For the following reaction : 2NO2(g) ? N2O4(g) ?H� = -58.04 kJ/mol Try to predict what happens to the system at equilibrium if: a/ The temperature is raised? b/ The pressure of the system is increased? c/ An inert gas is added to the system at constant pressure? d/ An inert gas is added to the system at constant volume? e/ A catalyst is added to the system?
For the following reaction : 2NO2(g) ? N2O4(g) ?H� = -58.04 kJ/mol Try to predict what...
16. Consider the reaction: 2NO2(g) = N204(g) 4,Hº = -58.04 kJ/mol. Which of the following prediction about the color change of system is CORRECT knowing that NO2 is brown and N204 is colorless (assuming all other side reactions can be neglected)? A. If the system at equilibrium is heated up, the color of the gas fades away. B. When the total pressure of the system at equilibrium is increased, the color of the gas deepens. C. If a colorless inert...
The reaction N2O4(g) ⇌ 2NO2(g) has ∆G° = 13.3 kJ/mol at 25 °C. What is the value of ∆G, in kJ/mol, for this reaction at this temperature when [N2O4] = 3.0 M and [NO2] = 0.0010 M? Enter your answer to the tenths place. Do not include units. Include the sign if appropriate! Thank you for your help!
Consider the following reaction. 2NO2(g)⇌N2O4(g) When the system is at equilibrium, it contains NO2 at a pressure of 0.870 atm, and N2O4 at a pressure of 0.0757 atm. The volume of the container is then reduced to half its original volume. What is the pressure of each gas after equilibrium is reestablished?
Consider the following reaction. 2NO2(g)⇌N2O4(g) When the system is at equilibrium, it contains NO2 at a pressure of 0.722 atm, and N2O4 at a pressure of 0.0521 atm. The volume of the container is then reduced to half its original volume. What is the pressure of each gas after equilibrium is reestablished? PNO2= ?? atm PN2O4= ?? atm
1964 PC13(g) + Cl2(g) AH = 92.5 kJ/mol Predict the direction of the shift in equilibrium in the following situations: (a) The temperature is raised. the system shifts from left to right o the system shifts from right to left O no effect (b) More chlorine gas is added to the reaction mixture. the system shifts from right to left O no effect the system shifts from left to right (c) Some PCIz is removed from the mixture. the system...
Calculate the Entropy of the reaction equilibrium between 2NO2 - N2O4 given the equation: Delta G = Delta H - T Delta S where: Enthalpy = -47.5 Kj/mol Gibbs free energy = -3.59 Kj/mol Temperature = 298K
Question text Calculate the equilibrium constants, KpKp and KcKc for the equilibrium reaction N2O4(g)⇄2NO2(g)N2O4(g)⇄2NO2(g) at 298 K. N2O4(g)N2O4(g) NO2(g)NO2(g) S0S0 (J/K/mol) 304.29 240.06 ΔfH0ΔfH0 (kJ/mol) 9.16 33.18 Select one or more: A. Kp=9.23Kp=9.23 , Kc=12.3Kc=12.3 B. Kp=0.563Kp=0.563 , Kc=0.33Kc=0.33 C. Kp=0.144Kp=0.144 , Kc=0.0058Kc=0.0058 D. Kp=0.355Kp=0.355 , Kc=1.23
Decomposition of nitrogen dioxide dimer N2O4 is described by the reaction: N2O4(g) = 2NO2(g) Concentration of N2O4 became 2 times less after 2,5⋅103 s. You have to calculate: a) the value of rate constant k of the reaction; b) the value of equilibrium constant Kp. You are given the value of standard Gibb’s energy of formation Goform: substance Goform, kJ/mol NO2(g) 51.6 N2O4(g) 98.4
At a particular temperature, Kp = 0.260 for the reaction N2O4 ---> <--- 2NO2 1. A flask containing only N2O4(g) at an initial pressure of 4.20 atm is allowed to reach equilibrium. Calculate the total pressure in this flask at equilibrium. 2. With no change in the amount of material in the flask, the volume of the container in question is decreased to 0.400 times the original volume. Assuming constant temperature, calculate the (new) total pressure, at equilibrium.
For the reaction 2NO(g) + O2(g) —>2NO2(g) AH° = -114.2 kJ and AS° = -146.5 J/K The equilibrium constant for this reaction at 270.0 K is Assume that AH° and AS are independent of temperature. Submit Answer Try Another Version 3 item attempts remaining elefchces to access important values if needed for this question, Consider the reaction 2CO2(g) + 5H2(g)CH2(g) + 4H2O(g) Using the standard thermodynamic data in the tables linked above, calculate AG for this reaction at 298.15K if...