`lambda_m^(@)(AgNO_3), lambda_m^(@)(HCl) and lambda_m^(@)(HNO_3)` are a,b and c `S cm^(2) mol^(-1)` respectively . If the conductivity of a saturated solution is Z S `cm^(-1)` . Then the solubility of AgCl is

^^_(m)^(0) for NaCl, HCl and NaAc are 126.4, 425.0 and 91.0 S cm^(2) mol ^(-1) respectively. Calculate ^^(0) for Hac.

The limiting molar conductivities (Lambda^(0)) for NaCl, KBr and KCl are 126, 152 and 150 S. cm^(2) "mol"^(-1) respectively. Then A for NaBr is

The conductivity of 0.20M solution of KCl at 298 K is 0.0248S cm^(-1). Calculate molar conductance.

The pH and pOH of 0.1 M aqueous solution of HNO_3 , are

lambda_(HCN) is 0.1 M solution is 20S m^(2) " mol"^(-1) lambda_(HCN)^(@) is 200S m^(2) "mol"^(-1) . The P^(H) of 0.1M HCN solution is ____________

The molar conductivities Lambda_(NaOAc)^(0) and Lambda_(HCl)^(0) at infinite dilute in water at 25^(@) C are 91.0 S cm^(2)//"mol" and 426.2 S cm^(2)//"mol" respectively . To calculate Lambda_(HOAc)^(0) the additional value required is

Molar conductivity (^^_m) is defined as conducting power of the ions produced by 1 mole of an electrolyte in a solution. ^^_m =(K)/(C) where K is conductivity (in S-cm^(-1) ), ^^_m is molar conductivity (in Scm^(2) mol^(-1) ) and C is molar concontration (in "mole"//cm^(3) ) The molar conductivity of 0.04 M solution of MgCl_2 is 200Scm^2 mol^(-1) at 298 K. A cell with electrodes that are 2.0cm^(2) in surface area and 0.50 cm apart is filled with MgCl_2 solution. The cell constant is

Line (1+lambda)x+(4-lambda)y+(2+lambda)=0 and (4-lambda)x-(1+lambda)y+(6-3lambda) =0 are concurrent at points A and B respectively and intersect at C then locus of centroid of DeltaABC " is " lambda is parameter