanism in bulk materials with 2D structures, and optimization methods are discussed. The phenomenological transport mechanism in these materials indicates that thermal conductivities are reduced in 2D materials with intrinsically short mean free paths. Recent progress in the transport mechanisms of Bi2Te3‐, SnSe‐, and BiCuSeO‐based systems is summarized. Finally, possible research directions to enhance the thermoelectric performance of bulk materials with 2D structures are briefly considered.

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“…However, since intrinsic Sn vacancy shows p‐type conducting behavior, it is difficult to convert SnSe to n‐type conductor, much more difficult to activate the heavy conduction band22 if compared with p‐type SnSe. I,23 BiCl 3 ,24 Bi,25 and Br26 have been proved capable of changing the Hall coefficient from positive to negative. A decent ZT of ≈0.8 at about 773 K was obtained in SnSe 0.96 I 0.04 with room temperature electron carrier concentration ≈2.0 × 10 17 cm −3 23.…”

Section: Introductionmentioning

confidence: 97%

Heavy Doping by Bromine to Improve the Thermoelectric Properties of n‐type Polycrystalline SnSe

Wang

Chen

et al. 2018

Advanced Science

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Single crystal tin selenide (SnSe) has attracted much attention for its excellent thermoelectric performance. However, polycrystalline SnSe exhibits unsatisfactory figure‐of‐merit due to the inferior electrical properties, especially for n‐type SnSe. In this work, a high concentration of Br doping (6–12 atm%) on the Se site effectively increases the Hall carrier concentration from 1.6 × 1017 cm−3 (p‐type) in undoped SnSe to 1.3 × 1019 cm−3 (n‐type) in Br‐doped SnSe0.88Br0.12, leading to an increased electrical conductivity close to that of a single crystal. Combined with the decreased lattice thermal conductivity due to the enhanced phonon scattering by composition fluctuation and dislocations, a peak ZT of ≈1.3 at 773 K, together with the enhanced average ZT is obtained in SnSe0.9Br0.1 along the hot pressing direction.

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Achieving ZT=2.2 with Bi-doped n-type SnSe single crystals

Cited by 366 publications

References 17 publications

Realizing High‐Ranged Out‐of‐Plane ZTs in N‐Type SnSe Crystals through Promoting Continuous Phase Transition

Realizing High‐Ranged Out‐of‐Plane ZTs in N‐Type SnSe Crystals through Promoting Continuous Phase Transition

Promising Thermoelectric Bulk Materials with 2D Structures

Heavy Doping by Bromine to Improve the Thermoelectric Properties of n‐type Polycrystalline SnSe

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