THERMAL BYU 8

We have two calorimeters A and B with equal amounts of water ($300 \text{ g}$ each).

• Initial Temperature of A ($T_A$) = $48^\circ\text{C}$
• Initial Temperature of B ($T_B$) = $80^\circ\text{C}$
• Initial difference $\Delta T = 80 – 48 = 32^\circ\text{C}$

Step 1 (A $\to$ B): Transfer $100 \text{ g}$ from A ($48^\circ\text{C}$) to B ($300 \text{ g}$, $80^\circ\text{C}$). B will now have $400 \text{ g}$. The new temperature of B ($T’_B$) is the weighted average:

$$ T’_B = \frac{1(48) + 3(80)}{4} = \frac{288}{4} = 72^\circ\text{C} $$

A has $200 \text{ g}$ at $48^\circ\text{C}$. B has $400 \text{ g}$ at $72^\circ\text{C}$.

Step 2 (B $\to$ A): Transfer $100 \text{ g}$ from B ($72^\circ\text{C}$) back to A ($200 \text{ g}$, $48^\circ\text{C}$). A returns to $300 \text{ g}$. The new temperature of A ($T’_A$) is:

$$ T’_A = \frac{1(72) + 2(48)}{3} = \frac{168}{3} = 56^\circ\text{C} $$

Result after Cycle 1: $T_A = 56^\circ\text{C}$, $T_B = 72^\circ\text{C}$.
New Difference $\Delta T_1 = 72 – 56 = 16^\circ\text{C}$.
Notice that the difference reduced from $32$ to $16$. It halved.

Since the masses and transfer amounts are constant, the reduction factor for the temperature difference is constant per cycle. In each complete cycle, the temperature difference is reduced by half.

Sequence of temperature differences ($\Delta T$):

• Start: $32^\circ\text{C}$
• Cycle 1: $16^\circ\text{C}$
• Cycle 2: $8^\circ\text{C}$
• Cycle 3: $4^\circ\text{C}$
• Cycle 4: $2^\circ\text{C}$
• Cycle 5: $1^\circ\text{C}$