The junctions of a `Ni-Cu` thermocouple are maintained at `0^@ C and 100^@ C`. Calculate the Seebeck emf produced in the loop. `a_(Ni, Cu) = 16.3 xx 10^(-6) V^@ C^(-1)` and `b_(Ni, Cu) = - 0.042 xx 10^(-6) V^@ C^(-3)`

The temperatures of the junctions of a biamuth-silver thermocouple are maintained at 0^@ C and 0.001^@ C . Find the thermo-emf (Seebeck emf) developed. For bismuth-silver, a = - 46 xx 10^(-6) V^@ C^(-1) and b= -0.48 xx 10^(-6) V^@ V^@ C^(-2) .

The junction of a Ni-Cu thermocouple is maintained to 0^(@)C and 100^(@)C . Find the thermo-emf produced. Also, find nautral temperature and inversion temperature. Given a_(Ni, Cu) = 16.3xx10^(-6)V//.^(@)C, b_(Ni,Cu) = -0.042xx10^(-6)V//(@C)^(2) .

The cold junction of a thermocouple is maintained at 10^(@)C . No thermo e.m.f . is developed when the hot junction is maintained at 530^(@)C . The neutral temperature is

Calculate the emf of the following cell at 25^(@)C Ag(s) |Ag+ (10^(-3)M) | |Cu 2+ (10^(-1)M | Cu(s) :

Calculate the emf of silver-iron thermocouple with junction at 10^(@) C and 80^(@)C given alpha =+13.31 mu V.^(@)C^(-1) and beta=-0.019 mu V.^(@)C^(-2) .

The standard reduction potential for Cu^(2+)|Cu is +0.34V . Calculate the reduction potential al pH=14 for the above couple . K_(sp) of Cu(OH)_(2) is 1.0xx10^(-19)

The standard reduction potential for Cu^(2+)//Cu is +0.34V . Calculate the reduction potential at pH=14 for the above couple. K_(SP) of Cu(OH)_(2) is 1.0xx10^(-19)

Silver and copper voltmeters are connected in parallel with a battery of emf 12V . In 30 minutes, 1g of silver and 1.8g of copper are liberated. The power supplied by the battery is (Z_(Cu) = 6.6xx10^(-4) g//C and Z_(Ag) = 11.2xx10^(-4)g//C )

The standard reduction potential for Cu^(2+)//Cu is +0.34 V. Calculate the reducing potential at PH= 14 for the above couple . (K_SP) of Cu(OH)_(2) is 1.0 xx10^(-19)