Difference between revisions of "A Thermodynamic Cycle for Heat to Electrical Energy Conversion by Means of Ferroelectrics"
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| − | A thermodynamic cycle transforms heat to electrical energy using ferroelectric materials. An expression for the electrocaloric effect may be derived from the laws of thermodynamics and electricity. From this, another derivation shows that a capacitor filled with a ferroelectric medium can be nonlinear with dC/dV > 0; i.e., the capacitance rises with an increase in voltage. This nonlinearity is essential for the thermodynamic cycle.[[Category:Scientific Paper]] | + | A thermodynamic cycle transforms heat to electrical energy using ferroelectric materials. An expression for the electrocaloric effect may be derived from the laws of thermodynamics and electricity. From this, another derivation shows that a capacitor filled with a ferroelectric medium can be nonlinear with dC/dV > 0; i.e., the capacitance rises with an increase in voltage. This nonlinearity is essential for the thermodynamic cycle. |
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| + | [[Category:Scientific Paper|thermodynamic cycle heat electrical energy conversion means ferroelectrics]] | ||
[[Category:New Energy]] | [[Category:New Energy]] | ||
Revision as of 10:04, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | A Thermodynamic Cycle for Heat to Electrical Energy Conversion by Means of Ferroelectrics |
| Author(s) | Andreas Ries |
| Keywords | capacitance, Curie temperature, electrocaloric effect, heat recovery |
| Published | 2004 |
| Journal | Electric Spacecraft Journal |
| Number | 38 |
| Pages | 9-12 |
Abstract
A thermodynamic cycle transforms heat to electrical energy using ferroelectric materials. An expression for the electrocaloric effect may be derived from the laws of thermodynamics and electricity. From this, another derivation shows that a capacitor filled with a ferroelectric medium can be nonlinear with dC/dV > 0; i.e., the capacitance rises with an increase in voltage. This nonlinearity is essential for the thermodynamic cycle.
