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-Electric Current -Resistance -Factors that affect resistance -Microscopic View of Current AP Physics C Mrs. Coyle
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Remember: Electric Potential Energy Difference-Two Unlike Charges Higher Potential Energy Lower Potential Energy + - To cause movement of a charge, there must be a potential difference.
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Microscopic View of Current: While the switch is open: Free electrons (conducting electrons) are always moving in random motion. The random speeds are at an order of 10 6 m/s. The sharp changes in direction are due to collisions There is no net movement of charge across a cross section of a wire.
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http://hyperphysics.phy-astr.gsu.edu/HBASE/electric/imgele/micohm.gif What occurs in a wire when the circuit switch is closed?
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An electric field is established instantaneously (at almost the speed of light, 3x10 8 m/s). Free electrons, while still randomly moving, immediately begin drifting due to the electric field, resulting in a net flow of charge. Average drift velocity is about 0.01cm/s.
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Question: If the drift velocity is about 0.01cm/s, why do the lights turn on instantaneously when the circuit switch is closed? What is required in order to have an electric current flow in a circuit?
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Closing the switch establishes a potential difference (voltage) and an electric field in the circuit. Electrons flow in a net direction away from the (-) terminal. High Potential Low Potential
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http://media-2.web.britannica.com/eb-media/36/236-004-D4AA985F.gif Conventional current has the direction that the (+) charges would have in the circuit.
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Voltaic Cell (chemical cell, battery) Alessandro Volta (1800’s) Battery: device that converts chemical energy to electricity. A battery provides a potential energy difference (voltage source).
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Cu and Zinc Electrodes. Why?
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Question: Why is the bird on the wire safe? Question: Why do electricians work with one hand behind their back?
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Question: Why is the ground prong longer than the other two in a plug? Question: Why is there a third rail for the subway?
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Electric Current Electric current is the rate of flow of charge through a cross sectional area The SI unit of current is the ampere (A) 1 A = 1 C / s The symbol for electric current is I
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Average Electric Current ΔQ is the amount of charge that passes through A in time Δt Assume charges are moving perpendicular to a surface of area A Instantaneous Electric Current
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Direct Current DC Provided by batteries Alternating Current AC Provided by power companies
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A Battery Provides Energy Electric Circuit The battery “pumps” positive charges from low (-) to high (+) potential.
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Resistors use up Energy Electric Circuit When the current goes through the resistor it goes to a lower potential.
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Charge Carrier Density, n: number of charge carriers per unit volume Charged particles (current carriers)move through a conductor of cross-sectional area A Volume = A Δx Total number of charge carriers= n A Δx
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Current in terms of Drift Speed I av = ΔQ/Δt = nqv d A or for a charge of an electron: I av =nev d A Derivation: ΔQ = (nA Δx)q Drift speed, v d, is the speed at which the carriers move: v d = Δx / Δt ΔQ = (nAv d Δt)q
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Resistance, R Resistance of an object to the flow of electrical current. Resistance in a circuit is due to collisions between the electrons carrying the current with the fixed atoms inside the conductor R= V / I Resistance equals the ratio of voltage to current. Unit: Ohm (Ω)
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Ohm’s Law (Georg Ohm, 1787-1854) V = IR The voltage, V, across a resistor is proportional to the current, I, that flows through it. In general, resistance does not depend on the voltage. (but for non-Ohmic resistors it may.) Applies to a given resistor or equivalent combination. The voltage is the potential difference across the resistor or equivalent combination.
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Resistor An object that has a given resistance.
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Ohmic Resistor A device that obeys Ohm’s Law, who’s resistance does not depend on the voltage. Most metals obey Ohm’s law The relationship between current and voltage is linear
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Nonohmic Material, Graph Nonohmic materials are those whose resistance changes with voltage or current The current-voltage relationship is nonlinear
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Resistance Depends on material, size and shape, temp. R=ρ L A ρ: resistivity -Resistivity has SI units of ohm-meters (Ω. M -An ideal conductor would have zero resistivity σ: 1/ρ conductivity
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Which has the greatest and least resistance? Ans: Greatest-D, Smallest-B
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Temperature Dependence of Resistance and Resistivity for metals R= R o (1 +α T) R o : reference resistance usually at 20 o C (sometimes at 0 o C) α: temperature coefficient of resistivity Resistivity = o (1 +α T)
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Resistivity and Temperature = o (1 +α T) For metals, the resistivity is nearly proportional to temperature Nonlinear region at very low temperatures Resistivity reaches a finite value (residual resistivity) as the temperature approaches absolute zero
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Semiconductors = o (1 +α T), a<0 For semiconductors there is a decrease in resistivity with an increase in temperature α is negative
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Superconductors For superconductors resistances fall to close to zero below a critical temperature T C The graph is the same as a normal metal above T C, but suddenly drops to zero at T C
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Current Density, J: current per unit area J = I / A A current density J and an electric field E are established in a conductor, when a potential difference is applied across the conductor The current density is a vector in the direction of the positive charge carriers
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Current Density, J: current per unit area J = I / A = nqv d A /A J=nqv d J units: A/m 2 This expression is valid only if the current density is uniform and A is perpendicular to the direction of the current
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Ohm’s Law in terms of Conductivity J = σ E Ohm’s law states that for many materials, the ratio of the current density to the electric field is a constant σ (conductivity)that is independent of the electric field producing the current
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Radial Resistance of a Cable, Example 27.4 In a coaxial cable the current flows along its length. Some unwanted current leaks radially. Find the radial resistance of the silicon
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Ex.27.4 Solution Assume the silicon between the conductors to be concentric elements of thickness dr. The total resistance across the entire thickness of silicon:
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Derivation of Ohm’s Law + + + + + + b a
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Derivation of Drift Velocity Electrical force acting on electron is F = qE a = F / m e = qE / m e v f = v i + at v f = v i + (qE/m e )t For t= the average time interval between successive collisions v f avg = v d v d = (qE/m e )
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Derivation of Resistivity Note, the conductivity and the resistivity do not depend on the strength of the field Mean free path, ℓ, average distance between collisions = ℓ /v av J = nqv d = (nq 2 E / m e ) J= E
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