`Lambda_m^@ H_2O` is equal to

Lambda_m^@(NH_4OH) is equal to

Calculate the Lambda_m^@ for NH_4OH given that the values of Lambda_m^@ for Ba(OH)_2 , BaCl_2 and NH_4Cl are 523.28, 280.0 and 129.8 s cm^2 mol^-1 respectively.

if A=[(1,2),(2,3)] and A^(2) -lambdaA-l_(2)=O, then lambda is equal to

P is any point on the hyperbola x^(2)-y^(2)=a^(2) . If F_1 and F_2 are the foci of the hyperbola and PF_1*PF_2=lambda(OP)^(2) . Where O is the origin, then lambda is equal to

If [axxb bxxc c xxa]=lambda[abc]^(2) , then lambda is equal to

If [vecaxxvecb vecbxxvecc veccxxveca]=lambda[veca vecb vecc]^2 , then lambda is equal to :

The following curve is obtained when molar conductivty, Lambda_m is plotted against the square rot of concentration, C^(1//2) along y and x axis respectively for the two electrolytes X and Y. How do you account for the increase in Lambda_m for the electolytes X and Y with dilution?

If the circumcentre of the triangle whose vertices are (3, 2, -5) , (-3, 8, -5) and (-3, 2, 1) is (-1, lambda, -3) the integer lambda must be equal to……

H_2O has structure

If the matrix A = [[lambda_(1)^(2), lambda_(1)lambda_(2), lambda_(1) lambda_(3)],[lambda_(2)lambda_(1),lambda_(2)^(2),lambda_(2)lambda_(3)],[lambda_(3)lambda_(1),lambda_(3)lambda_(2),lambda_(3)^(2)]] is idempotent, the value of lambda_(1)^(2) + lambda_(2)^(2) + lambda _(3)^(2) is