In Physics, a closed system refers to a physical system that does not allow the transfer of matter outside the system, but does allow the transfer of energy in the form of work or heat. This means that the total mass of the system remains constant over time, but the system can exchange energy with its surroundings.
Key Concepts:
Conservation of Mass: In a closed system, the total mass remains constant, meaning that no mass is lost or gained from the system.
Energy Transfer: While matter cannot enter or leave a closed system, energy in the form of work or heat can be transferred into or out of the system.
Thermodynamic Processes: Closed systems are often used to analyze thermodynamic processes, such as heat engines and refrigerators, where energy transfer occurs without the transfer of matter.
A sealed thermos flask, where heat can enter or leave the system, but no matter can enter or leave.
A piston-cylinder arrangement in a heat engine, where the working substance is contained within the cylinder and no mass is exchanged with the surroundings.
An insulated container, where heat can be exchanged through the walls, but no matter can enter or leave the container.
Study Guide:
If you're studying closed systems in Physics, here are some key points to focus on:
Understand the concept of a closed system and how it differs from open and isolated systems.
Explore the transfer of energy in the form of work and heat in closed systems, and how it impacts the system's behavior.
Practice solving problems involving closed systems, such as analyzing the energy transfers in thermodynamic processes.
Consider real-world applications of closed systems, such as heat exchangers, refrigeration systems, and insulated containers.
Understanding closed systems is essential for understanding various physical processes and the behavior of systems that exchange energy with their surroundings without exchanging matter. By mastering this topic, you can gain a deeper understanding of thermodynamics and energy transfer in the physical world.
[Closed Systems] Related Worksheets and Study Guides:
Create a computational model to calculate the change in the energy of one component in a system when the change in energy of the other component(s) and energy flows in and out of the system are known.
Develop and use models to illustrate that energy at the macroscopic scale can be accounted for as either motions of particles or energy stored in fields.