A metre rod of silver at `0^(@)C` is heated to `100^(@)C`. It's length is increased by 0.19 cm. coefficient of volume expansion of the silver rod is

A metal rod of length 100cm , made of silver at 0^(@)C is heated to 100^(@)C . It's length is increased by 0.19 cm . Coefficient of cubical expansion of the silver rod is

A metal rod of silver of length 100cm at 0^(@)C is heated to 100^(@)C . It's length is increased by 0.19 cm . Coefficient of cubical expansion of the silver rod is

On heating the metal rod of length 2m from 0°C to 50°C , its length is increased by 0.1 cm. the coeffecient of linear expansion of metal rod is

A uniform metal rod of 2mm^(2) area of cross section is heated from 0^(@)C to 20^(@)C . The coefficient of linear expansion of the rod is 12xx10^(-6)//""^(@)C . Its Young's modulus of elasticity is 10^(11)N//m^(2) , then the energy stored per unit volume of rod is,

On heating water from 0^(@)C to 100^(@)C its volume

The density of water at 0^@C is 0.998 g cm^(-3) at 4^@C is 1.00 g cm^(-3) . Calculate the average coefficient of volume expansion of water in the temperature range 0^@C to 4^@C .

An aluminium sphere of 20cm diameter is heated from 0^(@)C to 100^(@)C . Its volume changes by (given that the coefficient of linear expanison for aluminium (alpha_(Al) = 23 xx 10^(-6//0)C)

On heating a glass block of 10,000 cm^(3) from 25^(@)C to 40^(@)C , its volume increase by 4cm^(3) . Calculate coefficient of linear expansion of glass.

At 50^(@)C , a brass rod has a length 50 cm and a diameter 2 mm . It is joined to a steel rod of the same length and diameter at the same temperature . The change in the length of the composite rod when it is heated to 250^(@)C is (Coefficient of linear expansion of brass = 2.0 xx 10^(-5)"^(@) C^(-1) , coefficient of linear expansion of steel = 1.2 xx 10^(-5) "^(@) C^(-1) )

The density of wathr at 0^@C is 0.998 g cm^(-3) at 4^@C is 1.00 g cm^(-3) . Calculate the average coefficient of volume expansion of water in the temperature range 0 to 4^C .