290 likes | 298 Vues
This chapter covers topics such as electric fields, potential energies, and currents in circuits. It includes questions related to potential energies, equipotential surfaces, and currents in different circuits.
E N D
The positive charge is the end view of a positively charged glass rod. A negatively charged particle moves in a circular arc around the glass rod. Is the work done on the charged particle by the rod’s electric field positive, negative or zero? • Positive • Negative • Zero
The positive charge is the end view of a positively charged glass rod. A negatively charged particle moves in a circular arc around the glass rod. Is the work done on the charged particle by the rod’s electric field positive, negative or zero? • Positive • Negative • Zero
Rank in order, from largest to smallest, the potential energies Ua to Ud of these four pairs of charges. Each + symbol represents the same amount of charge. • Ua = Ub > Uc = Ud • Ua = Uc > Ub = Ud • Ub = Ud > Ua = Uc • Ud > Ub = Uc > Ua • Ud > Uc > Ub > Ua
Rank in order, from largest to smallest, the potential energies Ua to Ud of these four pairs of charges. Each + symbol represents the same amount of charge. • Ua = Ub > Uc = Ud • Ua = Uc > Ub = Ud • Ub = Ud > Ua = Uc • Ud > Ub = Uc > Ua • Ud > Uc > Ub > Ua
A proton is released from rest at point B, where the potential is 0 V. Afterward, the proton • moves toward A with an increasing speed. • moves toward A with a steady speed. • remains at rest at B. • moves toward C with a steady speed. • moves toward C with an increasing speed.
A proton is released from rest at point B, where the potential is 0 V. Afterward, the proton • moves toward A with an increasing speed. • moves toward A with a steady speed. • remains at rest at B. • moves toward C with a steady speed. • moves toward C with an increasing speed.
Rank in order, from largest to smallest, the potentials Va to Ve at the points a to e. • Va = Vb = Vc = Vd = Ve • Va = Vb > Vc > Vd = Ve • Vd = Ve > Vc > Va = Vb • Vb = Vc = Ve > Va = Vd • Va = Vb = Vd = Ve > Vc
Rank in order, from largest to smallest, the potentials Va to Ve at the points a to e. • Va = Vb = Vc = Vd = Ve • Va = Vb > Vc > Vd = Ve • Vd = Ve > Vc > Va = Vb • Vb = Vc = Ve > Va = Vd • Va = Vb = Vd = Ve > Vc
Rank in order, from largest to smallest, the potential differences ∆V12, ∆V13, and ∆V23 between points 1 and 2, points 1 and 3, and points 2 and 3. • ∆V12 > ∆V13 = ∆V23 • ∆V13 > ∆V12 > ∆V23 • ∆V13 > ∆V23 > ∆V12 • ∆V13 = ∆V23 > ∆V12 • ∆V23 > ∆V12 > ∆V13
Rank in order, from largest to smallest, the potential differences ∆V12, ∆V13, and ∆V23 between points 1 and 2, points 1 and 3, and points 2 and 3. • ∆V12 > ∆V13 = ∆V23 • ∆V13 > ∆V12 > ∆V23 • ∆V13 > ∆V23 > ∆V12 • ∆V13 = ∆V23 > ∆V12 • ∆V23 > ∆V12 > ∆V13
Which set of equipotential surfaces matches this electric field?
Which set of equipotential surfaces matches this electric field?
Three charged, metal spheres of different radii are connected by a thin metal wire. The potential and electric field at the surface of each sphere are V and E. Which of the following is true? • V1 = V2 = V3 and E1 = E2 = E3 • V1 = V2 = V3 and E1 > E2 > E3 • V1 > V2 > V3 and E1 = E2 = E3 • V1 > V2 > V3 and E1 > E2 > E3 • V3 > V2 > V1 and E1 = E2 = E3
Three charged, metal spheres of different radii are connected by a thin metal wire. The potential and electric field at the surface of each sphere are V and E. Which of the following is true? • V1 = V2 = V3 and E1 = E2 = E3 • V1 = V2 = V3 and E1 > E2 > E3 • V1 > V2 > V3 and E1 = E2 = E3 • V1 > V2 > V3 and E1 > E2 > E3 • V3 > V2 > V1 and E1 = E2 = E3
A wire connects the positive and negative terminals of a battery. Two identical wires connect the positive and negative terminals of an identical battery. Rank in order, from largest to smallest, the currents Ia to Id at points a to d. • Ia =Ib =Ic =Id • Ia =Ib >Ic =Id • Ic =Id >Ia =Ib • Ic =Id >Ia >Ib • Ia >Ib >Ic =Id
A wire connects the positive and negative terminals of a battery. Two identical wires connect the positive and negative terminals of an identical battery. Rank in order, from largest to smallest, the currents Ia to Id at points a to d. • Ia =Ib =Ic =Id • Ia =Ib >Ic =Id • Ic =Id >Ia =Ib • Ic =Id >Ia >Ib • Ia >Ib >Ic =Id
Rank in order, from largest to smallest, the equivalent capacitance (Ceq)a to (Ceq)d of circuits a to d. • (Ceq)a > (Ceq)b = (Ceq)c > (Ceq)d • (Ceq)b > (Ceq)a = (Ceq)d > (Ceq)c • (Ceq)c > (Ceq)a = (Ceq)d > (Ceq)b • (Ceq)d > (Ceq)b = (Ceq)c > (Ceq)a • (Ceq)d > (Ceq)b > (Ceq)a > (Ceq)c
Rank in order, from largest to smallest, the equivalent capacitance (Ceq)a to (Ceq)d of circuits a to d. • (Ceq)a > (Ceq)b = (Ceq)c > (Ceq)d • (Ceq)b > (Ceq)a = (Ceq)d > (Ceq)c • (Ceq)c > (Ceq)a = (Ceq)d > (Ceq)b • (Ceq)d > (Ceq)b = (Ceq)c > (Ceq)a • (Ceq)d > (Ceq)b > (Ceq)a > (Ceq)c
What are the units of potential difference? • Amperes • Potentiometers • Farads • Volts • Henrys
What are the units of potential difference? • Amperes • Potentiometers • Farads • Volts • Henrys
What is the SI unit of capacitance? • Capaciton • Faraday • Hertz • Henry • Exciton
What is the SI unit of capacitance? • Capaciton • Faraday • Hertz • Henry • Exciton
The electric potential inside a capacitor • is constant. • increases linearly from the negative to the positive plate. • decreases linearly from the negative to the positive plate. • decreases inversely with distance from the negative plate. • decreases inversely with the square of the distance from the negative plate.
The electric potential inside a capacitor • is constant. • increases linearly from the negative to the positive plate. • decreases linearly from the negative to the positive plate. • decreases inversely with distance from the negative plate. • decreases inversely with the square of the distance from the negative plate.
The electric field • is always perpendicular to an equipotential surface. • is always tangent to an equipotential surface. • always bisects an equipotential surface. • makes an angle to an equipotential surface that depends on the amount of charge.
The electric field • is always perpendicular to an equipotential surface. • is always tangent to an equipotential surface. • always bisects an equipotential surface. • makes an angle to an equipotential surface that depends on the amount of charge.