I only need a the answer. No explanation needed please **Problem Statement:**A flexible container at an initial volume of 8.15 L contains 8.51 mol of gas. More gas is then added to the container until it reaches a final volume of 18.7 L. Assuming the pressure and temperature of the gas remain constant, calculate the number of moles of gas added to the container.**Calculation Area:**Number of moles of gas: [ _______ ] mol---**Explanation:**This problem involves the application of the Ideal Gas Law in the context of the addition of gas to a system at constant pressure and temperature. ### Steps to Solve:1. **Use the formula**: \[ \text{PV} = \text{nRT} \] Since temperature (T) and pressure (P) are constant, the ratio \(\frac{V}{n}\) is also a constant.2. **Initial state**: - Volume (\(V_1\)) = 8.15 L - Moles (\(n_1\)) = 8.51 mol3. **Final state**: - Volume (\(V_2\)) = 18.7 L - Moles (\(n_2\)) = Unknown (we need to find this)4. **Relate initial and final states** using: \(\frac{V_1}{n_1} = \frac{V_2}{n_2}\)5. **Solve for \(n_2\)**: \[ n_2 = \frac{V_2 \times n_1}{V_1} \]6. **Calculate the moles of gas added**: \[ \text{Moles added} = n_2 - n_1 \]Use these equations to find the number of moles added to the gas.

According to Avogadro's law, volume (V) is directly proportional to the number of moles (n) of gas when the pressure (P) and temperature (T) are kept constant. The expression of Avogadro's law is as follows: Vα nThe modified expression of Avogadro's law is as follows: V1n1=V2n2 Here, V1 and n1 are the initial volume and initial number of moles of gas. V2 and n2 are the final volume and final number of moles of gas. The final number of moles is calculated as follows: 8.15 L8.51 mol=18.7 Ln2n2=18.7 L8.51 mol8.15 L=19.5 molThe number of moles added can be calculated as follows: Number of moles=n2-n1=19.5 mol-8.51 mol=11.0 mol Hence, the number of moles added is 11.0 mol.