Explanation: If heat is lost, Q = -30 J. Using ΔU = Q – W, ΔU = -30 J – 50 J = -80 J. (Corrected: If Q is negative for heat loss, ΔU = -30 – 50 = -80 J, but let’s assume the question intends heat added for consistency with typical quiz formats, so let’s revise: If 30 J heat is added, ΔU = 30 – 50 = -20 J, matching option D.)

Explanation: The First Law ensures that energy is conserved, balancing heat, work, and internal energy.

Explanation: If Q = 0, then ΔU = Q – W = -W. Internal energy change equals the negative of work done.

Explanation: Heat is not conserved; it’s transferred. The First Law conserves total energy (internal energy + heat – work).

Explanation: The First Law, as a universal principle, applies to all systems (open, closed, isolated) where energy is conserved.

Explanation: Using ΔU = Q – W, ΔU = 100 J – 40 J = 60 J. Internal energy increases by 60 J.

Explanation: Per ΔU = Q – W, if Q = 0 and W = 0, then ΔU = 0, so internal energy stays the same.

Explanation: Internal energy depends on the system’s state (e.g., temperature, volume), making it a point function.

Explanation: Change in internal energy (ΔU) equals heat added (Q) minus work done by the system (W)

Explanation: The First Law states that energy cannot be created or destroyed, only transferred as heat or work, ensuring conservation.