greatest first.
Figure Shown three sections of the circuit that are to be connecte in turn to the same battery via a switch. The resistors are all identical, as are capactiors. Rank the sections according to a. the final (equilibrium) charge on the capacitor……… b. the time required for the capacitor to reah 50% of its final charge, greatest first…….
11
Nov
Figure Shown three sections of the circuit that are to be connecte in turn to the same battery via a switch. The resistors are all identical, as are capactiors. Rank the sections according to a. the final (equilibrium) charge on the capacitor……… b. the time required for the capacitor to reah 50% of its final [...]
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as are capactiors. Rank the sections according to a. the final (equilibrium) charge on the capacitor......... b. the time required for the capacitor to reah 50% of its final charge ,
Figure Shown three sections of the circuit that are to be connecte in turn to the same battery via a switch. The resistors are all identical ,
greatest first. ,
The potential energies associated with four orientations of an electric dipole in an electric field are (1)−5U0,(2)−7U0,(3)3U0,and(4)5U0, where U0 is positive. Rank the orientationa according to the a. angle between the electric dipole moment P→ and the electric field `vec E, and B magnitude of the torque on the electric dipole, greatest first.
05
Nov
The potential energies associated with four orientations of an electric dipole in an electric field are (1)−5U0,(2)−7U0,(3)3U0,and(4)5U0, where U0 is positive. Rank the orientationa according to the a. angle between the electric dipole moment P→ and the electric field `vec E, and B magnitude of the torque on the electric dipole, greatest first. (2)−7U0 (3)3U0 [...]
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(2)−7U0 ,
(3)3U0 ,
and B magnitude of the torque on the electric dipole ,
and(4)5U0 ,
greatest first. ,
The potential energies associated with four orientations of an electric dipole in an electric field are (1)−5U0 ,
where U0 is positive. Rank the orientationa according to the a. angle between the electric dipole moment P→ and the electric field `vec E ,
An electric dipole consists of two opposite charges of magnitude 1μC (micro-coulomb) separated by a distance of 2 cm . The dipole is placed in an electric field of 105Vm−1. (a) What maximum torque does the field exert on the dipole ? (b) How much work must an external agent do to turn the dipole end for end , starting from a position of alignment θ=0 ?
05
Nov
An electric dipole consists of two opposite charges of magnitude 1μC (micro-coulomb) separated by a distance of 2 cm . The dipole is placed in an electric field of 105Vm−1. (a) What maximum torque does the field exert on the dipole ? (b) How much work must an external agent do to turn the dipole [...]
State the following statements as Ture or False. a. Electric potential at any point on the bisector of a dipole is zero. b. A dipole experences maximum torque at the positive where potential energy is zero.
05
Nov
State the following statements as Ture or False. a. Electric potential at any point on the bisector of a dipole is zero. b. A dipole experences maximum torque at the positive where potential energy is zero. (Fig. ) shows four orientations of an electric dipole in an external electric field. Rank the orientations acording to [...]
(Fig. ) shows four orientations of an electric dipole in an external electric field. Rank the orientations acording to the a. magnitude of the torque on the dipole, and b. potential energy of the dipole, greatest first.
05
Nov
(Fig. ) shows four orientations of an electric dipole in an external electric field. Rank the orientations acording to the a. magnitude of the torque on the dipole, and b. potential energy of the dipole, greatest first. (Fig. ) shows four orientations of an electric dipole in an external electric field. Rank the orientations acording [...]
Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection , the end caps have these shapes, S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) the electric flux through the top end caps , greatest first.
01
Nov
Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection , the end caps have these shapes, S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) [...]
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Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection ,
greatest first. ,
S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) the electric flux through the top end caps ,
the end caps have these shapes ,
Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection , the end caps have these shapes, S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) the electric flux through the top end caps , greatest first.
17
Sep
Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection , the end caps have these shapes, S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) [...]
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Figure shows four Gaussion surfaces consisting of identical cylindrical midsections but different end caps. The surfaces central axis of each . Cylindrical midsection ,
greatest first. ,
S1 convex hemispheres S2 concave hermisphere S3 cones S4e flat disks. rank the surfaces acccording to (a) the net electric flux through them and (b) the electric flux through the top end caps ,
the end caps have these shapes ,
Figure showns. In cross section m three solid cylinders, each of length L and uniform charge Q. Concntric with each cylinder is a cylindrical Gaussion surface, with all three surfaces having the same radius. Rank the Gussion surface according to the electric field at any point on the suface, greatest first.
17
Sep
Figure showns. In cross section m three solid cylinders, each of length L and uniform charge Q. Concntric with each cylinder is a cylindrical Gaussion surface, with all three surfaces having the same radius. Rank the Gussion surface according to the electric field at any point on the suface, greatest first. each of length L [...]
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each of length L and uniform charge Q. Concntric with each cylinder is a cylindrical Gaussion surface ,
Figure showns. In cross section m three solid cylinders ,
greatest first. ,
with all three surfaces having the same radius. Rank the Gussion surface according to the electric field at any point on the suface ,