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61

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年访问量

2017

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  • 外部: 2010

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总访问量

8067

  • 内部: 188

  • 外部: 7879

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1. Ultrahigh power factor and thermoelectric performance in hole-dope.. [1519]
2. 3D charge and 2D phonon transports leading to high out-of-plane ZT.. [1189]
3. All-scale hierarchical thermoelectrics: MgTe in PbTe facilitates v.. [1130]
4. BiCuSeO oxyselenides: new promising thermoelectric materials [1128]
5. Tuning Multiscale Microstructures to Enhance Thermoelectric Perfor.. [1052]
6. High performance bulk thermoelectrics via a panoscopic approach [1051]
7. High thermoelectric performance in low-cost SnS0.91Se0.09 crystals [951]
8. Broad temperature plateau for thermoelectric figure of merit ZT > .. [934]
9. High-entropy-stabilized chalcogenides with high thermoelectric per.. [912]
10. Power generation and thermoelectric cooling enabled by momentum an.. [845]
11. Origin of the High Performance in GeTe-Based Thermoelectric Materi.. [785]
12. Texturation boosts the thermoelectric performance of BiCuSeO oxyse.. [721]
13. Anisotropic Landau level splitting and Lifshitz transition induced.. [715]
14. High Thermoelectric Performance Realized in a BiCuSeO System by Im.. [650]
15. Enhanced Thermoelectric Properties in the Counter-Doped SnTe Syste.. [573]
16. Synergistically optimized electrical and thermal transport propert.. [533]
17. High figure-of-merit and power generation in high-entropy GeTe-bas.. [519]
18. Enhanced atomic ordering leads to high thermoelectric performance .. [485]
19. Low-cost, abundant binary sulfides as promising thermoelectric mat.. [433]
20. Superior thermoelectric performance in PbTe-PbS pseudo-binary: ext.. [386]
21. High-entropy enhanced capacitive energy storage [381]
22. Strong enhancement of phonon scattering through nanoscale grains i.. [374]
23. Understanding of the Extremely Low Thermal Conductivity in High-Pe.. [342]
24. Role of Sodium Doping in Lead Chalcogenide Thermoelectrics [339]
25. High-Performance Thermoelectricity in Nanostructured Earth-Abundan.. [335]
26. Remarkable Roles of Cu To Synergistically Optimize Phonon and Carr.. [259]
27. Impact of crystalline structures on the thermal stability and Scho.. [257]
28. High thermoelectric performance of Ge1-xPbxSe0.5Te0.5 due to (Pb, .. [247]
29. Electric Polarization Switching on an Atomically Thin Metallic Oxi.. [241]
30. Investigations on distinct thermoelectric transport behaviors of C.. [235]
31. Ultrahigh performance PEDOT/Ag2Se/CuAgSe composite film for wearab.. [232]
32. Coherent Sb/CuTe Core/Shell Nanostructure with Large Strain Contra.. [232]
33. Realizing high-efficiency power generation in low-cost PbS-based t.. [220]
34. 亚晶格工程与新型“半晶态”热电化合物结构-性能关系研究进展 [218]
35. Significantly Enhanced Thermoelectric Performance in n-type Hetero.. [216]
36. Controlled heterogeneous water distribution and evaporation toward.. [213]
37. Nano-patterning of a monolayer molybdenum disulfide with sub-nanom.. [211]
38. Multiple Converged Conduction Bands in K2Bi8Se13: A Promising Ther.. [210]
39. Interfacial superstructures and chemical bonding transitions at me.. [208]
40. The Thermoelectric Properties of SnSe Continue to Surprise: Extrao.. [200]
41. Realizing record high performance in n-type Bi2Te3-based thermoele.. [196]
42. Realizing High-Ranged Out-of-Plane ZTs in N-Type SnSe Crystals thr.. [192]
43. Ultrahigh power factor and flexible silver selenide-based composit.. [191]
44. Dynamic piezo-thermoelectric generator for simultaneously harvesti.. [189]
45. Constructing van der Waals gaps in cubic-structured SnTe-based the.. [189]
46. Potential-Dependent Phase Transition and Mo-Enriched Surface Recon.. [185]
47. A highly asymmetric interfacial superstructure in WC: Expanding th.. [184]
48. Achieving a fine balance between the strong mechanical and high th.. [181]
49. Excellent Thermoelectric Performance Realized in p-Type Pseudolaye.. [180]
50. Integrating Band Structure Engineering with All-Scale Hierarchical.. [177]
51. Giant polarization ripple in transverse pyroelectricity [176]
52. Realizing Improved Thermoelectric Performance in BiI3-Doped Sb2Te3.. [175]
53. Ultrahigh thermoelectric performance in Cu2Se-based hybrid materia.. [174]
54. Understanding the effects of iodine doping on the thermoelectric p.. [173]
55. Surface nitridation of nickel-cobalt alloy nanocactoids raises the.. [173]
56. A hierarchical carbon nitride tube with oxygen doping and carbon d.. [172]
57. Liquid-like thermal conduction in intercalated layered crystalline.. [172]
58. Realizing high performance n-type PbTe by synergistically optimizi.. [171]
59. Origin of low thermal conductivity in SnSe [169]
60. Visible-light-stimulated Alkalis-triggered Platinum Cocatalyst wit.. [169]
61. Realizing high figure of merit plateau in Ge1-xBixTe via enhanced .. [168]
62. Enhanced thermoelectric properties of bismuth telluride bulk achie.. [168]
63. Unexpected Large Hole Effective Masses in SnSe Revealed by Angle-R.. [167]
64. Investigation on thermal transport and structural properties of In.. [167]
65. Strategy to optimize the overall thermoelectric properties of SnTe.. [167]
66. Delocalized Carriers and the Electrical Transport Properties of n-.. [164]
67. Electrical and thermal transport properties of layered Bi2YO4Cu2Se.. [164]
68. Ultra-low Specific Contact Resistivity (3.2×10-10 Ω-cm2) of Ti/S.. [164]
69. Simultaneously enhancing the power factor and reducing the thermal.. [163]
70. Research Progress on Structure-Performance Relationship for Novel .. [163]
71. Enhancing thermoelectric performance of SnTe via stepwisely optimi.. [161]
72. Attaining high mid-temperature performance in (Bi,Sb)(2)Te-3 therm.. [160]
73. Synergizing aliovalent doping and interface in heterostructured Ni.. [160]
74. Magnetotransport signatures of Weyl physics and discrete scale inv.. [158]
75. Enhancing thermoelectric performance of SnTe via nanostructuring p.. [157]
76. Extraordinary thermoelectric performance in n-type manganese doped.. [156]
77. Direct observation of vast off-stoichiometric defects in single cr.. [156]
78. Large enhancement of thermoelectric performance of InTe compound b.. [156]
79. Colloidal syntheses of zero-dimensional Cs4SnX6 (X = Br, I) nanocr.. [155]
80. Synergistic modulation of mobility and thermal conductivity in (Bi.. [153]
81. Highly enhanced thermoelectric performance in BiCuSeO ceramics rea.. [152]
82. High thermoelectric performance in n-type BiAgSeS due to intrinsic.. [152]
83. High Performance and Flexible Polyvinylpyrrolidone/Ag/Ag2Te Ternar.. [152]
84. Directing Gold Nanoparticles into Free-Standing Honeycomb-Like Ord.. [150]
85. Synergistically optimizing thermoelectric transport properties of .. [150]
86. Mechanical Alloying and Spark Plasma Sintering of BiCuSeO Oxyselen.. [148]
87. Polymer/carbon nanotube composite materials for flexible thermoele.. [145]
88. Extraordinary Thermoelectric Performance Realized in n-Type PbTe t.. [145]
89. Interfacial origins of visible-light photocatalytic activity in Zn.. [145]
90. Step-Up Thermoelectric Performance Realized in Bi2Te3 Alloyed GeTe.. [144]
91. Thermoelectric properties of Cu2Sex prepared by solution phase met.. [143]
92. Remarkable electron and phonon band structures lead to a high ther.. [140]
93. Grain Boundary Engineering for Achieving High Thermoelectric Perfo.. [139]
94. Entropy engineering promotes thermoelectric performance in p-type .. [139]
95. High Power Factor Ag/Ag2Se Composite Films for Flexible Thermoelec.. [137]
96. Realizing high thermoelectric performance of polycrystalline SnS t.. [135]
97. Raising thermoelectric performance of n-type SnSe via Br doping an.. [135]
98. Multipoint Defect Synergy Realizing the Excellent Thermoelectric P.. [134]
99. Enhanced thermoelectric properties in chimney ladder structured Mn.. [133]
100. Highly Enhanced Thermoelectric Properties of Bi/Bi2S3 Nanocomposit.. [133]
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