The rates of cooling of a body at temperatures `100^(@)C and 80^(@)` are` x_(1) and x_(2)` respectively, when placed in a room of temperature `40^(@)C `then `(x_(1))/(x_(2))` is

The rate of emission of radiation of a black body at temperature 27^(@)C is E_(1) . If its temperature is increased to 327^(@)C the rate of emission of radiation is E_(2) . The relation between E_(1)andE_(2) is

Standar entropies of x_(2), y_(2) and xy_(3) are 60,40 and 50JK^(-1) mol^(-1) respectively for the reaction to be at equilibrium, the temperature should be (1)/(2) x_(2) + (3)/(2) y_(2) hArr xy_(3) Delta H= - 30kJ

The temperature of body is increased from T_(1)=127^(@)C" to "T_(2)=227^(@)C . The ambient temperature is 27^(@) C. The energies emitted per second by the body at T_(1)andT_(2) are E_(1)andE_(2) respectively. The ratio of (E_(2))/(E_(1)) is