Assertion: Neutral temperature of a thermocuple does not depend upon temperature of cold junction.
Reason: Its value is constant for the given metals of the couple

Assertion: When temperature of cold junction of a thermocouple is lowered, the value of neutral temperature of this thermo couple is raised. Reason: When the difference of temperature of two junction is raised. More thermo emf is produced.

If the temperature of cold junction of thermocouple is lowered, then the neutral temperature

How does the resistance of a metallic Wire depend on its temperature?

For a thermocouple, the neutral temperature is 570^(@)C and the temperature of its cold junction is 50^(@)C . If there is no deflection in the galvanometer, the temperature of the hot junction should be

For a thermocouple, the neutral temperature is 270^(@)C and the temperature of its cold junction is 20^(@)C . If there is no deflection in the galvanometer, the temperature of the hot junction should be

For a thermocouple, the neutral temperature is 300^(@)C and the temperature of its cold junction is 30^(@)C . If there is no deflection in the galvanometer, the temperature of the hot junction should be

Thermo e.m.f. E of a Cu-Fe thermocouple varies with the temperature theta of the hot junction ( cold juction 0^(@)C ) as E(muV)=12theta-0.02 theta^(2) . Determine:- (a) Neutral temperature of the termocouple (b) Temperature of inversion, assuming that cold junction is at 20^(@)C . (c) Value of Seebeck coefficient at neutral temperature

With the cold junction at 0^(@)C the neutral temperature for a thermo-couple is obtained at 270^(@)C . The cold junction temperature is now lowered to -10^(@)C Obta in the (a) neutral temperature (b) the temperature of inversion in this case.

Assertion : At same temperature among plastic body of pen and metal portion on cap, metal portion is cold. Reason : Thermal conductivity of metal is more than plastic.

The cold junction of a thermocouple is at 0^(@)C . The thermo e.m.f. epsilon , in volts, generated in this thermocouple varies with temperature t^(@)C of the hot junction as epsilon=6+4t-(t^(2))/(32) . The neutral temperature of the thermocouple