When we clap our hands, the sound produced is best described by Here p denotes the change in pressure from the equilibrium value

A vessel at 1000K contains CO_(2)(g) at 2 atm pressure. When graphite is added the following equilibrium is established. CO_(2)(g)+C(s) hArr 2CO(g) the toal pressure at equilibrium is 3 atm. The value of K_(p) is

Benzene can be produced from hexane in the reversible reaction: C_(6)H_(14) (g) The partial pressure equilibrium constant (Kp) for this reaction has been found to vary with temperature according to the equation. log K_(p) = 23.45 - (13941 K)/T Equilibrium is established by starting with pure C_6H_14 gas. What must be the temperature if the initial gas pressure is 1 atm and the equilibrium partial pressure of H_2 is 1 atm.

When we start filling an empty bucket with water, the pitch of sound produced goes on changing. Why?

Physical and chemical equilibrium can respond to a change in their pressure, temperature, and concentration of reactants and products. To describe the change in the equilibrium we have a principle named Le Chatelier principle. According to this principle, even if we make some changes in equilibrium, then also the system even re-establishes the equilibrium by undoing the effect. If we add SO_(4)^(2-) ion to a saturated solution of Ag_(2)SO_(4) , it will result in a//an

Physical and chemical equilibria can respond to a change in their pressure, temperature, and concentration of reactants and products. To describe the change in the equilibrium, we have a principle named Le Chatelier's principle. This we can define in terms of enegry, as the free energy change in equilibrium is zero means the system is stable. So if we are doing some changes in equilibrium, then the system having a tendency to reoestablish the equilibrium by undoing the effect we broughy. Consider the following equilibrium. Three sparingly soluble salts A_(2)B, AB , and AB_(3) are given. If all the three having the same value of solobility products (K_(sp)) , in the saturated solution, the correct order of their solubilites is

The pressure wave, P=0.01 sin [1000 t-3x]Nm^(-2) , corresponds to the sound produced by a vibrating blade on a day when atmospheric temperature is 0^(@)C . On some other day when temperature is T, the speed of sound produced by the same blade and at the same frequency is found to be 336 ms^(1) . Approximate value of T is:

The reaction which is in dynamic equilibrium, ensured us, that the reaction is reversible . But if that the reaction is in equilibrium. The reaction quotient predict either the reversible reaction is in equilibrium or tries to achieve equilibrium. In those reactions which have not achieved equilibrium, we obtain reaction quotient Q_(c) in place of equilibrium constant (K_(c)) by substituting the concentration of reactant and product at the time, at whih we have to calculate the value of Q_(c) . To determine the direction at which the net reaction will proceed to achieve equilibrium, we compare values of Q_(c) and K_(c) . The three possible cases are shown as comparison of K_(c) and Q_(c) in the following figures. Change in Gibbs free energy, i.e., Delta G is the driving force of any reaction. For spontaneous reaction , Delta G =-ve For non-spontaneous reaction , Delta G=+ve For reaction at equilibrium , Delta G =0 Thermodynamically, we know that Delta G= Delta G^(@)+ RT ln Q , where Q is reaction quotient and Delta G^(@)= change in Gibbs energy at standard condition. For equilibrium A(g) hArr B(g) (K_(eq) =1.732) If the pressure of the system [varied by introducing a stream of A (g) and B (g) is represented by the curve at constant temperature T. What will be the value of difference of standard Gibbs free energy to Gibbs free energy change at point Q in the figure above ?