A 200 mm long tube containing 48 `cm^(3)` of sugar solution produces an optical rotation of `11^(@)` when placed in a suucharimeter. If the specific rotation of sugar is `66^(@)` calculate the quantity of sugar contained in the solution of the tube.

A 300 mm long tube containing 60 cm^(3) of sugar solution produces an optical rotations of 10^(@) when placed in a saccharimeter. If specific rotation of sugar is 60^(@) calculate the quantity of sugar constained in te tube solution.

If solution of a compound ( 30g//100ml of solution ) has measured rotation of +15^(@) in a 2 dm long sample tube, the specific rotation of this compound is

80 gm of impure sugar when dissolved in a litre of water gives an optical rotation of 9.9^(@) when placed in a tube of length 20 cm. If concentration of sugar solution is 75 gm/litre then specific rotation of sugar is :

On putting a polarimeter tube 25cm long comtaining sugar solution of unknown strength, the plane of polarisation gets rotated through 10^(@) . Find the strength of sugar solution I n g cm^(-3) specific rotation of sugar is 60%(@) //"decimeter"//"unit concenteration" .

A polarimeter tube of length 0.21m contains sugar solution of specific rotation 0.01 rad m^(-1)kg^(-1)m^(3) concentration. If the produced is 36^(@) , calculate the concentration of the solution. The solution is the tube is poured into a clean beaker and equal amount of water id added to it. The tube is then filled with the diluted solution. Calculate the angle of rotation produced.

If specific rotation of glucose solution is 52^@ and fructose solution -92^@ then what will be specific rotaion of invert sugar ?

A Solution contains 30 g of sugar dissolved in 370 g of water, Calculate the concentration of this solution .