Certain thin walled glass bottles generally withstand a pressure difference across their walls of 1.25 atm before they bursts A typical such bottlle is sealed on a day when the temperature is `68^(@)` F and the pressure is `0.08atm` and it is immediately heated in an oven Estimate the temperature in degress fahrenheit at which it will explode .

A certain amount of gas is sealed in a glass flask at 1 atmosphere pressure and 20^(@)C . The flask can withstand upto a pressure of 2 atmosphere. Find the temperature to which gas can be heated so that the flask does not break.

A soft plastic bottle filled with water of density 1 gm/cc carries an inverted glass test tube with some air(ideal gas) trapped as shown in the figure. The test-tube has a mass of 5gm and it is made of a thick glass of density 2.5 gm/cc. Initially the bottle is sealed at atmospheric pressure p_0 = 10^5 Pa so that the volume of the trapped air is v_0 = 3.3 c . When the bottle is squeezed from outside at constant temperature, the pressure inside rises and the volume of the trapped air reduces. It is found that the test tube begins to sink at pressure p_0 + delta(p) without changing its orientation. At this pressure the volume of the trapped air is v_0 - delta(v) . Let delta(v) = X cc and delta(p) = Y x 10^3 Pa Value of X is

A soft plastic bottle filled with water of density 1 gm/cc carries an inverted glass test tube with some air(ideal gas) trapped as shown in the figure. The test-tube has a mass of 5gm and it is made of a thick glass of density 2.5 gm/cc. Initially the bottle is sealed at atmospheric pressure p_0 = 10^5 Pa so that the volume of the trapped air is v_0 = 3.3 c . When the bottle is squeezed from outside at constant temperature, the pressure inside rises and the volume of the trapped air reduces. It is found that the test tube begins to sink at pressure p_0 + delta(p) without changing its orientation. At this pressure the volume of the trapped air is v_0 - delta(v) . Let delta(v) = X cc and delta(p) = Y x 10^3 Pa Value of Y is

One mole of a certain gas is contained in a vessel of volume V = 0.250 1 . At a temperature T_1 = 300 K the gas pressure is p_1 = 90 atm , and at a temperature T_2 = 350 K the pressure is p_2 = 110 atm . Find the Van der Walls parameters for this gas

A certen amount of gas at 2.5^(@)C and at a pressure of 0.80 atm is kept in a glass vessel. Suppose that the vessel can withstand a pressure of 2.0 atm. How high can you raise the temperature of the gas without bursting the vessel?

Heat of reaction is the change in enthalpy or internal energy as represented by a balanced thermochemical equation . The amount of energy released during a chemical change depends upon the state of reactants and products, the conditions of pressure and volume at which reaction is carried out, and temperature. The variation of heat of reaction (DeltaH_(1) or DeltaE) with temperature is given as DeltaH_(2)-DeltaH_(1)=DeltaC_(P)[T_(2)-T_(1)] or DeltaE_(2)-DeltaE_(1)=DeltaC_(v)(T_(2)-T_(1). Standard heat enthalpy of elements in their most stable state is assumed to be zero whereas standard heat enthalpy of compound is referred as heat of formation of that compound at 1 atm pressure and 25^(@)C . Oxidation of N_(2) to N_(2)O,NO,NO_(2) shows absorption of energy whereas heat of combustion of N_(2) is exothermic like other heat of combustion. Heat of vaporisation of H_(2)O is 627.78cal//g . If heat of formation of H_(2)O_((l)) is -68.3kcal, heat of formation of H_(2)O_((g)) is :