The true statement for thermo e.m.f . of a thermocouple

Above neutral temperature, thermo e.m.f. in a thermocouple

The thermo e.m.f. E in volts of a certain thermocouple is found to vary with temperature difference q in .^(@)C between the two junctions according to the relation E=30 theta-(theta^(2))/(15) The neutral temperature for the thermo-couple will be:-

The rate of increase of thermo-emf with temperature at the neutral temperature of a thermocouple

The thermo emf E (in volts) of a certain thermocouple is found to vary with Q (in C) acoording to eqution (E=20Q-Q^2/(20)) , where Q is tempereature of the hot function, the cold function being kept at 0^@C . Then the neutral temperature of the thermocouple is

Plot a labelled graph to show variation of thermo-emf .e. versus temperature difference .theta. between the two junctions of a thermocouple. Mark .N. as neutral temperature and I as temperature of inversion. (ii) What is Peltier effect ?

The thermo emf E of a thermocouple is found to vary wit temperature T of the junction (cold junction is 0^(@)C ) as E=40T-(T^(2))/(20) The temperature of inversion for the thermocouple is

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.

The temperature of the cold junction of thermo-couple is 0^(@)C and the temperature of hot junction is T^(@)C . The e.m.f . is E=16T-0.04 T^(2)mu volts. The temperature of inversion is

If f(x)=|x+1| then the true statement from the following is :

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