FIELD: chemistry.
SUBSTANCE: material contains antimony telluride in the form of a triple solid solution with the composition BixSb2-xTe3, where x has values from 0.4 to 0.5, and a disperse filling agent, made from an ultradisperse diamond with the average size of particles from 3 to 5 nm. Concentration of particles of the ultradisperse diamond constitutes from 0.2 to 15% of the volume of the triple solid solution.
EFFECT: invention makes it possible to increase the thermoelectric figure of merit and mechanical strength of the nanostructured thermoelectric material.
2 cl, 4 ex
| Title | Year | Author | Number |
|---|---|---|---|
| METHOD OF INCREASING THE Q-FACTOR OF THE THERMOELECTRIC MATERIAL BASED ON SOLID SOLUTION OF BITE-BISE | 2019 |
|
RU2727061C1 |
| METHOD OF OBTAINING THERMOELECTRIC MATERIAL | 2013 |
|
RU2528280C1 |
| THERMOELECTRIC NANOCOMPOSITE, METHOD OF MAKING NANOCOMPOSITE AND USE OF NANOCOMPOSITE | 2008 |
|
RU2457583C2 |
| HIGH-EFFICIENT THERMOELECTRIC MATERIAL AND METHOD OF ITS MANUFACTURE | 2016 |
|
RU2660223C2 |
| METHOD OF PRODUCING P-TYPE CONDUCTIVITY THERMOELECTRIC MATERIAL BASED ON SOLID SOLUTIONS BiTe-SbTe | 2017 |
|
RU2683807C1 |
| METHOD FOR OBTAINING NANOSTRUCTURE THERMOELECTRIC MATERIALS | 2022 |
|
RU2794354C1 |
| HIGH-TEMPERATURE HIGH PERFORMANCE THERMOELECTRIC MODULE | 2009 |
|
RU2550799C2 |
| NANOCOMPOSITE THERMOELECTRIC AND METHOD OF ITS PRODUCTION | 2010 |
|
RU2474010C2 |
| METHOD OF PRODUCING p-TYPE THERMOELECTRIC MATERIAL BASED ON SOLID SOLUTIONS OF BiTe-SbTe | 2011 |
|
RU2470414C1 |
| METHOD FOR PRODUCING A THERMOELECTRIC MATERIAL BASED ON BISMUTH TELLURIDE | 2021 |
|
RU2765275C1 |
