Conductors and Insulators | Physics | Khan Academy

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8 Aug 201413:33

Summary

TLDRThis script delves into the fundamental concepts of insulators and conductors in electrical materials, explaining their atomic structures and how electrons behave within them. It highlights the free movement of electrons in conductors versus their restricted movement in insulators, and how these materials respond to applied electric fields or charges. The script also illustrates charging methods, including direct contact and induction, using everyday examples like balloons and metal rods, and emphasizes the polarization ability of insulators to create temporary attractions.

Takeaways

🌌 All materials in the universe can be categorized into insulators, conductors, semiconductors, and superconductors, but for basic physics, distinguishing between insulators and conductors is often sufficient.
🔬 Both insulators and conductors are made up of atoms and molecules with positively charged nuclei and negatively charged electrons.
🏠 In solids, the positively charged nucleus of atoms in both insulators and conductors is essentially immobile, only able to vibrate in place.
🔋 Conductors have electrons that can move freely with minimal resistance, which is the key difference from insulators where electrons are not free to move.
🚫 Insulators' electrons are confined and cannot jump freely from atom to atom, limiting the flow of electrical charge.
🌀 Even though insulators do not allow free electron movement, they can still polarize under an electric field, creating an electrical effect.
🔌 When extra charge is added to insulators, it remains static and can be uniformly distributed or concentrated on one side.
🌐 In contrast, conductors repel extra charge to the outer edges, and any excess charge can move to the surface, distributing evenly or concentrating depending on the shape.
🛠 Common insulators include glass, wood, and most plastics, while metals like copper, gold, and silver are typical conductors.
🤝 When two conducting rods touch, charge redistribution occurs, spreading the charge to maximize distance between like charges.
🌐 Charge by induction involves bringing a charged object near an uncharged conductor, causing a redistribution of charges within the conductor, and can even lead to charging the conductor by grounding it and cutting the connection to the ground.
🎈 The example of a balloon sticking to a ceiling demonstrates how insulators can still interact electrically through polarization, even though electrons do not transfer between the materials.

Q & A

What are the three main categories of materials in terms of electrical properties?
-The three main categories of materials in terms of electrical properties are insulators, electrical conductors, and semiconductors. Additionally, superconductors and other exotic forms of electrical materials exist, but they are often not considered in introductory physics classes.
What is a common characteristic of both insulators and conductors?
-Both insulators and conductors are composed of a large number of atoms and molecules, which in turn consist of a positively charged nucleus surrounded by negatively charged electrons.
Why can't the positively charged nucleus move freely in a solid insulator or conductor?
-The positively charged nucleus cannot move freely in a solid insulator or conductor because it is fixed in place. It can only wiggle or jiggle due to thermal vibrations but cannot travel throughout the material.
How do electrons behave differently in conductors compared to insulators?
-In conductors, electrons can move about relatively freely with almost no resistance, allowing for the flow of electricity. In contrast, in insulators, electrons do not have the right energy levels and bands to move around freely and are essentially stuck, unable to jump from atom to atom.
What happens when an insulator is connected to a battery or subjected to an electric field?
-When an insulator is connected to a battery or subjected to an electric field, the electrons cannot jump from atom to atom. However, the nucleus and the cloud of electrons can shift, causing one side of the atom to become more negative and the other side more positive, leading to an overall electrical effect where the insulator can interact with nearby charges.
What is the effect of adding extra charge to an insulator?
-When extra charge is added to an insulator, the charges cannot flow through the material and become stuck. They can be distributed uniformly throughout the insulator or concentrated on one side, but they do not move freely.
How do charges behave when added to a conductor?
-When extra charges are added to a conductor, they repel each other due to their like charge and move to the outside edge of the conductor. Charges can only be added to the outside edge of a conductor, as any internal charges will quickly redistribute to the edge.
What physical materials are considered insulators?
-Physical materials that are considered insulators include glass, wood, and most plastics. These materials do not allow charges to flow through them and can hold charge on their surface.
What are some examples of conductors?
-Examples of conductors include metals such as gold, copper, and silver. These materials allow charges to flow freely through them.
How can charge be transferred between two conducting rods?
-Charge can be transferred between two conducting rods by touching them together. The charges will spread out to maximize the distance between them, resulting in a sharing of the charge between the rods based on their size.
What is charge by induction, and how does it work?
-Charge by induction is a method of charging an object without direct contact. It involves bringing a charged object near an uncharged conductor and then grounding the conductor, causing electrons to move or leave the conductor, thus inducing a charge. If the grounding is maintained, the conductor remains charged even after the charged object is removed.
How can a balloon stick to a wall or ceiling?
-A balloon can stick to a wall or ceiling due to the insulating material's ability to polarize. When the negatively charged balloon is brought near an insulating surface, the atoms in the surface can reorient, creating a net force that attracts the balloon, allowing it to stick.