If the emf of a thermocouple, one junction of which is kep `0^(@)C` is given by `e=at+1//2bt^(2)` then the neutral temperature will be

If E=at+bt^(2) , what is the neutral temperature

The thermo emf of a therocouple , one junction of which is kept at 0^(@)C , is given by varepsilon=at+bt^(2) where a and b constants of the thermocouple . Calculate the neutral temperature and peltier and Thomson coefficients.

The emf in a thermooelectric circuit with one junction at 0^(@)C and other at t^(@)C is given by E=At-Bt^(2) , the neutral temperature is , then

The emf in a lead-iron thermocouple , one junction of which is at t^(@)C is given by varepsilon=178t-2.4t^(2)( "in "muV) where t is the temperature in .^(@)C .Find the neutral temperature , Peltier coefficient and Thomson coefficient.

For Copper-iron (Cu-Fe) couple, the thermo e.m.f. (temperature of cold junction =^(@)C ) is given by E=(14theta-0.02 theta^(2) ) mu V . The neutral temperature will be

The e.m.f. in a thermoelectric circuit with one junction at 0^(@)C and the other at t^(@)C is given by E=At-Bt^(2) . The neutral temperature is then

The emf varepsilon of a Cu-Fe thermocouple varies with the temperature theta of the hot junction (cold junction at 0^(@)C ), as varepsilon(mu V)=14 theta-0.02 theta^(2) Determine the neutral temperature.

The thermo emf of a thermocouple is given by E=alpha(theta-theta_(g))+beta(theta^(2)-theta_(0)^(2)) Determine the neutral temperature and inversion temperature.

For a certain thermocouple , varepsilon=alphatheta+(1)/(2)betatheta^(@),where theta.^(@)C is the temperature of the hot junction and 0^(@)C is the temperature of the cold junction . If alpha =10 mu V.^(@)C^(-1) and beta=-(1)/(20)muV.^(@)C^(-2) , find the neutral temperature and temperature of inversion.

If the cold junction of thermocouple is kept at 0^(@)C and the hot junction is kept at T^(@)C , then the relation between neutral temperature (T_(n)) and temperature of inversion (T_(i)) is