Add Important Electric Charge Page: 44 NGSS Standards: N/A Electric Charge MA Curriculum Frameworks (006): 5.1, 5.4 AP Physics 1 Learning Objectives: 1.B.1.1, 1.B.1., 1.B..1, 1.B.3.1 Knowledge/Understanding Goals: electric charge properties of electric charges conductors vs. insulators Language Objectives: Understand and correctly use the terms electricity, charge, current, conductor, insulator, and induction. Accurately describe and apply the concepts described in this section using appropriate academic language. Labs, Activities & Demonstrations: Notes: Charged balloon making hairs repel, attracting water molecules. Water sprayed on balloon neutralizes the charge. Wimshurst machine. Van de Graaff generator. electric charge: a physical property of matter which causes it to experience a force when near other electrically charged matter. Electric charge is measured in coulombs (C). positive charge: the type of charge carried by protons. Originally defined as the charge left on a piece of glass when rubbed with silk. The glass becomes positively charged because the silk pulls electrons off the glass. negative charge: the type of charge carried by electrons. Originally defined as the charge left on a piece of amber (or rubber) when rubbed with fur (or wool). The amber becomes negatively charged because the amber pulls the electrons off the fur.
Add Important Electric Charge Page: 45 elementary charge: the magnitude (amount) of charge on one proton or one 19 electron. One elementary charge equals 1.60 10 C. Because ordinary matter is made of protons and electrons, the amount of charge carried by any object must be a multiple of the elementary charge. Note however, that the quarks that protons and neutrons are made of carry fractional charges; up-type quarks carry a charge of +⅔ of an elementary charge, and down-type quarks carry a charge of ⅓ of an elementary charge. A proton is made of two up quarks and one down quark and carries a charge of +1 elementary charge. A neutron is made of one up quark and two down quarks and carries no charge. static electricity: stationary electric charge, such as the charge left on silk or amber in the above definitions. electric current (sometimes called electricity): the movement of electrons through a medium (substance) from one location to another. Note, however, that electric current is defined as the direction a positively charged particle would move. Thus electric current flows in the opposite direction from the actual electrons.
Add Important Electric Charge Page: 46 xkcd.com. Used with permission. Devices that Produce, Use or Store Charge capacitor: a device that stores electric charge. battery: a device that uses chemical reactions to produce an electric current. generator: a device that converts mechanical energy (motion) into an electric current. motor: a device that converts an electric current into mechanical energy.
Add Important Electric Charge Page: 47 Conductors vs. Insulators conductor: a material that allows charges to move freely through it. Examples of conductors include metals and liquids with positive and negative ions dissolved in them (such as salt water). When charges are transferred to a conductor, the charges distribute themselves evenly throughout the substance. insulator: a material that does not allow charges to move freely through it. Examples of insulators include nonmetals and most pure chemical compounds (such as glass or plastic). When charges are transferred to an insulator, they cannot move, and remain where they are placed. Behavior of Charged Particles Like charges repel. A pair of the same type of charge (two positive charges or two negative charges) exert a force that pushes the charges away from each other. Opposite charges attract. A pair of opposite types of charge (a positive charge and a negative charge) exert a force that pulls the charges toward each other. Charge is conserved. Electric charges cannot be created or destroyed, but can be transferred from one location or medium to another. (This is analogous to the laws of conservation of mass and energy.)
Add Important Electric Charge Page: 48 Charging by Induction induction: when an electrical charge on one object causes a charge in a second object. When a charged rod is brought near a neutral object, the charge on the rod attracts opposite charges and repels like charges that are near it. The diagram below shows a negatively-charged rod repelling negative charges. If the negatively-charged rod above were touched to the sphere, some of the charges from the rod would be transferred to the sphere at the point of contact, and the sphere would acquire an overall negative charge.
Add Important Electric Charge Page: 49 A process for inducing charges in a pair of metal spheres is shown below: (a) Metal spheres A and B are brought into contact. (b) A positively charged object is placed near (but not in contact with) sphere A. This induces a negative charge in sphere A, which in turn induces a positive charge in sphere B. (c) Sphere B (which is now positively charged) is moved away. (d) The positively charged object is removed. (e) The charges distribute themselves throughout the metal spheres. AP questions dealing with charging by induction are common, so you should be sure to understand how and why every step of this procedure works.
Add Important Electric Charge Page: 430 Grounding For the purposes of our use of electric charges, the ground (Earth) is effectively an endless supply of both positive and negative charges. Under normal circumstances, if a charged object is touched to the ground, electrons will move to neutralize the charge, either by flowing from the object to the ground or from the ground to the object. Grounding a charged object or circuit means neutralizing the electrical charge on an object or portion of the circuit. The charge of any object that is connected to ground is zero, by definition. In buildings, the metal pipes that bring water into the building are often used to ground the electrical circuits. The metal pipe is a good conductor of electricity, and carries the unwanted charge out of the building and into the ground outside.
Add Important Coulomb s Law Page: 431 NGSS Standards: HS-PS-4, HS-PS3-5 Coulomb s Law MA Curriculum Frameworks (006): 5.4 AP Physics 1 Learning Objectives: 3.C..1, 3.C.,, 5.A..1 Skills: understand & solve problems using Coulomb s Law Language Objectives: Accurately describe Coulomb s Law using appropriate academic language. Set up and solve word problems relating to Coulomb s Law. Labs, Activities & Demonstrations: Notes: Van de Graaff generator with inertia balance pan. Charged balloon or Styrofoam sticking to wall. Charged balloon pushing meter stick. Electric charge is measured in Coulombs (abbreviation C ). One Coulomb is the amount of electric charge transferred by a current of 1 ampere for a duration of 1 second. 1 C is the charge of 6.415 10 18 protons. 1 C is the charge of 6.415 10 18 electrons. One proton or electron (elementary charge) therefore has a charge of 1.60 10 19 C.
Add Important Coulomb s Law Page: 43 Because charged particles exert a force on each other, that force can be measured and quantified. The force is directly proportional to the strengths of the charges and inversely proportional to the square of the distance. The formula is therefore: where: kq q F e r 1 F e = electrostatic force of repulsion between electric charges. A positive value of F e denotes that the charges are repelling (pushing away from) each other; a negative value of F e denotes that the charges are attracting (pulling towards) each other. k = electrostatic constant = 8.9876 10 Nm 9.0 10 Nm q 1 and q = charges 1 and respectively r = distance (radius, because it goes outward in every direction) between the centers of the two charges This formula is Coulomb s Law, named for its discoverer, the French physicist Charles-Augustin de Coulomb. 9 C 9 C
Add Important Coulomb s Law Page: 433 Sample problem: Q: Find the force of electrostatic attraction between the proton and electron in a hydrogen atom if the radius of the atom is 37.1 pm A: The charge of a single proton is 1.60 10 19 C, and the charge of a single electron is 1.60 10 19 C. 37.1pm 3.71 10 F F F e e e kq q d 1 (9.0 10 9 1.67 10 )(1.60 10 7 (3.71 10 N 11 m 19 )( 1.60 10 11 The value of the force is negative, which signifies that the force is attractive. Homework Problems ) 19 1. What is the magnitude of the electric force between two objects, each 6 with a charge of.00 10 C, which are separated by a distance of 1.50 m? Is the force attractive or repulsive? ) Answer: 0.016 N, repulsive
Add Important Coulomb s Law Page: 434. An object with a charge of 1.50 10 C is separated from a second object with an unknown charge by a distance of 0.500 m. If the objects 6 attract each other with a force of 1.35 10 N, what is the charge on the second object? Answer:.50 10 3 C 3. An object with a charge of q1 is separated from a second object with an unknown charge by a distance d. If the objects attract each other with a force F, what is the charge on the second object? Answer: q Fd kq 1 4. The distance between an alpha particle and an electron is.00 10 m. What is the force of electrostatic attraction between the charges? 5 Answer: 1.15 10 N
Add Important Coulomb s Law Page: 435 5. Three elementary charges, particle q 1 with a charge of 6.00 10 C, particle q with a charge of of 5.00 10 9.00 10 9 9 C, and particle q 3 with a charge C, are arranged as shown in the diagram below. What is the net force (magnitude and direction) on particle q 3? Answer: 9 7.16 10 N at an angle of 65. above the x-axis.