Riley Gilbert
When a material's inherent property directly converts temperature variations across its body into electric voltage, this phenomenon is known as a thermoelectric effect. The differential operator's non-classical approach is used to predict the thermoelectric fluid's maximum and best heat transfer efficiency in this manuscript. The fractionalized numerical model is likewise settled to investigate the productivity and qualities of thermoelectric liquid through temperature dissemination and speed field. Cardano's method and the comprehensive analytical approach of integral transforms are utilized to provide analytical solutions that incorporate the dynamic examination of the temperature distribution and velocity field. On the basis of magnetization and anti-magnetization, which describe the behavior of sine and cosine sinusoidal waves, a dynamic investigation of the thermoelectric fluid's temperature distribution and velocity field is conducted. The rheological parameter magnetization suggests that the magnetized intensity generates 34.66% of the magnetic hysteresis during the thermoelectric effect when varying magnetic fields are used.
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