Problem 22
Question
In a thermodynamic study, a scientist focuses on the properties of a solution in an apparatus as illustrated. A solution is continuously flowing into the apparatus at the top and out at the bottom, such that the amount of solution in the apparatus is constant with time. (a) Is the solution in the apparatus a closed system, open system, or isolated system? (b) If the inlet and outlet were closed, what type of system would it be?
Step-by-Step Solution
Verified Answer
(a) The solution in the apparatus is an \(open\) system since it can exchange both matter and energy with its surroundings. (b) If the inlet and outlet were closed, the system would become a \(closed\) system as it can still potentially exchange energy with its surroundings, but not matter.
1Step 1: Definition of Closed, Open, and Isolated Systems
In thermodynamics, there are three types of systems based on the exchange of matter and energy with their surroundings:
1. Closed system: A system that can exchange energy, but not matter, with its surroundings.
2. Open system: A system that can exchange both matter and energy with its surroundings.
3. Isolated system: A system that cannot exchange either matter or energy with its surroundings.
2Step 2: Identify the Type of System in the Apparatus (a)
In the given system, a solution is continuously flowing into the apparatus at the top and out at the bottom. This implies that there is an exchange of matter happening between the system and its surroundings. Since matter is being exchanged, it cannot be a closed or isolated system. Therefore, the solution in the apparatus is an open system.
3Step 3: Identify the Type of System If Inlet and Outlet Were Closed (b)
If the inlet and outlet were closed, the solution would no longer flow into or out of the apparatus. This means that the exchange of matter between the system and its surroundings is stopped. However, there is no information that suggests that the exchange of energy is stopped as well. So, if the inlet and outlet were closed, the system would become a closed system as it can still potentially exchange energy with its surroundings.
Key Concepts
Open SystemClosed SystemIsolated System
Open System
In thermodynamics, an open system is a type that can exchange both matter and energy with its surroundings. Imagine a pot of water on a stove, with the lid off. The water can evaporate into the air, and heat from the stove moves into the pot. This demonstrates how both matter (water vapor) and energy (heat) can move in and out of the system.
Open systems are common in daily life since many systems exchange both matter and energy to perform processes.
- **Matter Exchange:** The ongoing exchange of substances, like how the solution in the exercise flows in and out of the apparatus.
- **Energy Exchange:** It can absorb or release heat or work with its environment.
Open systems are common in daily life since many systems exchange both matter and energy to perform processes.
Closed System
A closed system in thermodynamics is able to exchange energy but not matter with its surroundings. Picture a sealed pot on a stove, this setup allows heat to pass through but prevents the contents from escaping. This means the pot can change temperature as it gains or loses heat, even though the mass inside remains constant.
Closed systems often appear in experiments when isolating specific reactions or processes, ensuring mass stays constant while energy changes occur.
- **No Matter Exchange:** The sealed environment keeps all substances inside, just like when you close the inlet and outlet of the apparatus in the original exercise.
- **Energy Exchange:** Heat or work can cross the boundary even though no physical material can.
Closed systems often appear in experiments when isolating specific reactions or processes, ensuring mass stays constant while energy changes occur.
Isolated System
An isolated system does not exchange either matter or energy with its surroundings. It is completely self-contained. Think of a thermos flask filled with hot soup. Ideally, the soup remains hot for a long time as it's neither losing heat to the surroundings nor gaining heat from them, and no matter leaks in or out.
Although true isolated systems are theoretical—since absolute isolation is difficult to achieve in practice—they provide a useful model for understanding thermodynamic laws.
- **No Matter Exchange:** The boundary is perfectly sealed against material movement.
- **No Energy Exchange:** Heat or work cannot penetrate, making it insulated to energy transfers.
Although true isolated systems are theoretical—since absolute isolation is difficult to achieve in practice—they provide a useful model for understanding thermodynamic laws.
Other exercises in this chapter
Problem 20
Identify the force present and explain whether work is done when (a) a positively charged particle moves in a circle at a fixed distance from a negatively charg
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(a) Which of the following cannot leave or enter a closed system: heat, work, or matter? (b) Which cannot leave or enter an isolated system? (c) What do we call
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(a) According to the first law of thermodynamics, what quantity is conserved? (b) What is meant by the internal energy of a system? (c) By what means can the in
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(a) Write an equation that expresses the first law of thermodynamics in terms of heat and work. (b) Under what conditions will the quantities q and w be negativ
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