A 1.00 L reaction container is filled with 0.100 mol A and is allowed to decompose...

4.60 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose...

4.60 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose into gaseous B and C. The concentration of B steadily increased until it reached 1.10 M, where it remained constant. A(s)=B(g)+C(g) Then, the container volume was doubled and equilibrium was re-established. How many moles of A remain ? mol A

5.80 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose...

5.80 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose into gaseous B and C. The concentration of B steadily increased until it reached 1.20 M, where it remained constant. A(s)=B(g)+C(g) Then, the container volume was doubled and equilibrium was re-established. How many moles of A remain?​

5.60 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose...

5.60 mol of solid A was placed in a sealed 1.00-L container and allowed to decompose into gaseous B and C. The concentration of B steadily increased until it reached 1.40 M, where it remained constant. A(s) <---> B(g) + C(g) Then, the container volume was doubled and equilibrium was re-established. How many moles of A remain?

Imagine that a chemist puts 8.48 mol each of C2H6 and O2 in a 1.00-L container...

Imagine that a chemist puts 8.48 mol each of C2H6 and O2 in a 1.00-L container at constant temperature of 284 °C. This reaction occurs: 2C2H6(g) + 7O2(g) ⇄ 4CO2(g) + 6H2O(g) When equilibrium is reached, 1.06 mol of CO2 is in the container. Find the value of Keq for the reaction at 284 °C. Find the Equilbrium constant using both concentration values and pressure values.

The reaction SO3(g) + NO(g) NO2(g) + SO2(g) has Kc = 0.500.If 0.100 mol of SO3...

The reaction SO3(g) + NO(g) NO2(g) + SO2(g) has Kc = 0.500.If 0.100 mol of SO3 and 0.200 mol NO were placed in a 2.0 L container and allowed to react, what would be the NO2 and SO2 concentrations be at equilibrium?

A 1.00 L container holds 0.015 mol of H2 (g) , 0.015 mol of I2 (g),...

A 1.00 L container holds 0.015 mol of H2 (g) , 0.015 mol of I2 (g), and 0.015 mol of HI (g) at 721 K. What are the concentrations(pressures) of H2 (g), I2 (g), and HI (g) after the system achieved a state of equilibrium? The value of Kc is 50.0 for reaction: H2 (g) + I2 (g)  2HI (g)

part a: How many moles of gas does a 1.00 L container is filled with 1.52...

part a: How many moles of gas does a 1.00 L container is filled with 1.52 atm N2, 0.12 atm O2, and 0.040 atm CO2 gases at 25 °C? part b: How many moles of N2 gas are there in a 1.0 L container which contains 1.52 atm of N2 gas at 25 ºC? part c: How many moles of O2 gas are there in a 1.0 L container which contains 0.12 atm of O2 gas at 25 ºC? part...

If 1.00 mol of argon is placed in a 0.500-L container at 30.0 ∘C , what...

If 1.00 mol of argon is placed in a 0.500-L container at 30.0 ∘C , what is the difference between the ideal pressure (as predicted by the ideal gas law) and the real pressure (as predicted by the van der Waals equation)? For argon, a=1.345(L2⋅atm)/mol2 and b=0.03219L/mol.

If 1.00 mol of argon is placed in a 0.500-L container at 29.0 ∘C , what...

If 1.00 mol of argon is placed in a 0.500-L container at 29.0 ∘C , what is the difference between the ideal pressure (as predicted by the ideal gas law) and the real pressure (as predicted by the van der Waals equation)? For argon, a=1.345(L2⋅atm)/mol2 and b=0.03219L/mol.

A 0.10-mol sample of pure ozone, O3, is placed in a sealed 1.0-L container and the...

A 0.10-mol sample of pure ozone, O3, is placed in a sealed 1.0-L container and the reaction 2O3 (g) -> 3O2(g) is allowed to reach equilibrium. A 0.50-mol sample of pure ozone is placed in a second 1.0-L container at the same temperature and allowed to reach equilibrium. Without doing any calculations, predict which of the following will be different in the two containers at equilibrium. Which will be the same? Briefly explain your answers. a) amount of O2 b)...