Determine the rate constant for the recombination of I atoms in hexane at 298 K, when...

The equilibrium constant, K, for the following reaction is 1.80×10-4 at 298 K. NH4HS(s) NH3(g) +...

The equilibrium constant, K, for the following reaction is 1.80×10-4 at 298 K. NH4HS(s) NH3(g) + H2S(g) An equilibrium mixture of the solid and the two gases in a 1.00 L flask at 298 K contains 0.231 mol NH4HS, 1.34×10-2 M NH3 and 1.34×10-2 M H2S. If the concentration of H2S(g) is suddenly increased to 2.08×10-2 M, what will be the concentrations of the two gases once equilibrium has been reestablished? [NH3] = M [H2S] = M please finish it...

A copper block of mass 17.5 kg initially at 481 K is immersed in 31.5 kg...

A copper block of mass 17.5 kg initially at 481 K is immersed in 31.5 kg of water initially at 298 K. CP,m(H2O,l)=75.3J⋅K−1⋅mol−1 CP,m(Cu,s)=24.4J⋅K−1⋅mol−1 Assume that the heat capacity of Cu remains constant at its 298.15 K value over the temperature interval of interest. 1) Calculate ΔS for the water. 2) Calculate ΔS for the Cu block.

Rate constants for the reaction A → B + C are 1.55 s-1 at 298 K...

Rate constants for the reaction A → B + C are 1.55 s-1 at 298 K and 17.2 s-1 at 308 K. A. What is the activation energy (Ea) for this reaction? B. What would the rate constant be at 318 K? C. What is the order of this reaction?

A) Calculate KP at 298 K for the reaction NO(g)+1/2O2(g)→NO2(g) assuming that ΔH∘R is constant over...

A) Calculate KP at 298 K for the reaction NO(g)+1/2O2(g)→NO2(g) assuming that ΔH∘R is constant over the interval 298-600K. NOTE: I can tell you for sure the following answers are wrong: 7.2*10^10; 1.38*10^-11; 10.35; 14.65 B: Calculate KP at 475 K for this reaction assuming that ΔH∘R is constant over the interval 298-600 K. My prof told me to use: ln(K2/K)=-ΔH/(1/T2-1/T1) but it is not working for me NOTE: the following answers are wrong: 1.16*10^7; 6.26*10^6; 102

Air at 1 bar, 295 K, and a mass flow rate of 0.7 kg/s enters a...

Air at 1 bar, 295 K, and a mass flow rate of 0.7 kg/s enters a compressor operating at steady state and exits at 3 bar. During the compressing from inlet to exit, the air experiences a polytropic process as PV^n=constant. m=6, n=1.48. (1) Determine the power required by the compressor. (2) Determine the heat transfer between the compressor and the surrounding. (s) Determine the rate of exergy destruction. Kinetic and potential energy effects are negligible. Let T_0 = 300...

Air at 1 bar, 295 K, and a mass flow rate of 0.7 kg/s enters a...

Air at 1 bar, 295 K, and a mass flow rate of 0.7 kg/s enters a compressor operating at steady state and exits at 3 bar. During the compressing from inlet to exit, the air experiences a polytropic process as PV^n=constant. m=6, n=1.48 (1) Determine the power required by the compressor. (2) Determine the heat transfer between the compressor and the surrounding. (s) Determine the rate of exergy destruction. Kinetic and potential energy effects are negligible. Let T_0 = 300...

The rate constant k for the following reaction                                   &nb

The rate constant k for the following reaction                                     H2O2 + 2KI + 2H+ = 2H2O + I2(aq) + 2K+ was found to vary with temperature when the reactant concentrations were held constant at [H2O2] = 0.556 M and [KI] = 120 M. a) temperature = 44.5 degrees Celsius; rate of constant (k) = 1.66 x 10-3 k b) temperature = 35 degrees Celsius; rate of constant (k) = 1.02 x 10-3​ k c) temperature = 25.7 degrees Celsius; rate...

The rate constants for the reaction of oxygen atoms with benzene have been reported to be:...

The rate constants for the reaction of oxygen atoms with benzene have been reported to be: k (M-1 s-1) 1.44 x 107 3.03 x 107 6.90 x 107 T (oC) 27.2 68.0 119 Determine the activation energy and pre-exponential constant for this reaciton

7. Consider the following reaction: 2NO2 (g) -> 2NO(g) + O2 (g) rate = k[NO2]^2 When...

7. Consider the following reaction: 2NO2 (g) -> 2NO(g) + O2 (g) rate = k[NO2]^2 When the initial concentration of NO2 is 100 mM, it takes 55 s for 90% of the NO2 to react. Calculate the rate constant. a) 0.042 M–1·s–1 d) 1.6 ´ 10–3 M–1·s–1 b) 1.8 ´ 10–5 M–1·s–1 e) 0.13 M–1·s–1 c) 1.6 M–1·s–1 I am getting d.) but i am not sure, please confirm

Laser Cooling of Atoms: In the simplest versions of laser cooling, a gas of atoms can...

Laser Cooling of Atoms: In the simplest versions of laser cooling, a gas of atoms can be cooled from room temperature (?300 K) to about 1 × 10-4 K through the absorption of light. The absorbed light transfers momentum to the atoms, thereby slowing down those atoms that are moving in the direction of the incoming laser beam. The following questions refer to a gas of rubidium atoms. (a) The average speed of atoms in the gas phase is directly...