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Thomson Effect

Thomson Effect
In different materials, the Seebeck coefficient is not constant in temperature, and so a spatial gradient in temperature can result in a gradient in the Seebeck coefficient. If a current is driven through this gradient, then a continuous version of the Peltier effect will occur. This Thomson effect was predicted and subsequently observed in 1851 by Lord Kelvin (William Thomson). It describes the heating or cooling of a current-carrying conductor with a temperature gradient.

See Also


Aharonov-Bohm Effect
Bjerknes Effect
Casimir Effect
Cause and Its Effects
Effect
effect of motion
effects of motion
electric effect
electrical effect
Figure 16.00 - Maxwell and Thomson
Hundredth Monkey Effect
J. J. Thomson
Kervran Effect
law of cause and effect
Mind Force - a Reproducible Effect
Nocebo Effect
Ozone Effects
Peltier Effect
photoelectric effect
Placebo Effect
production of the opposite effect
Renner-Teller Effect
ripple effect
Seebeck Effect
spinning effect
Steric Effects
Table 13.03 - Photoelectric Effect of Elements
Table of Cause and Effect Dualities
Thermoelectric Effect
thermomagnetic effect
Thomsonian corpuscle
triboelectric effect
two-way divided effects of motion
two-way effect
Tyndall Effect
William Thomson
Zeeman effect
zero cause and dual effect
11.08 - Matter is an Effect of Will Force
14.11 - Ranges of Forces Effects and Actions
14.30 - Effect of Preponderance
15.24 - Water is Sensitive to Biometeorological Effects
16.11 - Seebeck Effect
2.22 - Voiding - an Effect of Desire and Will Force

Created by Dale Pond. Last Modification: Friday December 21, 2018 03:03:39 MST by Dale Pond.