2023
DOI: 10.1016/j.jmst.2022.11.003
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Dense dislocations induced ductile SnTe thermoelectric semiconductor over a wide range of temperatures

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Cited by 18 publications
(4 citation statements)
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“…In addition, Figure 5 d reveals dislocations have a positive effect on ductility enhancement. Yang et al [ 69 ] performed uniaxial compression tests on SnTe at different temperatures ranging from room temperature to 673K and found that the engineering compressive strain increased dramatically from 7.5% to 42%. Through TEM and first-principle calculations, it is found that there are considerable pre-existing dislocations in the grains of SnTe after preparation, as shown in Figure 5 g. During the compression test at room temperature, the pre-existing dislocations move locally and from slip bands leading the large deformability.…”
Section: Toughening Strategies Of Thermoelectric Materialsmentioning
confidence: 99%
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“…In addition, Figure 5 d reveals dislocations have a positive effect on ductility enhancement. Yang et al [ 69 ] performed uniaxial compression tests on SnTe at different temperatures ranging from room temperature to 673K and found that the engineering compressive strain increased dramatically from 7.5% to 42%. Through TEM and first-principle calculations, it is found that there are considerable pre-existing dislocations in the grains of SnTe after preparation, as shown in Figure 5 g. During the compression test at room temperature, the pre-existing dislocations move locally and from slip bands leading the large deformability.…”
Section: Toughening Strategies Of Thermoelectric Materialsmentioning
confidence: 99%
“…Copyright 2012 Elsevier); ( d ) Mechanical and thermoelectric properties of Mg 2 (Si 0.3 Sn 0.7 ) 0.99 Sb 0.01 improved by graphene oxide nanosheets and multi-walled carbon nanotubes [ 68 ]; ( e , f ) Crack propagates: pulling out and crack bridging (Reprinted with permission from ref [ 68 ]. Copyright 2021 Elsevier); ( g ) Dense dislocations loops in SnTe [ 69 ]; ( h ) Stress-strain curves for compression tests of SnTe at different temperature [ 69 ]; ( i ) The deformation mechanisms in SnTe samples at different temperatures (Reprinted with permission from ref [ 69 ]. Copyright 2023 Elsevier); ( j ) The digital photograph of PEDOT:PSS/Te–NWs (PP/T) hybrid fibers [ 70 ]; ( k ) SEM images of PP/T hybrid fibers [ 70 ]; ( l ) Stress-strain curves of PP/T before and after post-treatment.…”
Section: Figurementioning
confidence: 99%
“…By the introduction of microstructure defects, the average free path of phonons can be effectively reduced, thereby reducing the lattice thermal conductivity. Point-defect, dislocations, , grain boundaries, , and nanoprecipitates have been shown to be effective in enhancing phonon scattering. In addition, lattice softening caused by weakened interatomic binding force can also significantly reduce sound velocity, thereby reducing lattice thermal conductivity .…”
Section: Introductionmentioning
confidence: 99%
“…The current challenges facing humanity include energy shortage and the greenhouse effect, necessitating the development of new energy sources and the protection of the Earth’s environment. When utilizing energy sources like coal, oil, and natural gas, a significant amount of heat is wasted in the form of waste heat. Therefore, the recycling and utilization of these energy sources have become crucial issues. Traditional refrigeration materials have detrimental effects on the ozone layer and the environment. Hence, there is a need to develop new refrigeration technologies. Thermoelectric materials have the capability to convert heat energy and electric energy into each other, enabling the recycling and reuse of energy from sources such as automobile exhaust, industrial waste heat, and geothermal energy. They also offer rapid, precise, eco-friendly, and noise-free cooling methods. Thus, thermoelectric materials provide potential solutions to the energy crisis and environmental problems we face today. , …”
Section: Introductionmentioning
confidence: 99%