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Ch.15 - Chemical Equilibrium

Chapter 15, Problem 52b

At 80Β°C, 𝐾𝑐 = 1.87Γ—10βˆ’3 for the reaction PH3BCl3(𝑠) β‡Œ PH3(𝑔) + BCl3(𝑔) (a) Calculate the equilibrium concentrations of PH3 and BCl3 if a solid sample of PH3BCl3 is placed in a closed vessel at 80Β°C and decomposes until equilibrium is reached. (b) If the flask has a volume of 0.250 L, what is the minimum mass of PH3BCl3(𝑠) that must be added to the flask to achieve equilibrium?

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Hey, everyone, we're told that the equilibrium constant for the following decomposition reaction at degrees Celsius is 2.73. What is the minimum amount of ammonia? Try flora boring Ingram's that has to be added to a 0.3 50 liter flask. In order to reach equilibrium. First, let's go ahead and write out our equilibrium expression and use that to determine the concentrations of ammonia and boron try fluoride for this specific reaction. We know that our equilibrium expression is going to be equal to the concentration of our ammonia times the concentration of our boron try fluoride. Now, the reason we do not divide this by the concentration of ammonia trifle or a boring is because it is a solid and we do not include solids and liquids in our equilibrium expression. So let's go ahead and let X equal the concentration of our ammonia, which also means it is the concentration of our boron try fluoride. Since based on so geometry, the concentrations are going to be equal. So we have our equilibrium expression and it's going to be equal to X times X. Now, when we plug in these values, we were told that our equilibrium expression is 2.73. So this is going to be equal to X squared solving for X, we're going to take the square root of both sides. So this means X is going to be equal to 1. moller. So this is our equilibrium concentration. So since the mole ratios are 1-1, this means that the mole of ammonia or the mole of boron try fluoride produce is equal to the mole of ammonia trifle or a boring required. So if we go ahead and take that 0.350 l and use dimensional analysis, we're going to take that 1.65227 moles over leaders of our ammonia and we're going to use that multiple ratio. So based on our reaction, we know that one mole of ammonia is equivalent to one mole of ammonia. Try flora boring. So when we calculate this out and cancel out all of our units, we end up with 0.578 to nine mol of our ammonia. Try flora boring. So let's go ahead and use this value of 0.578- mol to calculate the mass required. So using the molar mass of ammonia, try flora boring, we have 84.84 g of ammonia, try flora boring per one mole of ammonia, try flora boring. So when we calculate this out we end up with 49.0625 g. So simplifying this value, our answer is going to be 49.1 g. Now, I hope this made sense and let us know if you have any questions.
Related Practice
Textbook Question

At 900 K, the following reaction has 𝐾𝑝 = 0.345: 2 SO2(𝑔) + O2(𝑔) β‡Œ 2 SO3(𝑔) In an equilibrium mixture the partial pressures of SO2 and O2 are 0.135 atm and 0.455 atm, respectively. What is the equilibrium partial pressure of SO3 in the mixture?

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Textbook Question

At 218Β°C, 𝐾𝑐 = 1.2Γ—10βˆ’4 for the equilibrium NH4SH(𝑠) β‡Œ NH3(𝑔) + H2S(𝑔) (a) Calculate the equilibrium concentrations of NH3 and H2S if a sample of solid NH4SH is placed in a closed vessel at 218Β°C and decomposes until equilibrium is reached.

Textbook Question

At 80Β°C, 𝐾𝑐 = 1.87Γ—10βˆ’3 for the reaction PH3BCl3(𝑠) β‡Œ PH3(𝑔) + BCl3(𝑔) (a) Calculate the equilibrium concentrations of PH3 and BCl3 if a solid sample of PH3BCl3 is placed in a closed vessel at 80Β°C and decomposes until equilibrium is reached.

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Textbook Question

At 25Β°C, the reaction CaCrO4(𝑠) β‡Œ Ca2+(π‘Žπ‘ž) + CrO42βˆ’(π‘Žπ‘ž) has an equilibrium constant 𝐾𝑐 = 7.1Γ—10βˆ’4. What are the equilibrium concentrations of Ca2+ and CrO42βˆ’ in a saturated solution of CaCrO4?

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Textbook Question

At 2000Β°C, the equilibrium constant for the reaction 2 NO(𝑔) β‡Œ N2(𝑔) + O2(𝑔) is 𝐾𝑐 = 2.4Γ—103. If the initial concentration of NO is 0.175 M, what are the equilibrium concentrations of NO, N2, and O2?

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Textbook Question

For the equilibrium Br2(𝑔) + Cl2(𝑔) β‡Œ 2 BrCl(𝑔) at 400 K, 𝐾𝑐 = 7.0. If 0.25 mol of Br2 and 0.55 mol of Cl2 are introduced into a 3.0-L container at 400 K, what will be the equilibrium concentrations of Br2, Cl2, and BrCl?

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