First, we need to find the equilibrium constant Kc for the reaction using the initial concentrations:Kc = [NOBr]^2 / [NO]^2 * [Br2] Using the initial concentrations:Kc = 0.40 ^2 / 0.10 ^2 * 0.20 = 0.16 / 0.002 = 80Now, let's consider the new situation where the concentration of Br2 is doubled, i.e., 0.20 M * 2 = 0.40 M. Let x be the change in concentration of NOBr at the new equilibrium.For the new equilibrium concentrations, we have:[NOBr] = 0.40 + x[NO] = 0.10 - 0.5x since 2 moles of NO react for every 1 mole of Br2 [Br2] = 0.40 - xNow, we can use the Kc value to find the new equilibrium concentrations:80 = [ 0.40 + x ^2] / [ 0.10 - 0.5x ^2] * 0.40 - x Now, we need to solve this equation for x:80 0.10 - 0.5x ^2 0.40 - x = 0.40 + x ^2This equation is quite complex to solve analytically, so we can use numerical methods or a calculator to find the value of x:x 0.131Now, we can find the new equilibrium concentration of NOBr:[NOBr] = 0.40 + x = 0.40 + 0.131 0.531 MSo, the new equilibrium concentration of NOBr is approximately 0.531 M.