Real Gases and van der Waals Equation
States of Matter: Real Gases and van der Waals Equation
Real Gases and van der Waals Equation
Real Gases and van der Waals Equation
What you'll learn
- Identify why real gases deviate from ideal behaviour at high pressure and low temperature
- Apply the van der Waals equation with constants a and b
- Interpret the compressibility factor Z and its deviation from 1
- Understand Boyle temperature and its physical significance
- Derive and use critical constants T_c, P_c, and V_c in terms of a and b
- Compare ideal vs real pressure in numerical problems
Key concepts
Level 1 — Foundations
Why ideal gas fails: The ideal gas model assumes:
- Zero molecular volume (negligible size)
- No intermolecular forces
Both assumptions fail at:
- High pressure: molecules are forced close together → their finite volume matters; repulsions are strong
- Low temperature: molecules move slowly → intermolecular attractions become significant relative to KE
Real behaviour: at high P, gases occupy less volume than ideal (attractions) or more (repulsions dominate at very high P).
Level 2 — JEE depth
van der Waals Equation (for n moles):
(P + an²/V²)(V − nb) = nRT
- a (L² atm mol⁻²): corrects for intermolecular attractions; higher a = stronger attractions (e.g., CO₂ > N₂ > He)
- b (L mol⁻¹): corrects for finite molecular volume (excluded volume); b ≈ 4 × actual volume per mole of molecules
For 1 mole: (P + a/V²)(V − b) = RT
The term an²/V² is the internal pressure — molecules near the wall are pulled back by interior molecules, reducing the effective pressure.
Compressibility Factor Z: Z = PV/nRT (= PV_m/RT for 1 mole)
| Z value | Interpretation | Dominant effect |
|---|---|---|
| Z = 1 | Ideal behaviour | — |
| Z < 1 | Gas more compressible than ideal | Attractive forces dominate |
| Z > 1 | Gas less compressible than ideal | Repulsive forces / finite volume |
At low P: Z → 1 for all gases (both corrections negligible) At intermediate P: Z dips below 1 (attractions win) At very high P: Z > 1 (volume correction dominates)
Boyle Temperature (T_B): The temperature at which a real gas behaves most like an ideal gas over a wide range of pressures (Z ≈ 1 for large P range):
T_B = a/(bR)
For N₂: a = 1.39 L² atm/mol², b = 0.0391 L/mol → T_B = 1.39/(0.0391 × 0.0821) ≈ 433 K
Critical Constants: At the critical point, the gas-liquid distinction disappears (single phase).
T_c = 8a / (27Rb) P_c = a / (27b²) V_c = 3nb (for n moles; V_c = 3b for 1 mole)
At critical point: Z_c = P_cV_c/(RT_c) = 3/8 = 0.375 (universal for van der Waals gas)
From a and b you can calculate all three critical constants, and vice versa: a = 3P_cV_c² (with V_c per mole) = 27R²T_c²/(64P_c) b = V_c/3 = RT_c/(8P_c)
JEE trap: The van der Waals equation is cubic in V — for a given P and T it may have up to three real roots. Below T_c the three roots correspond to vapour volume, unstable region, and liquid volume.
JEE trap: When comparing P_ideal and P_real: P_real = RT/(V−b) − a/V² and P_ideal = RT/V. Since the a/V² term decreases P, and the (V−b) term increases P, which effect wins depends on conditions.
Worked example
CO₂ (a = 3.59 L² atm mol⁻², b = 0.0427 L/mol): 1 mol, V = 2 L, T = 300 K. Compare P from ideal vs vdW.
Ideal gas:
P_ideal = nRT/V = (1 × 0.0821 × 300) / 2 = 24.63 / 2 = 12.315 atm
van der Waals:
P_vdW = [RT/(V − b)] − a/V²
= [0.0821 × 300 / (2 − 0.0427)] − 3.59/2²
= [24.63 / 1.9573] − 3.59/4
= 12.583 − 0.8975
= 11.686 atm
P_vdW < P_ideal because at these conditions (moderate V),
intermolecular attractions reduce pressure compared to ideal.
Difference: 12.315 − 11.686 = 0.629 atm (about 5% error from ideal)
Find Boyle temperature for N₂ (a = 1.39 L² atm mol⁻², b = 0.0391 L/mol)
T_B = a / (bR)
= 1.39 / (0.0391 × 0.0821)
= 1.39 / 0.003210
= 433 K ≈ 160°C
At 433 K, N₂ behaves most like an ideal gas over a wide pressure range.
Note: This is well above room temperature, which is why N₂ is
approximately ideal under ordinary lab conditions.
Common mistakes
| Mistake | Why it happens | Fix |
|---|---|---|
| Applying ideal PV=nRT at high P | Habit of using simpler formula | Check conditions: if P > 10 atm or T near condensation, use vdW |
| Forgetting n² in an²/V² | Using a/V² for n moles | Correction is an²/V² for n moles; a/V² only when n=1 |
| Thinking Z<1 always means real gas deviates badly | Z<1 can be small deviation | Size of deviation = |
| Confusing a and b roles | Both are "corrections" so students mix them | a → attractions (pressure correction); b → volume (size correction) |
Quick check
- Q1: For a gas with a = 4.0 and b = 0.05, calculate the Boyle temperature.
- Q2: At very high pressure, is Z for a real gas greater than, less than, or equal to 1? Explain.
- Q3: Which gas has larger 'a': N₂ or NH₃? Why?
- Q4: Calculate T_c for CO₂ using a = 3.59 L² atm/mol², b = 0.0427 L/mol, R = 0.0821 L atm/mol·K.
- Stretch: Q5: Show that for a van der Waals gas, Z_c = P_cV_c/(RT_c) = 3/8, using the critical constant expressions.
NCERT Chapter 5 link: Chapter 5 (Class 11) — Section 5.8 covers deviation from ideal behaviour, compressibility factor plots (Z vs P for different gases), van der Waals equation, and critical constants. The Z vs P plots are directly tested in JEE as interpretation questions.
Exam connections: JEE Mains frequently tests: (a) whether Z > 1 or < 1 at given conditions, (b) comparing P_ideal and P_vdW, (c) which van der Waals constant is larger for a given pair of gases, (d) calculating one critical constant given a and b. JEE Advanced may require deriving critical constants from the vdW equation.
Study strategy: Sketch the Z vs P graph for N₂, CO₂, and H₂ at room temperature — this visual locks in which effect (attraction vs repulsion) dominates at each pressure range. Then do 5 numerical problems each for P_vdW vs P_ideal comparisons and critical constant calculations.
Interactive Exploration Suggestions (Drishti Live Worlds)
- Use the platform-native live simulation or PhET-style tool for this topic.
- Mirror / body / home activity: observe that a sealed syringe is harder to compress as you push it — this is the excluded-volume effect. Describe what you feel and relate it to the b constant.
- Voice or text reflection with AI Mentor: explain the concept to a younger student or family member.
AI Mentor Prompts (Socratic, Board-Adaptive)
- "Explain this concept to a Class 6 student using one real example from an Indian home, school, market, or festival."
- "What is one common mistake students make here, and how would you catch yourself making it?"
- Stretch: "How does this connect to coding, robotics, money, health, environment, or a future career?"
Gamification, Portfolio & Parent Visibility
- Complete the core practice + one extension activity (photo, table, short reflection, or mini-project) for base XP + topic badge.
- 5-7 day streak or family discussion note = multiplier + visible artifact in parent/principal dashboard.
- Best real-world application stories (anonymised) featured on class or national leaderboard.
Robotics, STEM & Future Skills Bridges
- One hands-on project or measurement using the Drishti kit or household items that makes the concept physical.
- Direct link to at least one Future Skill track (Money Management, Green Tech, Cyber Defenders, Micro-Entrepreneurship, AI Mastery, Sustainable Living, Personality Development).
- Coding extension where relevant (simple script, simulation, or data logging).
NEP 2020 & Full Education OS Alignment
This material emphasises experiential "learning by doing", competency (apply/create/analyse), vocational exposure, critical thinking, and multidisciplinary connections. Designed to feed live worlds, AI Mentor (with memory), gamification, robotics, parent analytics, and future skills — not just exam prep.
Portfolio Evidence Idea: Your photo/table/reflection/project + one sentence on "How this helps me in real life or a possible future path."
Open the Practice tab for aligned questions (easy/medium/hard + case-based) with full AI scaffolding.
See curriculum for cross-links and the full future-skills/robotics chapters.
Key Takeaways (TL;DR)
- What you'll learn
- Key concepts
- Worked example
- Common mistakes
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