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PowerPoint Lectures to accompany Physical Science, 8e Chapter 6 Electricity Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Core Concept Electric and magnetic fields interact and can produce forces. Concepts of Electricity • Electron theory of charge – Ancient mystery: “Amber effect” – J. J. Thompson: identified negatively charged electrons • Today: – Basic unit of matter = atom – Atoms made up of electrons and nuclei containing positively charged protons and neutral neutrons (See Ch. 8) Electric Charge • Charges in matter – Inseparable property of certain particles – Electrons: negative electric charge – Protons: positive electric charge • Charge interaction – Electric force – “Like charges repel; unlike charges attract” • Ions: non-zero net charge from loss/gain of electrons Static Electricity • Electrostatic charge – Stationary charge confined to an object • Charging mechanisms – Friction – Contact with a charged object – Polarization (reorientation induced without changing net charge) Electrical Conductors and Insulators • Electrical conductors – Electrons are free to move throughout material – Added charge dissipates – Examples: metals, graphite (carbon) • Electrical insulators – Electron motions restricted – Added charge tends to remain on object – Examples: Glass, wood, diamond (carbon) • Semiconductors – Conduct/insulate depending on circumstances – Applications: Computer chips, solar cells, ... Electric Charge • Unit of charge = coulomb (C) – Equivalent to charge of 6.24x1018 electrons! – Metric unit of charge • Electron charge – Fundamental charge – Smallest seen in nature – Quantity of charge and the number of electrons Electrostatic Forces Coulomb’s law • Relationship giving force between two charges • Similar to Newton’s law of gravitation • k versus G implies gravity weaker Force Fields How do forces act through space? • Charges surrounded by electric fields (Vector fields/directional) • Fields and charges inseparable • Fields act on other charges – Direction of fields = motion of positive test charge in the field – Visualized with lines of force • Same ideas apply to gravity and magnetism Force Fields How do forces act through space? • Charges surrounded by electric fields (Vector fields/directional) • Fields and charges inseparable • Fields act on other charges – Direction of fields = motion of positive test charge in the field – Visualized with lines of force • Same ideas apply to gravity and magnetism Electric Potential • Scalar field associated with potential energy • Units = volts (V) • Related to work involved in positioning charges • Potential difference important in producing forces and moving charges • Analogous to moving masses in gravitational fields Electric Current Earlier - electrostatics • Charges more or less fixed in place Now - charge allowed to move • Electric current – Flow of charge – Reason for charge flow - potential (voltage) differences • Electric circuits – Structures designed to localize and utilize currents The Electric Circuit Structure • Voltage source – Energy input – Necessary for continuing flow • Circuit elements – Energy used up as heat, light, work, … • Current flow convention: from high potential to low potential through the external circuit • Water/pump analogy The Nature of Current • Historically - nature of “electrical fluid” unknown • Current thought to be a flow of positive charge • Reality - more complicated, depending on material • Opposite correct in metals, current = electron flow Current Mechanisms Liquids and gases • Both positive and negative charges move, in opposite directions Metals • Delocalized electrons free to move throughout metal • “Electron gas” • Drift velocity of electrons slow • Electric field moves through at nearly light speed More Current Details • Current = charge per unit time • Units = ampere, amps (A) • Direct current (DC) – Charges move in one direction – Electronic devices, batteries, solar cells • Alternating current (AC) – Charge motion oscillatory – No net current flow Electrical Resistance • Loss of electron current energy • Two sources – Collisions with other electrons in current – Collisions with other charges in material • Ohm’s law More on Resistance • Resistance factors – – – – Type of material Length Cross-sectional area Temperature • Superconductors – Negligible resistance at very low temperatures Electrical Power and Work Three circuit elements contribute to work Power in circuits • Voltage source • Electrical device • Conducting wires – Maintain potential difference across device – Input wire at higher potential than output wire – Output wire = "ground" for AC circuits – No potential difference, no current (bird on a wire) Electric bills Magnetism Earliest ideas • Associated with naturally occurring magnetic materials (lodestone, magnetite) • Characterized by “poles” - “north seeking” and “south seeking” • Other magnetic materials - iron, cobalt, nickel (ferromagnetic) Modern view • Associated with magnetic fields • Field lines go from north to south poles Magnetic Poles and Fields • Magnetic fields and poles inseparable • Poles always come in north/south pairs • Field lines go from north pole to south pole • Like magnetic poles repel; unlike poles attract Sources of Magnetic Fields • Microscopic fields – Intrinsic spins of subatomic particles (electrons, protons, …) – Orbital motions of electrons in atoms • Macroscopic fields – – – – Permanent magnets Earth’s magnetic field Electric currents Electromagnets Permanent Magnets • Ferromagnetic materials • Atomic magnetic moment – Electron/proton intrinsic moments – Electron orbital motion • Clusters of atomic moments align in domains • Not magnetized - domains randomly oriented • Magnetized - domains aligned Earth’s Magnetic Field • Originates deep beneath the surface from currents in molten core • Magnetic “north” pole = south pole of Earth’s magnetic field • Magnetic declination = offset • Direction of field periodically reverses – Deposits of magnetized material – Last reversal - 780,000 yrs. ago Electric Currents and Magnetism • Moving charges (currents) produce magnetic fields Electric Currents and Magnetism • Shape of field determined by geometry of current – Straight wire – Current loops – Solenoid Electromagnets • Structure – Ferromagnetic core – Current carrying wire wrapped around core • Field enhanced by the combination • Can be turned on/off • Used in many applications: meters, switches, speakers, motors… Electric Meters • Instrument for measuring current (ammeter) • Uses magnetic field produced by the current • Magnetic field and, hence, deflection proportional to current • Modified, can measure – Potential (voltmeter) – Resistance (ohmmeter) Electromagnetic Switches Relays • Use low voltage control currents to switch larger, high voltage currents on/off • Mercury switch/thermostat Solenoid switches • Moveable spring-loaded iron core responds to solenoid field • Water valves, auto starters, VCR switches, activation of bells and buzzers Telephones and Loudspeakers Coupling Acoustic Waves to Electric Currents Telephone • Sound vibrates carbon granules changing resistance • Changing resistance varies current Speaker • Varying current changes field of electromagnet, moving permanent magnet • Moving magnet vibrates spring attached to paper cone producing sound Electric Motors • Convert electrical energy to mechanical energy • Two working parts – Field magnet - stationary – Armature - moveable electromagnet • Armature rotates by interactions with field magnet – Commutator and brushes reverse current to maintain rotation Electromagnetic Induction Causes: • • Relative motion between magnetic fields and conductors Changing magnetic fields near conductors Effect: • Induced voltages and currents Induced voltage depends on: • • • Number of loops Strength of magnetic field Rate of magnetic field change Generators Structure • Axle with main wire loops in a magnetic field • Axle turned mechanically to produce electrical energy AC generator • “Alternating current” • Sign of current and voltage alternate DC generator • “Direct current” • Sign of current and voltage constant Transformers • Problems in power transmission – High currents - large resistive losses – High voltages - dangerous potential differences • Solution: transformers boost/lower AC currents and voltages • Basic relationships – Power in = power out – Number of coils to voltage Circuit Connections • Alternating current – Practically all generated electricity – Transmitted over high voltage lines and stepped down for use in homes and industry • Direct current – Used in automobiles, cell phones, mp3 players, laptops, … – Moveable and portable applications – Main current source is chemical batteries Voltage Sources in Circuits • Series circuit – Negative terminal of one cell connected to positive terminal of another cell – Total voltage is the sum of single cell voltages – Single current pathway Voltage Sources in Circuits • Parallel circuit – All negative terminals connected; all positive terminals connected – Resultant voltage determined by the largest cell voltage – Makes greater electrical energy available Resistances in Circuits • Series connection Rtotal R1 R2 R3 ... – Total resistance is the sum of all components – Current drops as more elements are added Resistances in Circuits • Parallel connection 1 1 1 1 ... Rtotal R1 R2 R3 – More than one current path available – Overall resistance drops as more elements are added – Total circuit current increases as more elements are added Household Circuits • Combination series and parallel circuit – Light fixtures in a room in parallel • Appliances in parallel – Same voltage available to each – Circuit breakers and fuses prevent overloads Household Circuit Safety • Potential difference from two wires per device – Energized load carrier – Grounded or neutral wire • Three-pronged plug – Provides another grounding wire • Other devices: polarized plugs, groundfault interrupter (GFI)