A solid maintained at `t_(1)^(0)` is kept in an evacuated chamber at temperature `t_(2) ""^(0)C (t_(2) gt gt t_(1))`.Rate of heat absorbed by the body

Two black bodies at temperatures 327^@ C and 427^@C are kept in an evacuated chamber at 27^@C . The ratio of their rates of loss of heat are :

Write down the Arrhenius equation relating the rate constant of reaction with temperature , mentioning what the terms indicate. If k_(1) and k_(2) be the rate constant of a reaction at temperature t_(1)^(@)C and t_(2)^(@)C , respectively, find out the relation between k_(1) ,k_(2) and t_(1) and t_(2) . Given that the activation energy (E_(a)) of the reaction remains unchanged within the temperature range mentioned. The rate constant of a reaction at 400K and 500K are 0.02s^(-1) and 0.08s^(-1) respectively . Determine the activation energy (E_(a)) of the reaction.

The rate constant and half-life of a first order reaction at temperature T_(1) " are " k_(1)"min"^(-1) and x_(1) min , respectively and those at temperature T_(2) " are "k_(2) "min"^(-1) and x_(2) min , respectively. If T_(2)gtT_(1) , which is greater , x_(1) " or, " x_(2) ?

Apparent weights of a body immersed in a liquid at the temperature t_(1) is W_(1) and temperature t_(2) is W_(2) . Coefficients of volume expansion of the liquid and the solid are gamma and gamma_(s) respectively. The value of W_(2)-W_(1) will be

At two different temperature T_(1) and T_(2), (T_(2) gt T_(1)) , draw two PV-P graphs for a definite amount of an ideal gas.

Activation energy (E_(a)) and rate constant (k_(1) and k_(2)) of a chemical reaction at two different temperatures (T_(1) and T_(2)) are related by -

At temperature T_(1) , the equilibrium constant of reaction is K_(1) . At a higher temperature T_(2),K_(2) is 10% of K_(1) . Predict whether the equilibrium is endothermic or exothermic.