thermodynamics formulas pyqs - physicstutor.kumarphysicsclasses.com

How to Use This Final Sheet

Thermodynamics questions usually become easy when you first identify the process, then choose the correct energy balance.

Step 1: Identify Process

Check whether the process is isothermal, adiabatic, isochoric, isobaric, cyclic, or a heat-engine/refrigerator cycle.

Step 2: Apply First Law

Use ΔU = Q - W. Decide signs: heat supplied positive, work done by system positive.

Step 3: Use Graph Meaning

Area under P-V graph gives work. Area inside a closed clockwise loop gives positive net work.

Step 4: Convert Units

Use kelvin temperature in ideal-gas, Carnot and entropy formulae. Convert litres to m³ if using SI pressure.

Step 5: Check Limitation

Heat engines cannot be 100% efficient. Refrigerators need work input to pump heat from cold to hot.

Step 6: Interpret Result

Negative work usually means compression. Positive entropy of universe means a natural irreversible process.

Complete Formula Sheet

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

Q = mcΔT

Symbols: Q is heat, m is mass, c is specific heat capacity, ΔT is temperature change.

Use: Used when temperature changes but no phase change occurs.

Exam tip: Use kelvin or degree Celsius for ΔT; the numerical change is the same.

Q = mL

Symbols: m is mass and L is latent heat.

Use: Used during change of state at constant temperature.

Exam tip: Do not add mcΔT during pure melting or boiling at constant temperature.

C = Q/ΔT

Symbols: C is heat capacity of the whole body.

Use: Heat needed per unit temperature rise of the body.

Exam tip: Do not confuse C with c; C depends on mass.

c = Q/(mΔT)

Symbols: c is specific heat capacity.

Use: Heat needed per kg per kelvin rise.

Exam tip: Check units: J kg^-1 K^-1.

W = ∫P dV

Symbols: W is work done by gas, P is pressure, dV is small volume change.

Use: General work formula for expansion/compression.

Exam tip: Area under P-V graph gives work.

ΔU = Q - W

Symbols: ΔU is change in internal energy, Q is heat supplied, W is work done by system.

Use: First law with physics sign convention.

Exam tip: If work is done on gas, W is negative.

PV = nRT

Symbols: P pressure, V volume, n moles, R gas constant, T kelvin temperature.

Use: Ideal gas equation.

Exam tip: Temperature must be in kelvin.

U = nC_VT

Symbols: U is internal energy of ideal gas.

Use: Internal energy depends only on temperature for ideal gas.

Exam tip: For ideal gas, ΔU = nC_VΔT.

C_P - C_V = R

Symbols: C_P and C_V are molar heat capacities.

Use: Mayer's relation for ideal gas.

Exam tip: Use molar heat capacities, not total heat capacities.

γ = C_P/C_V

Symbols: γ is adiabatic index.

Use: Used in adiabatic relations.

Exam tip: For monoatomic ideal gas γ = 5/3; diatomic near room temperature γ = 7/5.

η = W/Q_H

Symbols: η is efficiency, W work output, Q_H heat absorbed.

Use: Heat engine efficiency.

Exam tip: Efficiency is always a fraction or percentage, not COP.

ΔS = Q_rev/T

Symbols: ΔS entropy change for reversible heat transfer at T.

Use: Basic entropy formula.

Exam tip: Use reversible path for entropy change.

Heat Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

Q = mcΔT

Symbols: m mass, c specific heat capacity, ΔT final minus initial temperature.

Use: Sensible heat formula.

Exam tip: Use this only when no phase change occurs.

Q = mL_f

Symbols: L_f is latent heat of fusion.

Use: Heat during melting/freezing.

Exam tip: Melting Q positive for system; freezing Q negative for system.

Q = mL_v

Symbols: L_v is latent heat of vaporization.

Use: Heat during boiling/condensation.

Exam tip: Vaporization needs larger heat than fusion for water.

1 cal = 4.186 J

Symbols: calorie and joule are heat units.

Use: Unit conversion.

Exam tip: In school problems, 1 cal ≈ 4.2 J is often acceptable.

J = W/H

Symbols: J is mechanical equivalent of heat.

Use: Relates mechanical work and heat.

Exam tip: Historical value: J ≈ 4.186 J cal^-1.

Q_lost = Q_gained

Symbols: Heat lost by hotter body equals heat gained by colder body in an isolated mixture.

Use: Calorimetry principle.

Exam tip: Apply only if heat losses to surroundings are neglected.

mc(θ - θ_f) = m'c'(θ_f - θ')

Symbols: θ_f is final equilibrium temperature.

Use: Mixing two bodies without phase change.

Exam tip: Final temperature lies between initial temperatures.

Q = nCΔT

Symbols: n moles, C molar heat capacity.

Use: Molar form of heat formula.

Exam tip: Use C_P at constant pressure and C_V at constant volume.

Work Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

W = ∫P dV

Symbols: P external pressure in quasi-static process, dV volume change.

Use: General work by gas.

Exam tip: Expansion gives positive W; compression gives negative W.

W = PΔV

Symbols: P constant pressure.

Use: Work in isobaric process.

Exam tip: Use only when pressure is constant.

W = nRT ln(V₂/V₁)

Symbols: n moles, R gas constant, T constant temperature.

Use: Isothermal work by ideal gas.

Exam tip: Expansion has V₂ > V₁, so W positive.

W = 2.303 nRT log(V₂/V₁)

Symbols: Common-log version of isothermal work.

Use: Use when log base 10 is provided.

Exam tip: Do not mix ln and log without 2.303 factor.

W = (P₁V₁ - P₂V₂)/(γ - 1)

Symbols: Adiabatic reversible work by gas.

Use: Useful in adiabatic expansion/compression.

Exam tip: Sign depends on initial and final states.

W = nC_V(T₁ - T₂)

Symbols: Ideal gas adiabatic work by gas.

Use: For Q = 0, W = -ΔU.

Exam tip: Expansion cools gas, so T₁ > T₂ and W positive.

W_cycle = area enclosed

Symbols: Closed P-V loop area.

Use: Net work in cyclic process.

Exam tip: Clockwise loop: positive work by engine.

W = 0 for ΔV = 0

Symbols: Volume constant.

Use: Isochoric work.

Exam tip: No boundary work in constant-volume process.

Internal Energy Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

ΔU = nC_VΔT

Symbols: n moles, C_V molar heat capacity at constant volume.

Use: Change in internal energy of ideal gas.

Exam tip: Depends only on temperature for ideal gas.

U = (f/2)nRT

Symbols: f degrees of freedom.

Use: Internal energy of ideal gas.

Exam tip: Monoatomic f=3; diatomic near room temperature f=5.

U = (3/2)nRT

Symbols: For monoatomic ideal gas.

Use: Internal energy of monoatomic gas.

Exam tip: Use for He, Ne, Ar ideal-gas problems.

U = (5/2)nRT

Symbols: For diatomic ideal gas without vibration.

Use: Approximate internal energy near room temperature.

Exam tip: Use when problem says diatomic ideal gas.

ΔU = 0 for isothermal ideal gas

Symbols: Temperature constant.

Use: Internal energy change in isothermal ideal-gas process.

Exam tip: If ΔT = 0, ΔU = 0.

ΔU = Q for isochoric process

Symbols: W = 0 because ΔV = 0.

Use: First law at constant volume.

Exam tip: All supplied heat changes internal energy.

ΔU = -W for adiabatic process

Symbols: Q = 0.

Use: First law in adiabatic process.

Exam tip: Work by gas decreases internal energy.

ΔU_cycle = 0

Symbols: Initial and final states are same.

Use: Cyclic process.

Exam tip: Internal energy is a state function.

First Law Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

ΔQ = ΔU + ΔW

Symbols: Heat supplied equals internal energy change plus work done by system.

Use: First law in differential form.

Exam tip: Use signs carefully.

ΔU = ΔQ - ΔW

Symbols: Change in internal energy equals heat supplied minus work done by system.

Use: Most common physics convention.

Exam tip: W positive for expansion.

Q = W for isothermal ideal gas

Symbols: ΔU = 0.

Use: First law for isothermal ideal gas.

Exam tip: Heat absorbed becomes work done.

Q = ΔU for isochoric process

Symbols: W = 0.

Use: Constant-volume heating or cooling.

Exam tip: P-V graph is vertical line.

Q = ΔU + PΔV

Symbols: Pressure constant.

Use: Isobaric first law.

Exam tip: Use W = PΔV.

Q = 0 in adiabatic process

Symbols: No heat exchange.

Use: Thermally insulated or very fast process.

Exam tip: First law becomes ΔU = -W.

Q_cycle = W_cycle

Symbols: ΔU_cycle = 0.

Use: For a complete cycle.

Exam tip: Net heat absorbed equals net work output.

ΔU = Q + W_on

Symbols: W_on is work done on system.

Use: Alternative chemistry convention.

Exam tip: Do not mix W by system and W on system in same solution.

Process Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

PV = constant

Symbols: For isothermal ideal gas.

Use: Boyle relation at constant temperature.

Exam tip: Only valid for fixed amount of ideal gas.

PV^γ = constant

Symbols: γ = C_P/C_V.

Use: Reversible adiabatic relation.

Exam tip: Do not use for irreversible free expansion.

TV^γ-1 = constant

Symbols: T kelvin, V volume.

Use: Adiabatic temperature-volume relation.

Exam tip: Useful when pressure is absent.

T^γP^1-γ = constant

Symbols: T kelvin, P pressure.

Use: Adiabatic pressure-temperature relation.

Exam tip: Convert Celsius to kelvin.

V/T = constant

Symbols: Pressure constant.

Use: Isobaric ideal-gas relation.

Exam tip: Charles law.

P/T = constant

Symbols: Volume constant.

Use: Isochoric ideal-gas relation.

Exam tip: Pressure law.

W_isothermal = nRT ln(V₂/V₁)

Symbols: T constant.

Use: Work in isothermal ideal gas process.

Exam tip: Expansion positive, compression negative.

W_isobaric = P(V₂ - V₁)

Symbols: P constant.

Use: Work at constant pressure.

Exam tip: Area under horizontal P-V line.

W_isochoric = 0

Symbols: V constant.

Use: No volume change.

Exam tip: Vertical P-V line has zero area.

Q_adiabatic = 0

Symbols: No heat exchange.

Use: Adiabatic process.

Exam tip: Temperature can still change.

Carnot Engine Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

W = Q_H - Q_C

Symbols: Heat engine energy balance.

Use: Net work per cycle.

Exam tip: Q_C is rejected heat magnitude.

η = W/Q_H

Symbols: Efficiency definition.

Use: Useful work output per heat input.

Exam tip: η is less than 1.

η = 1 - Q_C/Q_H

Symbols: Equivalent heat-engine efficiency.

Use: Uses absorbed and rejected heat.

Exam tip: If Q_C decreases, efficiency increases.

η_Carnot = 1 - T_C/T_H

Symbols: T in kelvin.

Use: Maximum possible engine efficiency.

Exam tip: Never use Celsius.

Q_C/Q_H = T_C/T_H

Symbols: Carnot reversible relation.

Use: Connects heat and reservoir temperatures.

Exam tip: Use magnitudes of heat.

COP_R = Q_C/W

Symbols: Refrigerator COP.

Use: Cooling obtained per work input.

Exam tip: COP can be greater than 1.

COP_R,Carnot = T_C/(T_H - T_C)

Symbols: Ideal refrigerator temperatures in kelvin.

Use: Maximum COP of refrigerator.

Exam tip: COP rises when temperature gap is small.

COP_HP = Q_H/W

Symbols: Heat pump COP.

Use: Heating obtained per work input.

Exam tip: Heat pump COP = refrigerator COP + 1.

COP_HP,Carnot = T_H/(T_H - T_C)

Symbols: Ideal heat pump COP.

Use: Maximum heating performance.

Exam tip: Use when desired output is heating.

Entropy Formulae

Every card gives the formula, symbols, meaning and exam tip so that revision remains quick but not shallow.

ΔS = Q_rev/T

Symbols: Reversible heat transfer at constant T.

Use: Basic entropy change.

Exam tip: Use reversible path even for irreversible actual process.

ΔS ≥ 0 for isolated system

Symbols: Equality reversible, greater than zero irreversible.

Use: Second law in entropy form.

Exam tip: System entropy may decrease, universe entropy cannot.

ΔS_universe = ΔS_system + ΔS_surroundings

Symbols: Total entropy balance.

Use: Spontaneity test.

Exam tip: For natural irreversible process, total is positive.

ΔS = nC_V ln(T₂/T₁) + nR ln(V₂/V₁)

Symbols: Ideal gas entropy change using T and V.

Use: General ideal-gas entropy formula.

Exam tip: Use kelvin temperatures.

ΔS = nC_P ln(T₂/T₁) - nR ln(P₂/P₁)

Symbols: Ideal gas entropy change using T and P.

Use: Alternative entropy formula.

Exam tip: Pressure ratio must be dimensionless.

ΔS = nR ln(V₂/V₁)

Symbols: Isothermal ideal-gas entropy change.

Use: Because ΔT = 0.

Exam tip: Free expansion entropy can be calculated by reversible isothermal path.

ΔS = mL/T

Symbols: Phase change at constant T.

Use: Melting or boiling entropy change.

Exam tip: Positive for melting/vaporization, negative for freezing/condensation.

ΔS_total = -Q/T_H + Q/T_C

Symbols: Heat Q flows from hot to cold.

Use: Entropy generated in natural heat transfer.

Exam tip: Since T_H > T_C, total is positive.

NCERT Examples: Important Solved Models

These original NCERT-style models cover the calculation patterns repeatedly used in school exams and entrance exams.

NCERT-Style Example 1: Calorimetry

A 0.5 kg metal block cools from 80°C to 30°C. If c = 400 J kg^-1 K^-1, find heat lost.

Show Solution

Given: m = 0.5 kg, c = 400 J kg^-1 K^-1, ΔT = 50 K.

Formula: Q = mcΔT.

Solution: Q = 0.5 × 400 × 50 = 10000 J. Since it cools, heat lost by block is 10000 J.

Final Answer: 1.0 × 10⁴ J lost.

NCERT-Style Example 2: Latent Heat

How much heat is required to melt 20 g of ice at 0°C? L_f = 3.34 × 10⁵ J kg^-1.

Show Solution

Given: m = 0.020 kg, L_f = 3.34 × 10⁵ J kg^-1.

Formula: Q = mL.

Solution: Q = 0.020 × 3.34 × 10⁵ = 6680 J.

Final Answer: 6.68 × 10³ J.

NCERT-Style Example 3: Ideal Gas Work

One mole of ideal gas expands isothermally at 300 K from 2 L to 4 L. Find work done.

Show Solution

Given: n = 1, T = 300 K, V₂/V₁ = 2.

Formula: W = nRT ln(V₂/V₁).

Solution: W = 1 × 8.314 × 300 × ln2 = 1728 J approximately.

Final Answer: 1.73 × 10³ J.

NCERT-Style Example 4: Isochoric Heating

A gas is heated at constant volume and absorbs 600 J. Find work and internal energy change.

Show Solution

Given: Q = 600 J, ΔV = 0.

Formula: W = 0, ΔU = Q - W.

Solution: At constant volume, W = 0. ΔU = 600 - 0 = 600 J.

Final Answer: W = 0, ΔU = 600 J.

NCERT-Style Example 5: Isothermal Ideal Gas

An ideal gas absorbs 500 J heat in an isothermal expansion. Find ΔU and W.

Show Solution

Given: Q = 500 J, isothermal ideal gas.

Formula: ΔU = 0, Q = W.

Solution: For an ideal gas, internal energy depends only on temperature. Since T constant, ΔU = 0 and W = Q = 500 J.

Final Answer: ΔU = 0, W = 500 J.

NCERT-Style Example 6: Adiabatic Process

In an adiabatic expansion, a gas does 300 J work. Find heat exchanged and internal energy change.

Show Solution

Given: W = 300 J, adiabatic.

Formula: Q = 0, ΔU = Q - W.

Solution: ΔU = 0 - 300 = -300 J.

Final Answer: Q = 0, ΔU = -300 J.

NCERT-Style Example 7: Cyclic Process

In a cycle, a gas absorbs net 700 J heat. Find net work done.

Show Solution

Given: Q_cycle = 700 J.

Formula: ΔU_cycle = 0, Q = W.

Solution: Since the gas returns to the initial state, ΔU = 0. Hence W = 700 J.

Final Answer: 700 J.

NCERT-Style Example 8: Isobaric Work

A gas expands at constant pressure 2 × 10⁵ Pa from 3 L to 8 L. Find work.

Show Solution

Given: P = 2 × 10⁵ Pa, ΔV = 5 L = 5 × 10^-3 m³.

Formula: W = PΔV.

Solution: W = 2 × 10⁵ × 5 × 10^-3 = 1000 J.

Final Answer: 1000 J.

NCERT-Style Example 9: Carnot Efficiency

A Carnot engine operates between 500 K and 300 K. Find efficiency.

Show Solution

Given: T_H = 500 K, T_C = 300 K.

Formula: η = 1 - T_C/T_H.

Solution: η = 1 - 300/500 = 0.40.

Final Answer: 40%.

NCERT-Style Example 10: Refrigerator COP

An ideal refrigerator works between 250 K and 300 K. Find COP.

Show Solution

Given: T_C = 250 K, T_H = 300 K.

Formula: COP_R = T_C/(T_H - T_C).

Solution: COP = 250/(300 - 250) = 5.

Final Answer: 5.

NCERT-Style Example 11: Entropy by Heat

A system absorbs 900 J reversibly at 300 K. Find entropy change.

Show Solution

Given: Q_rev = 900 J, T = 300 K.

Formula: ΔS = Q_rev/T.

Solution: ΔS = 900/300 = 3 J K^-1.

Final Answer: 3 J K^-1.

NCERT-Style Example 12: Hot to Cold Entropy

100 J heat flows from 400 K to 300 K. Find total entropy change.

Show Solution

Given: Q = 100 J, T_H = 400 K, T_C = 300 K.

Formula: ΔS = -Q/T_H + Q/T_C.

Solution: ΔS = -100/400 + 100/300 = -0.25 + 0.333 = 0.083 J K^-1.

Final Answer: 0.083 J K^-1.

NCERT Exercise-Type Practice

These exercise-type questions are designed in the same spirit as Class 11 textbook practice: direct formula use, sign convention and conceptual interpretation.

NCERT-Style Example 1: Heat Capacity

A 2 kg body with c = 500 J kg^-1 K^-1 is heated by 20 K. Find heat supplied.

Show Solution

Given: m = 2 kg, c = 500 J kg^-1 K^-1, ΔT = 20 K.

Formula: Q = mcΔT.

Solution: Q = 2 × 500 × 20 = 20000 J.

Final Answer: 20000 J.

NCERT-Style Example 2: Constant Pressure Work

A gas expands at constant pressure 10⁵ Pa by 0.02 m³. Find work.

Show Solution

Given: P = 10⁵ Pa, ΔV = 0.02 m³.

Formula: W = PΔV.

Solution: W = 10⁵ × 0.02 = 2000 J.

Final Answer: 2000 J.

NCERT-Style Example 3: First Law

A gas receives 1000 J heat and does 400 J work. Find ΔU.

Show Solution

Given: Q = 1000 J, W = 400 J.

Formula: ΔU = Q - W.

Solution: ΔU = 1000 - 400 = 600 J.

Final Answer: 600 J.

NCERT-Style Example 4: Adiabatic Compression

A gas is compressed adiabatically and 250 J work is done on it. Find ΔU.

Show Solution

Given: Q = 0, W_on = 250 J, so work by gas W = -250 J.

Formula: ΔU = Q - W.

Solution: ΔU = 0 - (-250) = +250 J.

Final Answer: +250 J.

NCERT-Style Example 5: Heat Engine

A cyclic engine absorbs 2000 J and rejects 1200 J. Find work and efficiency.

Show Solution

Given: Q_H = 2000 J, Q_C = 1200 J.

Formula: W = Q_H - Q_C, η = W/Q_H.

Solution: W = 800 J. η = 800/2000 = 0.40.

Final Answer: W = 800 J, η = 40%.

NCERT-Style Example 6: Carnot Efficiency

A Carnot engine works between 600 K and 450 K. Find efficiency.

Show Solution

Given: T_H = 600 K, T_C = 450 K.

Formula: η = 1 - T_C/T_H.

Solution: η = 1 - 450/600 = 0.25.

Final Answer: 25%.

NCERT-Style Example 7: Refrigerator COP

A refrigerator extracts 1800 J using 300 J work. Find COP and heat rejected.

Show Solution

Given: Q_C = 1800 J, W = 300 J.

Formula: COP = Q_C/W, Q_H = Q_C + W.

Solution: COP = 1800/300 = 6. Q_H = 1800 + 300 = 2100 J.

Final Answer: COP = 6, Q_H = 2100 J.

NCERT-Style Example 8: Latent Heat

50 g ice melts at 0°C. L_f = 3.34 × 10⁵ J kg^-1. Find heat.

Show Solution

Given: m = 0.050 kg, L_f = 3.34 × 10⁵ J kg^-1.

Formula: Q = mL.

Solution: Q = 0.050 × 3.34 × 10⁵ = 16700 J.

Final Answer: 16700 J.

NCERT-Style Example 9: Entropy

200 J heat is absorbed reversibly at 400 K. Find ΔS.

Show Solution

Given: Q_rev = 200 J, T = 400 K.

Formula: ΔS = Q_rev/T.

Solution: ΔS = 200/400 = 0.5 J K^-1.

Final Answer: 0.5 J K^-1.

NCERT-Style Example 10: Free Expansion

A gas expands freely into vacuum in an insulated container. What are Q and W?

Show Solution

Given: Insulated container and vacuum expansion.

Formula: Q = 0, W = 0.

Solution: No heat enters and no external pressure is opposed, so no work is done. For an ideal gas, ΔU = 0, but entropy increases.

Final Answer: Q = 0, W = 0; entropy increases.

NCERT-Style Example 11: Isothermal Work

Two moles of ideal gas expand isothermally at 300 K from V to 3V. Find work.

Show Solution

Given: n = 2, T = 300 K, V₂/V₁ = 3.

Formula: W = nRT ln(V₂/V₁).

Solution: W = 2 × 8.314 × 300 × ln3 = 5480 J approximately.

Final Answer: 5.48 × 10³ J.

NCERT-Style Example 12: Isochoric Process

A gas at constant volume is supplied 750 J heat. Find W and ΔU.

Show Solution

Given: Q = 750 J, ΔV = 0.

Formula: W = 0, ΔU = Q - W.

Solution: At constant volume, W = 0. Hence ΔU = 750 J.

Final Answer: W = 0, ΔU = 750 J.

NCERT-Style Example 13: Pressure Law

At constant volume, a gas has pressure 1.5 × 10⁵ Pa at 300 K. Find pressure at 450 K.

Show Solution

Given: P₁ = 1.5 × 10⁵ Pa, T₁ = 300 K, T₂ = 450 K.

Formula: P/T = constant.

Solution: P₂ = P₁T₂/T₁ = 1.5 × 10⁵ × 450/300 = 2.25 × 10⁵ Pa.

Final Answer: 2.25 × 10⁵ Pa.

NCERT-Style Example 14: Charles Law

At constant pressure, a gas volume is 4 L at 300 K. Find volume at 450 K.

Show Solution

Given: V₁ = 4 L, T₁ = 300 K, T₂ = 450 K.

Formula: V/T = constant.

Solution: V₂ = 4 × 450/300 = 6 L.

Final Answer: 6 L.

NCERT-Style Example 15: Mayer Relation

For an ideal gas, C_V = 20.8 J mol^-1 K^-1. Find C_P.

Show Solution

Given: C_V = 20.8 J mol^-1 K^-1, R = 8.314 J mol^-1 K^-1.

Formula: C_P - C_V = R.

Solution: C_P = 20.8 + 8.314 = 29.114 J mol^-1 K^-1.

Final Answer: 29.1 J mol^-1 K^-1.

NCERT-Style Example 16: Monoatomic Internal Energy

Find ΔU for 1 mole monoatomic ideal gas when temperature rises by 40 K.

Show Solution

Given: n = 1, ΔT = 40 K.

Formula: ΔU = (3/2)nRΔT.

Solution: ΔU = 1.5 × 1 × 8.314 × 40 = 498.8 J.

Final Answer: 499 J approximately.

NCERT-Style Example 17: Adiabatic Relation

For reversible adiabatic expansion, P₁V₁^γ = P₂V₂^γ. If volume doubles and γ = 5/3, write pressure ratio P₂/P₁.

Show Solution

Given: V₂ = 2V₁, γ = 5/3.

Formula: P₂/P₁ = (V₁/V₂)^γ.

Solution: P₂/P₁ = (1/2)^5/3.

Final Answer: (1/2)^5/3.

NCERT-Style Example 18: Entropy of Heat Flow

300 J heat flows from 600 K body to 300 K body. Find total entropy change.

Show Solution

Given: Q = 300 J, T_H = 600 K, T_C = 300 K.

Formula: ΔS_total = -Q/T_H + Q/T_C.

Solution: ΔS = -300/600 + 300/300 = -0.5 + 1 = 0.5 J K^-1.

Final Answer: 0.5 J K^-1.

NCERT-Style Example 19: Ideal Heat Pump

An ideal heat pump operates between 280 K and 350 K. Find COP.

Show Solution

Given: T_C = 280 K, T_H = 350 K.

Formula: COP_HP = T_H/(T_H - T_C).

Solution: COP = 350/(350 - 280) = 350/70 = 5.

Final Answer: 5.

NCERT-Style Example 20: Cyclic Graph

A clockwise P-V cycle encloses area 1500 J. Find net work and net heat.

Show Solution

Given: Area enclosed = 1500 J, clockwise cycle.

Formula: W_cycle = area, ΔU_cycle = 0, Q = W.

Solution: Clockwise cycle gives positive work by gas. W = 1500 J and Q = 1500 J.

Final Answer: W = 1500 J, Q = 1500 J.

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PYQ Bank and Multi-Curriculum Questions

Answers are hidden. Attempt each one before opening the answer.

Q1 CBSE PYQ. State the first law of thermodynamics and explain the sign convention for work.

Show Answer

Answer: ΔU = Q - W. Q is positive when heat is supplied to the system. W is positive when work is done by the system during expansion.

Q2 CBSE PYQ. Why is work zero in an isochoric process?

Show Answer

Answer: In an isochoric process volume is constant, so ΔV = 0 and W = ∫P dV = 0.

Q3 CBSE PYQ. What is the physical meaning of area under a P-V graph?

Show Answer

Answer: It gives work done by gas during expansion or compression.

Q4 CBSE PYQ. Why does internal energy of an ideal gas depend only on temperature?

Show Answer

Answer: For ideal gas, intermolecular potential energy is neglected, so internal energy is kinetic and depends only on temperature.

Q5 CBSE PYQ. Write two limitations imposed by the second law.

Show Answer

Answer: Heat cannot be completely converted into work in a cyclic engine; heat cannot flow from cold to hot without work input.

Q6 NEET PYQ. For an ideal gas in isothermal expansion, ΔU is: (A) positive (B) negative (C) zero (D) infinite

Show Answer

Answer: (C) zero.

Q7 NEET PYQ. In an adiabatic process: (A) Q = 0 (B) W = 0 (C) ΔU = 0 (D) P constant

Show Answer

Answer: (A) Q = 0.

Q8 NEET PYQ. A Carnot engine has T_H = 600 K and T_C = 300 K. Efficiency is:

Show Answer

Answer: η = 1 - 300/600 = 50%.

Q9 NEET PYQ. Which process has maximum work for the same volume change between same end volumes in slow expansion? Compare qualitatively.

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Answer: Work is area under P-V curve. The process with higher pressure throughout the expansion gives larger work.

Q10 NEET PYQ. COP of refrigerator can be greater than one because:

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Answer: It measures heat removed per work input; the work transfers heat rather than being directly converted into cooling.

Q11 JEE Main PYQ. One mole ideal gas expands isothermally from V to 2V at temperature T. Find work.

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Answer: W = nRT ln2 = RT ln2.

Q12 JEE Main PYQ. A gas undergoes a cycle and does 500 J work. Find net heat absorbed.

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Answer: For a cycle ΔU = 0, so Q = W = 500 J.

Q13 JEE Main PYQ. If 800 J heat is supplied and work done by gas is 300 J, find internal energy change.

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Answer: ΔU = Q - W = 800 - 300 = 500 J.

Q14 JEE Main PYQ. For reversible adiabatic process, write relation between P and V.

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Answer: PV^γ = constant.

Q15 JEE Main PYQ. A Carnot engine efficiency is 25% and source is at 400 K. Find sink temperature.

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Answer: 0.25 = 1 - T_C/400, so T_C = 300 K.

Q16 JEE Advanced PYQ. A gas goes from A to B by two paths. What determines work difference?

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Answer: Work is path dependent and equals area under P-V path; different paths have different areas.

Q17 JEE Advanced PYQ. For a cyclic process, can heat supplied be nonzero while ΔU is zero?

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Answer: Yes. Since ΔU is state function and cycle returns to initial state, ΔU = 0, but net heat equals net work.

Q18 JEE Advanced PYQ. Why is free expansion not represented by a well-defined path on P-V graph?

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Answer: It is not quasi-static; intermediate states are not equilibrium states with well-defined pressure of the gas against external pressure.

Q19 JEE Advanced PYQ. In adiabatic free expansion of ideal gas, what happens to T and S?

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Answer: For ideal gas, T remains same because Q = W = ΔU = 0; entropy increases due to larger volume.

Q20 JEE Advanced PYQ. Compare reversible and irreversible engines between same reservoirs.

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Answer: Reversible engine has maximum efficiency. Irreversible engine has entropy production and lower efficiency.

Q21 IB Question. Explain why thermal energy transferred at lower temperature produces larger entropy change.

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Answer: ΔS = Q/T; for the same Q, smaller T gives larger entropy change.

Q22 IB Question. A student says entropy is disorder only. Improve the statement.

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Answer: Entropy is a thermodynamic state function measuring energy dispersal; disorder is only a rough analogy.

Q23 IB Question. Why is kelvin scale compulsory in Carnot formula?

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Answer: Carnot formula depends on absolute thermodynamic temperature.

Q24 IGCSE Question. Why does a pressure cooker cook food faster?

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Answer: Pressure cooker raises pressure, increasing boiling point of water, so food cooks at higher temperature.

Q25 IGCSE Question. Why does evaporation cause cooling?

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Answer: Faster molecules escape, taking energy away; remaining liquid has lower average kinetic energy.

Q26 IGCSE Question. What happens to temperature during melting?

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Answer: Temperature remains constant while supplied heat changes phase.

Q27 A-Level Question. For ideal gas, derive C_P - C_V = R in statement form.

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Answer: At constant volume Q = ΔU = nC_VΔT. At constant pressure Q = nC_PΔT = ΔU + PΔV = nC_VΔT + nRΔT, hence C_P - C_V = R.

Q28 A-Level Question. What is entropy change of ideal gas in isothermal expansion V to 4V?

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Answer: ΔS = nR ln(4V/V) = nR ln4.

Q29 A-Level Question. Why is heat not a state function?

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Answer: Heat depends on path of energy transfer, not only initial and final states.

Q30 Assertion-Reason. Assertion: In isothermal process of ideal gas, internal energy remains constant. Reason: Internal energy of ideal gas depends only on temperature.

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Answer: Both true and reason correctly explains assertion.

Q31 Assertion-Reason. Assertion: In cyclic process, ΔU = 0. Reason: Internal energy is a state function.

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Answer: Both true and reason correctly explains assertion.

Q32 Assertion-Reason. Assertion: A refrigerator violates natural heat flow. Reason: It uses external work to transfer heat from cold to hot.

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Answer: Assertion as worded is incomplete; it does not violate second law because work is supplied. Reason is true.

Q33 Assertion-Reason. Assertion: For an irreversible process, ΔS_universe > 0. Reason: Irreversibility produces entropy.

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Answer: Both true and reason correctly explains assertion.

Q34 True/False. Heat and work are path functions.

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Answer: True.

Q35 True/False. Internal energy is a state function.

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Answer: True.

Q36 True/False. For isochoric process, work done by gas is maximum.

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Answer: False. It is zero.

Q37 True/False. Carnot efficiency can be 100% if T_C is 0 K.

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Answer: Mathematically yes, but 0 K cannot be achieved physically, so practical 100% efficiency is impossible.

Q38 True/False. Entropy of a system can decrease.

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Answer: True, but entropy of an isolated system cannot decrease.

Q39 Conceptual. Why does a diesel engine heat air during compression?

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Answer: Rapid compression is approximately adiabatic; work done on air increases internal energy and temperature.

Q40 Conceptual. Why does an air conditioner warm the outside air?

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Answer: It rejects heat removed from the room plus compressor work to the outside.

Q41 Conceptual. Why is a slow frictionless process close to reversible?

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Answer: It remains near equilibrium and avoids dissipative entropy production.

Q42 Conceptual. Can Q be zero and ΔU nonzero?

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Answer: Yes, in adiabatic compression or expansion work changes internal energy while Q = 0.

Q43 Conceptual. Can W be zero and Q nonzero?

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Answer: Yes, in isochoric heating or cooling where all heat changes internal energy.

Q44 Difficult Numerical. A Carnot engine absorbs 1200 J at 600 K and rejects heat at 300 K. Find rejected heat and work.

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Answer: Q_C = Q_HT_C/T_H = 1200 × 300/600 = 600 J. W = 600 J.

Q45 Difficult Numerical. A refrigerator has COP 5 and removes 2500 J. Find work input and heat rejected.

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Answer: W = Q_C/COP = 2500/5 = 500 J. Q_H = 3000 J.

Q46 Difficult Numerical. A gas receives 300 J heat and 100 J work is done on it. Find ΔU.

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Answer: Work done by gas W = -100 J. ΔU = Q - W = 300 - (-100) = 400 J.

Q47 Difficult Numerical. A monoatomic ideal gas, n = 2, changes temperature by 10 K. Find ΔU.

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Answer: ΔU = (3/2)nRΔT = 1.5 × 2 × 8.314 × 10 = 249.4 J.

Q48 Difficult Numerical. 100 J heat flows from 500 K to 250 K. Find total entropy change.

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Answer: ΔS = -100/500 + 100/250 = -0.2 + 0.4 = 0.2 J K^-1.

Case Study 1: Refrigerator

A domestic refrigerator removes heat from the cold chamber and rejects heat to the room. The compressor needs electrical work.

Q49 Case Study - Refrigerator. What is the desired output?

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Answer: Q_C, the heat removed from the cold chamber.

Q50 Case Study - Refrigerator. Why is work needed?

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Answer: Heat is being transferred from cold to hot, against natural direction.

Q51 Case Study - Refrigerator. Write energy balance.

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Answer: Q_H = Q_C + W.

Case Study 2: Heat Engine

A petrol engine absorbs heat from burning fuel, produces shaft work and rejects waste heat to surroundings.

Q52 Case Study - Heat Engine. Why is efficiency below 100%?

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Answer: Some heat must be rejected to the sink.

Q53 Case Study - Heat Engine. What is useful output?

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Answer: Work W.

Q54 Case Study - Heat Engine. Formula for efficiency?

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Answer: η = W/Q_H = 1 - Q_C/Q_H.

Case Study 3: Carnot Engine

An ideal reversible engine operates between a source at T_H and sink at T_C.

Q55 Case Study - Carnot Engine. What is maximum efficiency?

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Answer: η = 1 - T_C/T_H.

Q56 Case Study - Carnot Engine. What temperatures must be used?

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Answer: Kelvin temperatures.

Q57 Case Study - Carnot Engine. Why is it ideal?

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Answer: All processes are reversible and no entropy is produced.

Case Study 4: Entropy

Heat flows naturally from a hot block to a cold block inside an insulated box.

Q58 Case Study - Entropy. What happens to total entropy?

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Answer: It increases.

Q59 Case Study - Entropy. Formula for total entropy change?

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Answer: ΔS = -Q/T_H + Q/T_C.

Q60 Case Study - Entropy. When does heat flow stop?

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Answer: At thermal equilibrium.

Case Study 5: Pressure Cooker

A pressure cooker traps steam and increases pressure above atmospheric pressure.

Q61 Case Study - Pressure Cooker. Why does boiling point rise?

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Answer: Higher pressure requires higher temperature for boiling.

Q62 Case Study - Pressure Cooker. Why food cooks faster?

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Answer: Water and steam are hotter than 100°C.

Q63 Case Study - Pressure Cooker. Is this thermodynamics?

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Answer: Yes, phase change and pressure-temperature relation are involved.

Case Study 6: Diesel Engine

Air is compressed rapidly before fuel injection.

Q64 Case Study - Diesel Engine. Approximate process?

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Answer: Adiabatic compression.

Q65 Case Study - Diesel Engine. What happens to temperature?

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Answer: Temperature rises.

Q66 Case Study - Diesel Engine. Why does fuel ignite?

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Answer: Compressed air becomes hot enough for ignition.

Case Study 7: Air Conditioner

An AC removes heat from the room and rejects heat outdoors.

Q67 Case Study - Air Conditioner. Same principle as what device?

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Answer: Refrigerator.

Q68 Case Study - Air Conditioner. What is work input?

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Answer: Electrical work to compressor.

Q69 Case Study - Air Conditioner. Why outdoor unit is hot?

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Answer: It rejects room heat plus compressor work.

Quick Revision Notes

One-Page Revision Sheet

Heat and Calorimetry

Q = mcΔT for temperature change.
Q = mL for phase change.
Heat lost = heat gained in insulated mixing.
Temperature remains constant during phase change.

Work and Graphs

W = ∫P dV.
Area under P-V graph gives work.
Clockwise cycle gives positive net work.
Isochoric process has W = 0.

First Law

ΔU = Q - W.
Isothermal ideal gas: ΔU = 0.
Adiabatic: Q = 0.
Cyclic: ΔU = 0 and Q = W.

Processes

Isothermal: PV = constant.
Adiabatic: PV^γ = constant.
Isobaric: P constant.
Isochoric: V constant.

Heat Engines

W = Q_H - Q_C.
η = W/Q_H.
Carnot: η = 1 - T_C/T_H.
100% efficiency is impossible in practice.

Entropy

ΔS = Q_rev/T.
For isolated system, ΔS ≥ 0.
Reversible: ΔS_universe = 0.
Irreversible: ΔS_universe > 0.

Most Important Exam Tips

Always convert Celsius to kelvin in ideal gas, Carnot and entropy formulae involving absolute temperature.
Write sign convention at the start if the problem involves work done on gas versus by gas.
For cyclic processes, immediately write ΔU = 0.
For ideal gas isothermal process, immediately write ΔU = 0 and Q = W.
For adiabatic process, immediately write Q = 0.
COP is not efficiency; it can be greater than one.
Entropy is a state function; heat and work are path functions.

Most Common Mistakes

Using litre with pascal without converting to m³.
Using Celsius in η = 1 - T_C/T_H.
Forgetting that W is negative during compression when W is work done by gas.
Using adiabatic formulas for irreversible free expansion.
Confusing heat capacity C with specific heat c.
Opening answer before attempting the question. That one is technically not thermodynamics, but it ruins the score.

Last-Day Revision Order

Revise formula cards in this order: heat, work, first law, processes, Carnot, entropy.
Practice five graph questions and five sign-convention questions.
Revise special cases: isothermal, adiabatic, isochoric, isobaric, cyclic.
Practice Carnot temperature conversion questions.
End with assertion-reason and case-study questions.

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