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Journal Article
Applied Physics Letters, ISSN 0003-6951, 09/2014, Volume 105, Issue 13, p. 132107
We report thermoelectric (TE) properties of dense samples of colusites Cu26V2M6S32 (M = Ge, Sn), most of which are composed of earth-abundant elements; Cu and... 
POWER | PHYSICS, APPLIED
Journal Article
Journal of Applied Physics, ISSN 0021-8979, 05/2016, Volume 119, Issue 17
The colusite Cu26V2Sn6S32 has high potential as a thermoelectric material at medium-high temperatures because of a large Seebeck coefficient (S ≃ 220 μV/K) and... 
Composition | X ray powder diffraction | X-ray diffraction | Seebeck effect | Valence band | Zinc | Thermoelectricity | Charge density | Current carriers | Electron probe microanalysis | Thermoelectric materials | Tin | Copper | Carrier density | Quantum theory | Figure of merit
Journal Article
Journal of the Physical Society of Japan, ISSN 0031-9015, 10/2015, Volume 84, Issue 10, p. 103601
We report the thermal conductivity and specific heat measurements at temperatures down to 0.3 and 0.4 K, respectively, for synthetic Cu-S based minerals,... 
RIETVELD REFINEMENT | IRON | NICKEL | PHYSICS, MULTIDISCIPLINARY | CU12SB4S13 | TENNANTITE
Journal Article
Applied Physics Letters, ISSN 0003-6951, 09/2014, Volume 105, Issue 13
We report thermoelectric (TE) properties of dense samples of colusites Cu26V2M6S32 (M = Ge, Sn), most of which are composed of earth-abundant elements; Cu and... 
Tin | Thermal conductivity | Germanium | Copper | Thermoelectricity | Figure of merit
Journal Article
Journal of the Physical Society of Japan, ISSN 0031-9015, 10/2015, Volume 84, Issue 10, pp. 1 - 1
We report the thermal conductivity and specific heat measurements at temperatures down to 0.3 and 0.4 K, respectively, for synthetic Cu-S based minerals,... 
Specific heat | PROPERTIES | MINERALS | PHYSICAL PROPERTIES | Thermal conductivity | Displays | CRYSTAL STRUCTURE | ELECTRICAL CONDUCTIVITY | Copper | Thermophysical properties | Heat transfer | GLASSES
Journal Article
Journal of the Physical Society of Japan, ISSN 0031-9015, 10/2015, Volume 84, Issue 10, p. 1
  We report the thermal conductivity and specific heat measurements at temperatures down to 0.3 and 0.4 K, respectively, for synthetic Cu-S based minerals,... 
Temperature | Minerals | Heat conductivity | Physical properties
Journal Article
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