Measurement of the thermoelectric power of very small samples at ambient and high pressures
- 1 September 1999
- journal article
- Published by AIP Publishing in Review of Scientific Instruments
- Vol. 70 (9) , 3586-3589
- https://doi.org/10.1063/1.1149964
Abstract
There is currently much interest in the thermoelectric properties of materials. A method for measuring the thermoelectric power of small single-crystal or polycrystalline samples is described. For high-pressure measurements, the small samples are loaded into a diamond anvil cell and compressed. An infrared laser system is used to induce a temperature gradient in the sample. The thermoelectric power is measured with a pair of small thermocouples contacting the sample. Reported here is the thermoelectric power of Ni and the previously reported intermetallic compound CePd3 up to 10 GPa. Other standards measured by this method included: Bi, Yb, and CeSn3.Keywords
This publication has 11 references indexed in Scilit:
- Measurement of thermoelectric power using metal opposed anvil cells up to 100 kbarReview of Scientific Instruments, 1995
- Producing diamond anvil cell gaskets for ultrahigh-pressure applications using an inexpensive electric discharge machineReview of Scientific Instruments, 1994
- Theoretical models of the electrical discharge machining process. I. A simple cathode erosion modelJournal of Applied Physics, 1989
- Technique for high-pressure electrical conductivity measurement in diamond anvil cells at cryogenic temperaturesReview of Scientific Instruments, 1987
- Thermoelectric power of barium up to 8 GPaPhysical Review B, 1987
- High pressure thermopower and electrical resistance measurements in CeSn3, CeAl3, CeAl2 and CeIn3Solid State Communications, 1983
- Thermoelectric power of strontium up to 6.5 GPaSolid State Communications, 1982
- Thermoelectric power of cerium up to 6 GPaSolid State Communications, 1979
- Measurement of thermoelectric power of solids up to 10 GPaReview of Scientific Instruments, 1978
- Calibration of the pressure dependence of the R1 ruby fluorescence line to 195 kbarJournal of Applied Physics, 1975