Nitrogen and oxygen do not react appreciably at room temperature, as illustrated by our atmosphere. But at high temperatures, the reaction below can proceed to a measurable extent.

N₂(g) + O₂(g) ⇌ 2NO(g)

At 3000 K, the reaction above has K_c = 0.0153. If 0.3000 mol of pure NO is injected into an evacuated 2.000 L container and heated to 3000 K, what will be the equilibrium concentration of NO?

At a particular temperature, K_c = 2.0 x 10¯⁶ for the reaction:

2CO₂(g) ⇌ 2CO(g) + O₂(g)

If 2.0 mol CO₂ is initially placed into a 5.0 L vessel, calculate x?

What are the two factors to look for when determining if the reaction is at equilibrium?

For the reaction... SO₂ + O₂  <−>  SO₃ If the concentration of SO₂ is increased, the equilibrium of the reaction will shift ___________.

For the reaction... SO₂ + O₂ <−>  SO₃ If the equilibrium shifts to the right, the concentration of O₂ will ___________.

Nitrogen and oxygen do not react appreciably at room temperature, as illustrated by our atmosphere. But at high temperatures, the reaction below can proceed to a measurable extent.

N₂(g) + O₂(g) ⇌ 2NO(g)

At 3000 K, the reaction above has K_c = 0.0153. If 0.3000 mol of pure NO is injected into an evacuated 2.000 L container and heated to 3000 K, what will be the equilibrium concentration of NO?

Nitrogen and oxygen do not react appreciably at room temperature, as illustrated by our atmosphere. But at high temperatures, the reaction below can proceed to a measurable extent.

N₂(g) + O₂(g) ⇌ 2NO(g)

At 3000 K, the reaction above has K_c = 0.0153. If 0.3000 mol of pure NO is injected into an evacuated 2.000 L container and heated to 3000 K, what will be the equilibrium concentration of NO?