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1. Roadmap on energy harvesting materials

Author

Pecunia, Vincenzo, Silva, S Ravi P, Phillips, Jamie D, Artegiani, Elisa, Romeo, Alessandro, Shim, Hongjae, Park, Jongsung, Kim, Jin Hyeok, Yun, Jae Sung, Welch, Gregory C, Larson, Bryon W, Creran, Myles, Laventure, Audrey, Sasitharan, Kezia, Flores-Diaz, Natalie, Freitag, Marina, Xu, Jie, Brown, Thomas M, Li, Benxuan, Wang, Yiwen, Li, Zhe, Hou, Bo, Hamadani, Behrang H, Defay, Emmanuel, Kovacova, Veronika, Glinsek, Sebastjan, Kar-Narayan, Sohini, Bai, Yang, Bin Kim, Da, Cho, Yong Soo, Žukauskaitė, Agnė, Barth, Stephan, Fan, Feng Ru, Wu, Wenzhuo, Costa, Pedro, del Campo, Javier, Lanceros-Mendez, Senentxu, Khanbareh, Hamideh, Wang, Zhong Lin, Pu, Xiong, Pan, Caofeng, Zhang, Renyun, Xu, Jing, Zhao, Xun, Zhou, Yihao, Chen, Guorui, Tat, Trinny, Ock, Il Woo, Chen, Jun, Graham, Sontyana Adonijah, Yu, Jae Su, Huang, Ling-Zhi, Li, Dan-Dan, Ma, Ming-Guo, Luo, Jikui, Jiang, Feng, Lee, Pooi See, Dudem, Bhaskar, Vivekananthan, Venkateswaran, Kanatzidis, Mercouri G, Xie, Hongyao, Shi, Xiao-Lei, Chen, Zhi-Gang, Riss, Alexander, Parzer, Michael, Garmroudi, Fabian, Bauer, Ernst, Zavanelli, Duncan, Brod, Madison K, Al Malki, Muath, Snyder, G Jeffrey, Kovnir, Kirill, Kauzlarich, Susan M, Uher, Ctirad, Lan, Jinle, Lin, Yuan-Hua, Fonseca, Luis, Morata, Alex, Martin-Gonzalez, Marisol, Pennelli, Giovanni, Berthebaud, David, Mori, Takao, Quinn, Robert J, Bos, Jan-Willem G, Candolfi, Christophe, Gougeon, Patrick, Gall, Philippe, Lenoir, Bertrand, Venkateshvaran, Deepak, Kaestner, Bernd, Zhao, Yunshan, Zhang, Gang, Nonoguchi, Yoshiyuki, Schroeder, Bob C, Bilotti, Emiliano, Menon, Akanksha K, Urban, Jeffrey J, Fenwick, Oliver, Asker, Ceyla, and Talin, A Alec

Subjects
Engineering, Materials Engineering, Affordable and Clean Energy, energy harvesting materials, photovoltaics, thermoelectric energy harvesting, piezoelectric energy harvesting, triboelectric energy harvesting, radiofrequency energy harvesting, sustainability, Macromolecular and materials chemistry, Physical chemistry, Materials engineering
Abstract

Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere.

Published
2023

4. Generation of T-cell-receptor-negative CD8αβ-positive CAR T cells from T-cell-derived induced pluripotent stem cells.

Author

van der Stegen, Sjoukje, Lindenbergh, Pieter, Petrovic, Roseanna, Xie, Hongyao, Diop, Mame, Alexeeva, Vera, Shi, Yuzhe, Mansilla-Soto, Jorge, Hamieh, Mohamad, Eyquem, Justin, Cabriolu, Annalisa, Wang, Xiuyan, Abujarour, Ramzey, Lee, Tom, Clarke, Raedun, Valamehr, Bahram, Themeli, Maria, Riviere, Isabelle, and Sadelain, Michel

Subjects
Mice, Animals, Humans, T-Lymphocytes, Induced Pluripotent Stem Cells, Receptors, Antigen, T-Cell, CD8 Antigens, Receptors, Chimeric Antigen
Abstract

The production of autologous T cells expressing a chimaeric antigen receptor (CAR) is time-consuming, costly and occasionally unsuccessful. T-cell-derived induced pluripotent stem cells (TiPS) are a promising source for the generation of off-the-shelf CAR T cells, but the in vitro differentiation of TiPS often yields T cells with suboptimal features. Here we show that the premature expression of the T-cell receptor (TCR) or a constitutively expressed CAR in TiPS promotes the acquisition of an innate phenotype, which can be averted by disabling the TCR and relying on the CAR to drive differentiation. Delaying CAR expression and calibrating its signalling strength in TiPS enabled the generation of human TCR- CD8αβ+ CAR T cells that perform similarly to CD8αβ+ CAR T cells from peripheral blood, achieving effective tumour control on systemic administration in a mouse model of leukaemia and without causing graft-versus-host disease. Driving T-cell maturation in TiPS in the absence of a TCR by taking advantage of a CAR may facilitate the large-scale development of potent allogeneic CD8αβ+ T cells for a broad range of immunotherapies.

Published
2022

7. Implications and Optimization of Domain Structures in IV–VI High-Entropy Thermoelectric Materials

Author

Liu, Yukun, primary, Xie, Hongyao, additional, Li, Zhi, additional, dos Reis, Roberto, additional, Li, Juncen, additional, Hu, Xiaobing, additional, Meza, Paty, additional, AlMalki, Muath, additional, Snyder, G. Jeffrey, additional, Grayson, Matthew A., additional, Wolverton, Christopher, additional, Kanatzidis, Mercouri G., additional, and Dravid, Vinayak P., additional

Published
2024
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9. Li3Sb7Se12: A Pavonite Homologue with Ultralow Thermal Conductivity

Author

Iyer, Abishek K., Shahabfar, Shima, Au, Alann P., Xie, Hongyao, Pournara, Anastasia D., Wolverton, Christopher, and Kanatzidis, Mercouri G.

Abstract

Lithium-containing semiconductors have applications in solid-state batteries, thermoelectrics, and neutron detectors. Li3Sb7Se12is a new ternary semiconductor isostructural to the mineral benjaminite (Ag3Sb7S12) crystallizing in monoclinic space group C2/m. Benjaminite belongs to the pavonite mineral family with the general formula Mn+1(Bi/Sb)2Qn+5(n= 0–8), where nis the octahedral building block length consisting of face-sharing octahedra. Li3Sb7Se12belongs to n= 7, and it differs from benjaminite by exhibiting occupancy disorder between Li+and Sb3+atoms. It exhibits exceptionally low lattice thermal conductivities of 0.53–0.37 W m–1K–1in the temperature range 300–873 K and is a p-type semiconductor. Chemical bonding analysis using DFT calculations indicates that hierarchical bonding and the distorted coordination environment of antimony play a prominent role in its heat transport properties, leading to ultralow lattice thermal conductivity, while selenium dominates the electronic structure near the bandgap.

Published
2024
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12. Modifying Roles of CuSbSe2 in Realizing High Thermoelectric Performance of GeTe.

Author

Jin, Yang, Qiu, Yuting, Bai, Shulin, Xie, Hongyao, Liu, Shibo, Hong, Tao, Gao, Xiang, Wen, Yi, and Zhao, Li‐Dong

Subjects
THERMOELECTRIC conversion, CARRIER density, MULTIPLE scattering (Physics), ENERGY conversion, COPPER, THERMAL conductivity, THERMOELECTRIC materials
Abstract

Thermoelectric materials are widely researched for their energy conversion capabilities in the fields of power generation and refrigeration. And a superior thermoelectric conversion efficiency requires an excellent power factor and low thermal conductivity. Herein, a remarkable thermoelectric figure of merit(ZT) ∼ 2.6 at 673 K is realized in GeTe with 20% addition of CuSbSe2. Multiple synergistic effects of CuSbSe2 alloying collectively contribute to the excellent thermoelectric performance in GeTe. CuSbSe2 alloying effectively tunes ultrahigh carrier density of GeTe to the optimum. The introduction of Cu, Sb, and Se atoms create numerous point defects that scatter high‐frequency phonons. Additionally, surplus CuSbSe2 facilitates the formation of copper‐selenium phases, which embed at grain boundaries and generate interfaces after sintering. Combining the planar defects evolved from Ge vacancies, multi‐dimension defects effectively scatter multiple frequency phonons. An extraordinarily low lattice thermal conductivity of 0.3 Wm−1 K−1 at 673 K is obtained, approaching the theoretical estimation predicted by Cahill model. Eventually, the peak conversion efficiency of 7.4% is obtained in segmented device with ΔT of 419 K. The commingled effects of CuSbSe2 in GeTe further open up an elitist route to designing high‐performance materials. [ABSTRACT FROM AUTHOR]

Published
2024
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17. Realizing thermoelectric cooling and power generation in N-type PbS0.6Se0.4 via lattice plainification and interstitial doping.

Author

Wang, Lei, Wen, Yi, Bai, Shulin, Chang, Cheng, Li, Yichen, Liu, Shan, Liu, Dongrui, Wang, Siqi, Zhao, Zhe, Zhan, Shaoping, Cao, Qian, Gao, Xiang, Xie, Hongyao, and Zhao, Li-Dong

Subjects
THERMOELECTRIC generators, THERMOELECTRIC cooling, THERMOELECTRIC power, HEAT recovery, THERMOELECTRIC apparatus & appliances, ELECTRIC power, BIOELECTROCHEMISTRY
Abstract

Thermoelectrics have great potential for use in waste heat recovery to improve energy utilization. Moreover, serving as a solid-state heat pump, they have found practical application in cooling electronic products. Nevertheless, the scarcity of commercial Bi2Te3 raw materials has impeded the sustainable and widespread application of thermoelectric technology. In this study, we developed a low-cost and earth-abundant PbS compound with impressive thermoelectric performance. The optimized n-type PbS material achieved a record-high room temperature ZT of 0.64 in this system. Additionally, the first thermoelectric cooling device based on n-type PbS was fabricated, which exhibits a remarkable cooling temperature difference of ~36.9 K at room temperature. Meanwhile, the power generation efficiency of a single-leg device employing our n-type PbS material reaches ~8%, showing significant potential in harvesting waste heat into valuable electrical power. This study demonstrates the feasibility of sustainable n-type PbS as a viable alternative to commercial Bi2Te3, thereby extending the application of thermoelectrics. The authors fabricate a thermoelectric cooling device based on n-type PbS based material, which exhibits a remarkable cooling temperature difference of 36.9 K at room temperature, and the single-leg power generation efficiency of 8%. [ABSTRACT FROM AUTHOR]

Published
2024
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18. Network Pharmacology Analysis of Liquid-Cultured Armillaria ostoyae Mycelial Metabolites and Their Molecular Mechanism of Action against Gastric Cancer.

Author

Wang, Zhishuo, Wang, Ruiqi, Na, Zhiguo, Liang, Shanshan, Wu, Fan, Xie, Hongyao, Zhang, Xue, Xu, Wei, and Wang, Xin

Subjects
STOMACH cancer, ETHANOL, METABOLITES, MOLECULAR docking, CELL culture, PHARMACOLOGY, EDIBLE mushrooms
Abstract

Armillaria sp. are traditional edible medicinal mushrooms with various health functions; however, the relationship between their composition and efficacy has not yet been determined. Here, the ethanol extract of liquid-cultured Armillaria ostoyae mycelia (AOME), a pure wild Armillaria sp. strain, was analyzed using UHPLC-QTOF/MS, network pharmacology, and molecular docking techniques. The obtained extract affects various metabolic pathways, such as JAK/STAT and PI3K/AKT. The extract also contains important compounds such as 4-(dimethylamino)-N-[7-(hydroxyamino)-7-oxoheptyl] benzamide, isoliquiritigenin, and 7-hydroxycoumarin. Moreover, the extract targets key proteins, including EGFR, SCR, and IL6, to suppress the progression of gastric cancer, thereby synergistically inhibiting cancer development. The molecular docking analyses indicated that the main compounds stably bind to the target proteins. The final cell culture experimental data showed that the ethanol extract inhibited MGC-803 gastric cancer cells. In summary, our research revealed the beneficial components of AOME for treating gastric cancer and its associated molecular pathways. However, further research is needed to confirm its effectiveness and safety in gastric cancer patients. [ABSTRACT FROM AUTHOR]

Published
2024
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23. Unraveling the Role of Entropy in Thermoelectrics: Entropy-Stabilized Quintuple Rock Salt PbGeSnCdxTe3+x

Author

Liu, Yukun, primary, Xie, Hongyao, additional, Li, Zhi, additional, Zhang, Yinying, additional, Malliakas, Christos D., additional, Al Malki, Muath, additional, Ribet, Stephanie, additional, Hao, Shiqiang, additional, Pham, Thang, additional, Wang, Yuankang, additional, Hu, Xiaobing, additional, dos Reis, Roberto, additional, Snyder, G. Jeffrey, additional, Uher, Ctirad, additional, Wolverton, Christopher, additional, Kanatzidis, Mercouri G., additional, and Dravid, Vinayak P., additional

Published
2023
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24. Roadmap on energy harvesting materials

Author

Fonds de Recherche du Québec, Canada Research Chairs, University of Calgary, Department of Energy (US), Pecunia, Vincenzo, Silva, S.Ravi P., Phillips, Jamie D., Artegiani, Elisa, Romeo, Alessandro, Shim, Hongjae, Park, Jongsung, Kim, Jin Hyeok, Yun, Jae Sung, Welch, Gregory C., Larson, Bryon W., Brod, Madison K., Al Malki, Muath, G Jeffrey Snyder, Kirill Kovnir, Kauzlarich, Susan M., Uher, Ctirad, Lan, Jinle, Lin, Yuan-Hua, Fonseca. Luis, Morata, Alex, Candolfi, Christophe, Martín-González, Marisol, Pennelli, Giovanni, Berthebaud, David, Mori, Takao, Quinn, Robert J., Bos, Jan-Willem G., Gougeon, Patrick, Gall, Philippe, Lenoir, Bertrand, Venkateshvaran, Deepak, Kaestner, Bernd, Zhao, Yunshan, Zhang, Gang, Nonoguchi, Yoshiyuki, Schroeder,Bob C., Anthopoulos, Thomas D., Bilotti, Emiliano, Menon, Akanksha K., Urban, Jeffrey J., Fenwick, Oliver, Asker, Ceyla, Talin, A. Alec, Losi, Tommaso, Viola, Fabrizio, Caironi, Mario., Georgiadou, Dimitra G., Ding, Li, Peng, Lian-Mao, Wang, Zhenxing, Wei,Muh-Dey, Negra, Renato, Creran, Myles, Lemme, Max C., Wagih, Mahmoud, Beeby, Steve, Ibn-Mohammed, Taofeeq, Mustapha, K. B., Joshi, A. P., Laventure, Audrey, Sasitharan, Kezia, Flores-Diaz, Natalie, Freitag, Marina, Xu, Jie, Brown, Thomas M., Li, Benxuan, Wang, Yiwen, Li, Zhe, Hou, Bo, Hamadani, Behrang H., Defay, Emmanuel, Kovacova, Veronika, Glinsek, Sebastjan, Kar-Narayan, Sohini, Bai, Yang, Kim, Da Bin, Cho, Yong Soo, Žukauskaitė, Agnė, Barth, Stephan, Fan, Feng Ru, Wu, Wenzhuo, Costa, Pedro, Campo, Javier del, Lanceros-Mendez, Senentxu, Khanbareh, Hamideh, Wang, Zhong Lin, Pu, Xiong, Pan, Caofeng, Zhang, Renyun, Xu, Jing, Zhao, Xun, Zhou, Yihao, Chen, Guorui, Tat, Trinny, Ock, Il Woo, Chen, Jun, Sontyana Adonijah Graham, Yu, Jae Su, Huang, Ling-Zhi, Li, Dan-Dan, Ma, Ming-Guo, Luo, Jikui, Jiang, Feng, Lee, Pooi See, Dudem, Bhaskar, Vivekananthan, Venkateswaran, Kanatzidis, Mercouri G., Xie, Hongyao, Shi, Xiao-Lei, Chen, Zhi-Gang, Riss, Alexander, Parzer, Michael, Garmroudi, Fabian, Bauer, Ernst, Zavanelli, Duncan, Fonds de Recherche du Québec, Canada Research Chairs, University of Calgary, Department of Energy (US), Pecunia, Vincenzo, Silva, S.Ravi P., Phillips, Jamie D., Artegiani, Elisa, Romeo, Alessandro, Shim, Hongjae, Park, Jongsung, Kim, Jin Hyeok, Yun, Jae Sung, Welch, Gregory C., Larson, Bryon W., Brod, Madison K., Al Malki, Muath, G Jeffrey Snyder, Kirill Kovnir, Kauzlarich, Susan M., Uher, Ctirad, Lan, Jinle, Lin, Yuan-Hua, Fonseca. Luis, Morata, Alex, Candolfi, Christophe, Martín-González, Marisol, Pennelli, Giovanni, Berthebaud, David, Mori, Takao, Quinn, Robert J., Bos, Jan-Willem G., Gougeon, Patrick, Gall, Philippe, Lenoir, Bertrand, Venkateshvaran, Deepak, Kaestner, Bernd, Zhao, Yunshan, Zhang, Gang, Nonoguchi, Yoshiyuki, Schroeder,Bob C., Anthopoulos, Thomas D., Bilotti, Emiliano, Menon, Akanksha K., Urban, Jeffrey J., Fenwick, Oliver, Asker, Ceyla, Talin, A. Alec, Losi, Tommaso, Viola, Fabrizio, Caironi, Mario., Georgiadou, Dimitra G., Ding, Li, Peng, Lian-Mao, Wang, Zhenxing, Wei,Muh-Dey, Negra, Renato, Creran, Myles, Lemme, Max C., Wagih, Mahmoud, Beeby, Steve, Ibn-Mohammed, Taofeeq, Mustapha, K. B., Joshi, A. P., Laventure, Audrey, Sasitharan, Kezia, Flores-Diaz, Natalie, Freitag, Marina, Xu, Jie, Brown, Thomas M., Li, Benxuan, Wang, Yiwen, Li, Zhe, Hou, Bo, Hamadani, Behrang H., Defay, Emmanuel, Kovacova, Veronika, Glinsek, Sebastjan, Kar-Narayan, Sohini, Bai, Yang, Kim, Da Bin, Cho, Yong Soo, Žukauskaitė, Agnė, Barth, Stephan, Fan, Feng Ru, Wu, Wenzhuo, Costa, Pedro, Campo, Javier del, Lanceros-Mendez, Senentxu, Khanbareh, Hamideh, Wang, Zhong Lin, Pu, Xiong, Pan, Caofeng, Zhang, Renyun, Xu, Jing, Zhao, Xun, Zhou, Yihao, Chen, Guorui, Tat, Trinny, Ock, Il Woo, Chen, Jun, Sontyana Adonijah Graham, Yu, Jae Su, Huang, Ling-Zhi, Li, Dan-Dan, Ma, Ming-Guo, Luo, Jikui, Jiang, Feng, Lee, Pooi See, Dudem, Bhaskar, Vivekananthan, Venkateswaran, Kanatzidis, Mercouri G., Xie, Hongyao, Shi, Xiao-Lei, Chen, Zhi-Gang, Riss, Alexander, Parzer, Michael, Garmroudi, Fabian, Bauer, Ernst, and Zavanelli, Duncan

Abstract

Ambient energy harvesting has great potential to contribute to sustainable development and address growing environmental challenges. Converting waste energy from energy-intensive processes and systems (e.g. combustion engines and furnaces) is crucial to reducing their environmental impact and achieving net-zero emissions. Compact energy harvesters will also be key to powering the exponentially growing smart devices ecosystem that is part of the Internet of Things, thus enabling futuristic applications that can improve our quality of life (e.g. smart homes, smart cities, smart manufacturing, and smart healthcare). To achieve these goals, innovative materials are needed to efficiently convert ambient energy into electricity through various physical mechanisms, such as the photovoltaic effect, thermoelectricity, piezoelectricity, triboelectricity, and radiofrequency wireless power transfer. By bringing together the perspectives of experts in various types of energy harvesting materials, this Roadmap provides extensive insights into recent advances and present challenges in the field. Additionally, the Roadmap analyses the key performance metrics of these technologies in relation to their ultimate energy conversion limits. Building on these insights, the Roadmap outlines promising directions for future research to fully harness the potential of energy harvesting materials for green energy anytime, anywhere.

Published
2023

27. The Development of Allogeneic Tips-Derived TCR- CAR+ CD8αβ T Cells

Author

van der Stegen, Sjoukje J.C., primary, Petrovic, Roseanna M., additional, Lindenbergh, Pieter L., additional, Diop, Mame P., additional, Alexeeva, Vera, additional, Xie, Hongyao, additional, Clarke, Raedun, additional, Valamehr, Bahram, additional, Rivière, Isabelle, additional, and Sadelain, Michel, additional

Published
2022
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29. High Thermoelectric Performance in Chalcopyrite Cu1–xAgxGaTe2–ZnTe: Nontrivial Band Structure and Dynamic Doping Effect

Author

Xie, Hongyao, primary, Liu, Yukun, additional, Zhang, Yinying, additional, Hao, Shiqiang, additional, Li, Zhi, additional, Cheng, Matthew, additional, Cai, Songting, additional, Snyder, G. Jeffrey, additional, Wolverton, Christopher, additional, Uher, Ctirad, additional, Dravid, Vinayak P., additional, and Kanatzidis, Mercouri G., additional

Published
2022
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31. Valence Disproportionation of GeS in the PbS Matrix Forms Pb5Ge5S12 Inclusions with Conduction Band Alignment Leading to High n-Type Thermoelectric Performance

Author

Luo, Zhong-Zhen, primary, Cai, Songting, additional, Hao, Shiqiang, additional, Bailey, Trevor P., additional, Xie, Hongyao, additional, Slade, Tyler J., additional, Liu, Yukun, additional, Luo, Yubo, additional, Chen, Zixuan, additional, Xu, Jianwei, additional, Luo, Wenjun, additional, Yu, Yan, additional, Uher, Ctirad, additional, Wolverton, Christopher, additional, Dravid, Vinayak P., additional, Zou, Zhigang, additional, Yan, Qingyu, additional, and Kanatzidis, Mercouri G., additional

Published
2022
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32. Valence disproportionation of GeS in the PbS matrix forms Pb₅Ge₅S₁₂ inclusions with conduction band alignment leading to high n-type thermoelectric performance

Author

Luo, Zhong-Zhen, Cai, Songting, Hao, Shiqiang, Bailey, Trevor P., Xie, Hongyao, Slade, Tyler J., Liu, Yukun, Luo, Yubo, Chen, Zixuan, Xu, Jianwei, Luo, Wenjun, Yu, Yan, Uher, Ctirad, Wolverton, Christopher, Dravid, Vinayak P., Zou, Zhigang, Yan, Qingyu, Kanatzidis, Mercouri G., and School of Materials Science and Engineering

Subjects
Materials [Engineering], Thermoelectric Material, Thermoelectric Performance
Abstract

Converting waste heat into useful electricity using solid-state thermoelectrics has a potential for enormous global energy savings. Lead chalcogenides are among the most prominent thermoelectric materials, whose performance decreases with an increase in chalcogen amounts (e.g., PbTe > PbSe > PbS). Herein, we demonstrate the simultaneous optimization of the electrical and thermal transport properties of PbS-based compounds by alloying with GeS. The addition of GeS triggers a complex cascade of beneficial events as follows: Ge2+ substitution in Pb2+ and discordant off-center behavior; formation of Pb5Ge5S12 as stable second-phase inclusions through valence disproportionation of Ge2+ to Ge0 and Ge4+. PbS and Pb5Ge5S12 exhibit good conduction band energy alignment that preserves the high electron mobility; the formation of Pb5Ge5S12 increases the electron carrier concentration by introducing S vacancies. Sb doping as the electron donor produces a large power factor and low lattice thermal conductivity (κlat) of ∼0.61 W m-1 K-1. The highest performance was obtained for the 14% GeS-alloyed samples, which exhibited an increased room-temperature electron mobility of ∼121 cm2 V-1 s-1 for 3 × 1019 cm-3 carrier density and a ZT of 1.32 at 923 K. This is ∼55% greater than the corresponding Sb-doped PbS sample and is one of the highest reported for the n-type PbS system. Moreover, the average ZT (ZTavg) of ∼0.76 from 400 to 923 K is the highest for PbS-based systems. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) This study was supported primarily by the Department of Energy, Office of Science Basic Energy Sciences under grant DE-SC0014520, the DOE Office of Science (sample preparation, synthesis, XRD, TE measurements, TEM measurements, DFT calculations), and the Fujian Science & Technology Innovation Laboratory for Optoelectronic Information of China (2021ZZ127). The authors acknowledge the Minjiang Scholar Professorship (GXRC-21004), the National Natural Science Foundation of China (52102218 and 61728401), the National Key Research and Development Program/Key Scientific Issues of Transformative Technology (2020YFA0710303), the EPIC facility of Northwestern University’s NUANCE Center, which received support from the Soft and Hybrid Nanotechnology Experimental (SHyNE) Resource (NSF ECCS-1542205), the MRSEC program (NSF DMR-1720139) at the Materials Research Center, the International Institute for Nanotechnology (IIN), Keck Foundation, State of Illinois, through IIN, and the Office of Science of the U.S. Department of Energy under Contract Nos. DE-AC02-06CH11357 and DE-AC02-05CH11231. The authors further acknowledge access to facilities for high performance computational resources at Northwestern University and Singapore MOE AcRF Tier 2 under Grant No. 2018-T2-1-010, Singapore A*STAR project A19D9a0096, and the support from FACTs of Nanyang Technological University for sample analysis.

Published
2022

33. Low Thermal Conductivity in Heteroanionic Materials with Layers of Homoleptic Polyhedra

Author

Zhang, Chi, primary, He, Jiangang, additional, McClain, Rebecca, additional, Xie, Hongyao, additional, Cai, Songting, additional, Walters, Lauren N., additional, Shen, Jiahong, additional, Ding, Fenghua, additional, Zhou, Xiuquan, additional, Malliakas, Christos D., additional, Rondinelli, James M., additional, Kanatzidis, Mercouri G., additional, Wolverton, Chris, additional, Dravid, Vinayak P., additional, and Poeppelmeier, Kenneth R., additional

Published
2022
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40. Stabilization of the Polar Structure and Giant Second‐Order Nonlinear Response of Single Crystal γ‐NaAs0.95Sb0.05Se2.

Author

Iyer, Abishek K., He, Jingyang, Xie, Hongyao, Goodling, Devin, Chung, Duck‐Young, Gopalan, Venkatraman, and Kanatzidis, Mercouri G.

Subjects
SINGLE crystals, PHASE transitions, NONLINEAR optical materials, CRYSTAL growth, ZONE melting
Abstract

The dearth of suitable materials significantly restricts the practical development of infrared (IR) laser systems with highly efficient and broadband tuning. Recently, γ‐NaAsSe2 is reported, and it exhibits a large nonlinear second‐harmonic generation (SHG) coefficient of 590 pm V−1 at 2 µm. However, the crystal growth of γ‐NaAsSe2 is challenging because it undergoes a phase transition to centrosymmetric δ‐NaAsSe2. Herein, the stabilization of non‐centrosymmetric γ‐NaAsSe2 by doping the As site with Sb, which results in γ‐NaAs0.95Sb0.05Se2 is reported. The congruent melting behavior is confirmed by differential thermal analysis with a melting temperature of 450 °C and crystallization temperature of 415 °C. Single crystals with dimensions of 3 mm × 2 mm are successfully obtained via zone refining and the Bridgman method. The purification of the material plays a significant role in crystal growth and results in a bandgap of 1.78 eV and thermal conductivity of 0.79 Wm−1 K−1. The single‐crystal SHG coefficient of γ‐NaAs0.95Sb0.05Se2 exhibits an enormous value of |d11| = 648 ± 74 pm V−1, which is comparable to that of γ‐NaAsSe2 and ≈20× larger than that of AgGaSe2. The bandgap of γ‐NaAs0.95Sb0.05Se2 (1.78 eV) is similar to that of AgGaSe2, thus rendering it highly attractive as a high‐performing nonlinear optical material. [ABSTRACT FROM AUTHOR]

Published
2023
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42. High Thermoelectric Performance through Crystal Symmetry Enhancement in Triply Doped Diamondoid Compound Cu2SnSe3

Author

Hu, Lei, primary, Luo, Yubo, additional, Fang, Yue‐Wen, additional, Qin, Feiyu, additional, Cao, Xun, additional, Xie, Hongyao, additional, Liu, Jiawei, additional, Dong, Jinfeng, additional, Sanson, Andrea, additional, Giarola, Marco, additional, Tan, Xianyi, additional, Zheng, Yun, additional, Suwardi, Ady, additional, Huang, Yizhong, additional, Hippalgaonkar, Kedar, additional, He, Jiaqing, additional, Zhang, Wenqing, additional, Xu, Jianwei, additional, Yan, Qingyu, additional, and Kanatzidis, Mercouri G., additional

Published
2021
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44. High thermoelectric performance through crystal symmetry enhancement in triply doped diamondoid compound Cu₂SnSe₃

Author

Hu, Lei, Luo, Yubo, Fang, Yue-Wen, Qin, Feiyu, Cao, Xun, Xie, Hongyao, Liu, Jiawei, Dong, Jinfeng, Sanson, Andrea, Giarola, Marco, Tan, Xian Yi, Zheng, Yun, Suwardi, Ady, Huang, Yizhong, Hippalgaonkar, Kedar, He, Jiaqing, Zhang, Wenqing, Xu, Jianwei, Yan, Qingyu, Kanatzidis, Mercouri G., School of Materials Science and Engineering, and Institute of Materials Research and Engineering, A*STAR

Subjects
Materials [Engineering], Crystal Symmetry, Diamondoid Structure
Abstract

The presence of high crystallographic symmetry and nanoscale defects are favorable for thermoelectrics. With proper electronic structures, a highly symmetric crystal tends to possess multiple carrier channels and promote electrical conductivity without sacrificing Seebeck coefficient. In addition, nanoscale defects can effectively scatter acoustic phonons to suppress thermal conductivity. Here, it is reported that the triple doping of Cu2SnSe3 leads to a high ZT value of 1.6 at 823 K for Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3, and a decent average ZT (ZTave) value of 0.7 is also achieved for Cu1.85Ag0.15(Sn0.93Mg0.06Na0.01)Se3 from 475 to 823 K. This study reveals: 1) Ag doping on Cu sites generates numerous point defects and greatly decreases lattice thermal conductivity. 2) Doping Mg or Ga converts the monoclinic Cu2SnSe3 into a cubic structure. This symmetry enhancing leads to an increase in the effective mass from 0.8 me to 2.6 me (me, free electron mass) and the power factor from 4.3 µW cm−1 K−2 for Cu2SnSe3 to 11.6 µW cm−1 K−2. 3) Na doping creates dense dislocation arrays and nanoprecipitates, which strengthens the phonon scattering. 4) Pair distribution function analysis shows localized symmetry breakdown in the cubic Cu1.85Ag0.15(Sn0.88Ga0.1Na0.02)Se3. This work provides a standpoint to design promising thermoelectric materials by synergistically manipulating crystal symmetry and nanoscale defects. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Submitted/Accepted version This work was supported by the U.S. Department of Energy, Office of Science Basic Energy Sciences under grant DE-SC0014520, DOE Office of Science (materials characterization, sample synthesis, transport properties). User Facilities were supported by the Office of Science of the U.S. Department of Energy under Contract Nos. DE-AC02-06CH11357 and DE-AC02-05CH11231. Access to facilities of high-performance computational resources at the Northwestern University is acknowledged. The authors also acknowledge Singapore MOE Tier 2 under Grant Nos. MOE2018-T2-1-010, Singapore A*STAR Pharos Program SERC 1527200022, and Singapore A*STAR project A19D9a0096.

Published
2021

45. Ultralow Thermal Conductivity in Diamondoid Structures and High Thermoelectric Performance in (Cu1–xAgx)(In1–yGay)Te2

Author

Xie, Hongyao, primary, Hao, Shiqiang, additional, Bailey, Trevor P., additional, Cai, Songting, additional, Zhang, Yinying, additional, Slade, Tyler J., additional, Snyder, G. Jeffrey, additional, Dravid, Vinayak P., additional, Uher, Ctirad, additional, Wolverton, Christopher, additional, and Kanatzidis, Mercouri G., additional

Published
2021
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