If the 0.05 molar solution of `M^+` is replaced by a 0.0025 molar solution, then the magnitude of the cell potential would be ( Ecell = 70mV) :

A simple model for a concentration cell involving a metal M is M(s)|M^(o+)(aq,0.05 molar )||M^(o+)(aq,1 molar )|M(s) For the abov electrolytic cell, the magnitude of the cell potential is |E_(cell)|=70mV. If the 0.05 molar solution of M^(o+) is replaced by a 0.0025 molar M^(o+) solution, then the magnitude of the cell potential would be (a) 35mV (b) 70mV (c) 140mV (d) 700mV

A simple model for a concentration cell involving a metal M is M(s)|M^(o+)(aq,0.05 molar )||M^(o+)(aq,1 molar )|M(s) For the abov electrolytic cell, the magnitude of the cell potential is |E_(cell)|=70mV. For the above cell (a) E_(cell)lt0,DeltaGgt0 (b) E_(cell)gt0,DeltaGlt0 (c) E_(cell)lt0,DeltaG^(c-)gt0 (d) E_(cell)gt0,DeltaG^(c-)lt0

200 ml of water is added of 500 ml of 0.2 M solution. What is the molarity of this diluted solution?

2.5 litre of 1 M NaOH solution are mixed with another 3 litre of 0.5 M NaOH solution Then the molarity of the resultant solution is

When a cell is placed in 0.5 M solution of salt and no change in the volume of the cell is observed, the concentration of cell sap would be

Aqueous solution of HCl has pH = 4 . Its molarity would be

The molarity of solution obtained by dissolving 0.01 moles of NaCl in 500ml of solution is:

If 36.0 g of glucose is present in 400 ml of solution, molarity of the solution is:

The pH of 0.005 molar aqueous solution of sulphuric acid is approximately

3.0 molal NaOH solution has a density of 1.110 g//mL . The molarity of the solution is: