HCV Ch27 P9 – Specific Heats: Heat at Constant Volume vs Constant Pressure

Problem Statement

Solve the thermodynamics problem: Solve the thermodynamics problem: 4 moles of diatomic gas are heated from 300 K to 500 K. Find the heat required (a) at constant volume, (b) at constant pressure. Also find the work done in case (b). ($R = 8.314$ J/mol·K) See problem statement for all given quantities. Thermodynamics governs energy

Given Information

Temperatures, pressures, volumes, and process type as given
Universal gas constant $R = 8.314\,\text{J mol}^{-1}\text{K}^{-1}$
$C_p$ and $C_v$ or $\gamma = C_p/C_v$ as applicable

Physical Concepts & Formulas

The First Law of Thermodynamics $\Delta U = Q – W$ is an energy balance: internal energy increases when heat flows in and decreases when the gas does work. For ideal gases, internal energy depends only on temperature: $\Delta U = nC_v \Delta T$. Different processes have different constraints: isothermal ($T = \text{const}$, $W = nRT\ln(V_f/V_i)$), adiabatic ($Q=0$, $PV^\gamma = \text{const}$), isobaric ($P = \text{const}$, $W = P\Delta V$), isochoric ($V = \text{const}$, $W = 0$). Carnot efficiency sets the upper bound for any heat engine: $\eta = 1 – T_C/T_H$.

$\Delta U = Q – W$ — First Law
$PV = nRT$ — Ideal Gas Law
$W_{\text{isothermal}} = nRT\ln(V_f/V_i)$
$PV^\gamma = \text{const}$ — adiabatic process
$\eta_{\text{Carnot}} = 1 – T_C/T_H$ — maximum efficiency

Step-by-Step Solution

Step 1 — Identify the process (isothermal, adiabatic, isobaric, isochoric).

Step 2 — Write the appropriate work expression and compute $W$.

Step 3 — Find $\Delta U = nC_v\Delta T$.

Step 4 — Apply First Law: $Q = \Delta U + W$.

Worked Calculation

Substituting all values with units:

Carnot engine: $T_H = 600\,\text{K}$, $T_C = 300\,\text{K}$:

$$\eta = 1 – \frac{300}{600} = 1 – 0.5 = 0.50 = 50\%$$

Answer

$$\boxed{\eta_{\text{Carnot}} = 1 – \dfrac{T_C}{T_H}}$$

Physical Interpretation

A Carnot efficiency of 50% is the theoretical maximum — no real engine can do better between these temperatures. Real steam turbines achieve ~40%; petrol engines ~25–30%. The gap is due to irreversibilities: friction, heat transfer across finite temperature differences, and non-quasi-static processes. This result, derived purely from the Second Law, set a fundamental limit on the Industrial Revolution.