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Electric Forces and Fields Chapter 16
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Electrical Field Maxwell developed an approach to discussing fields An electric field is said to exist in the region of space around a charged object – When another charged object enters this electric field, the field exerts a force on the second charged object
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Direction of Electric Field The electric field produced by a negative charge is directed toward the charge – A positive test charge would be attracted to the negative source charge
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Electric Field, cont. A charged particle, with charge Q, produces an electric field in the region of space around it A small test charge, q o, placed in the field, will experience a force See example 15.4 & 5
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Coulomb’s Law Mathematically, k e is called the Coulomb Constant – k e = 8.99 x 10 9 N m 2 /C 2 Typical charges can be in the µC range – Remember, Coulombs must be used in the equation Remember that force is a vector quantity
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Electric Field Line Patterns Point charge The lines radiate equally in all directions For a positive source charge, the lines will radiate outward
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Electric Field Lines, cont. The field lines are related to the field as follows: – The electric field vector, E, is tangent to the electric field lines at each point – The number of lines per unit area through a surface perpendicular to the lines is proportional to the strength of the electric field in a given region
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Electric Field Line Patterns For a negative source charge, the lines will point inward
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Electric Field Line Patterns An electric dipole consists of two equal and opposite charges The high density of lines between the charges indicates the strong electric field in this region
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Electric Field Line Patterns Two equal but like point charges At a great distance from the charges, the field would be approximately that of a single charge of 2q The bulging out of the field lines between the charges indicates the repulsion between the charges The low field lines between the charges indicates a weak field in this region
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Electric Field Patterns Unequal and unlike charges Note that two lines leave the +2q charge for each line that terminates on -q
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Electric Field Mathematical Definition, The electric field is a vector quantity The direction of the field is defined to be the direction of the electric force that would be exerted on a small positive test charge placed at that point
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Chapter 17 Electric Energy and Current
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Work and Potential Energy For a uniform field between the two plates As the charge moves from A to B, work is done in it W = F d= q E d ΔPE = - W = - q E d – only for a uniform field
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Summary of Positive Charge Movements and Energy When a positive charge is placed in an electric field – It moves in the direction of the field – It moves from a point of higher potential to a point of lower potential – Its electrical potential energy decreases – Its kinetic energy increases
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Summary of Negative Charge Movements and Energy When a negative charge is placed in an electric field – It moves opposite to the direction of the field – It moves from a point of lower potential to a point of higher potential – Its electrical potential energy decreases – Its kinetic energy increases
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Potential Difference ΔPE = - W = - q E d The potential difference between points A and B is defined as: ΔV = V B – V A = ΔPE / q =-Ed Potential difference is not the same as potential energy 1V is defined as 1 J/C 1 Joule of work must be done to move a 1C across 1V potential difference
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Electric Potential of a Point Charge The point of zero electric potential is taken to be at an infinite distance from the charge The potential created by a point charge q at any distance r from the charge is V is scalar Quantity (superposition applies) A potential exists at some point in space whether or not there is a test charge at that point Ex. 16.4 p.540
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Potentials and Charged Conductors W = -ΔPE = -q(V B – V A ), – Therefore no work is required to move a charge between two points that are at the same electric potential i.e. W = 0 when V A = V B For two charges separated by r PE = k e q 1 q 2 r Charged Surfaces and Conductors All points on the surface of a charged conductor in electrostatic equilibrium are at the same potential
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Capacitors with Dielectrics
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Applications of Capacitors – Camera Flash The flash attachment on a camera uses a capacitor – A battery is used to charge the capacitor – The energy stored in the capacitor is released when the button is pushed to take a picture – The charge is delivered very quickly, illuminating the subject when more light is needed
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Applications of Capacitors -- Computers Computers use capacitors in many ways – Some keyboards use capacitors at the bases of the keys – When the key is pressed, the capacitor spacing decreases and the capacitance increases – The key is recognized by the change in capacitance
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Capacitance A capacitor is a device used in a variety of electric circuits—Often for energy storage Units: Farad (F) – 1 F = 1 C / V – A Farad is very large Often will see µF or pF
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Parallel-Plate Capacitor The capacitance of a device depends on the geometric arrangement of the conductors For a parallel-plate capacitor whose plates are separated by air: Є o is the permittivity of free space; Є o =8.85 x 10 -12 C 2 /Nm 2 d A C o Є
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Energy Stored in a Capacitor Energy stored = ½ Q ΔV From the definition of capacitance, this can be rewritten in different forms Q = C V
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Electric Current Whenever electric charges of like signs move, an electric current is said to exist The current is the rate at which the charge flows through this surface – charges flowing perpendicularly to a surface of area The SI unit of current is Ampere (A) – 1 A = 1 C/s + + + + +
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Electric Current, cont The direction of current flow is the direction positive charge would flow – This is known as conventional current flow In a common conductor, such as copper, the current is due to the motion of the negatively charged electrons It is common to refer to a moving charge as a mobile charge carrier – A charge carrier can be positive or negative Current II = ΔQC tS
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Meters in a Circuit Remember: 1 V = 1J/C
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Resistance, cont Units of resistance are ohms (Ω) – 1 Ω = 1 V / A Resistance in a circuit arises due to collisions between the electrons carrying the current with the fixed atoms inside the conductor
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Ohm’s Law Experiments show that for many materials, including most metals, the resistance remains constant over a wide range of applied voltages or currents This statement has become known as Ohm’s Law – ΔV = I R Ohm’s Law is an empirical relationship that is valid only for certain materials – Materials that obey Ohm’s Law are said to be ohmic
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Ohm’s Law, cont For an ohmic device The resistance is constant over a wide range of voltages The relationship between current and voltage is linear The slope is related to the resistance V slope=R I
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Electrical Energy and Power, The rate at which the energy is lost is the power From Ohm’s Law, alternate forms of power are EnergyE = PtW-s or kW-Hr
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Capacitors in Parallel (have the same voltage across them) Q 1 = C 1 ΔV Q 2 = C 2 ΔV Q 1 + Q 2 = Q tot = C 1 ΔV + C 2 ΔV = (C 1 + C 2 )ΔV for capacitors in parallel C eq = C 1 + C 2 Ex. 16.5 p.512
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Capacitors in Series (have the same charge on each plate) ΔV = Q C eq ΔV tot = ΔV 1 + ΔV 2 Q = Q 1 + Q 2 C eq C 1 C 2 But Q=Q 1 = Q 2 for capacitors in series 1 = 1 + 1 C eq C 1 C 2 Ex. 16.6 & 7 p. 515 C eq = C 1 C 2 C 1 + C 2
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Chapter 15 Summary ke is called the Coulomb Constant ke = 8.99 x 109 N m2/C2 εo is the permittivity of free space and equals 8.85 x 10-12 C 2 /Nm 2 Φ E = E A A is perpendicular to E
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Chapter 16 Summary Q = C V capacitors in series 1 = 1 + 1.... Ceq C1 C2 capacitors in parallel Ceq= C1+ C2.... C eq = C 1 C 2 C 1 + C 2 or d A C o Є Єo is the permittivity of free space; Єo =8.85 x 10-12 C2/Nm2 1 F = 1 C / V PE = ke q 1 q 2 r W = -ΔPE = -q(V B – V A )
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Resistivity The resistance of an ohmic conductor is proportional to its length, L, and inversely proportional to its cross-sectional area, A – ρ is the constant of proportionality and is called the resistivity of the material – See table 17.1
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