A very long insulating cylinder of charge of radius 3.00 cm carries a uniform linear density of 18.0 nC/m .
If you put one probe of a voltmeter at the surface, how far from the surface must the other probe be placed so that the voltmeter reads 155 V ?
d= cm
A very long insulating cylinder of charge of radius 3.00 cm carries a uniform linear density...
A very long insulating cylinder of charge of radius 2.80 cm carries a uniform linear density of 18.0 nC/m . Part A If you put one probe of a voltmeter at the surface, how far from the surface must the other probe be placed so that the voltmeter reads 155 V ?
Constants A very long insulating cylinder of charge of radius 2.60 cm carries a uniform linear density of 14.0 nC/m f you put one probe of a voltmeter at the surface, how far from the surface must the other probe be placed so that the voltmeter reads 150 V ? cm
A very long insulating cylinder of charge of radius 2.90 cm cm carries a uniform linear density of 17.0 nC/m. If you put one probe of a voltmeter at the surface, how far from the surface must the other probe be placed so that the voltmeter reads 175 VV? Express your answer in centimeters.
Exercise 23.32 A very long insulating cylinder of charge of radius 2.40cm carries a uniform linear density of 18.0nC/m . i tried 6900 cm and140cm 1.4cm and1.3cm Part A If you put one probe of a voltmeter at the surface, how far from the surface must the other probe be placed so that the voltmeter reads 195V ?
A very long insulating cylindrical shell of radius 6.10 cm carries charge of linear density 9.00 μC/m spread uniformly over its outer surface. What would a voltmeter read if it were connected between the surface of the cylinder and a point 4.20 cm above the surface?
A very long insulating cylindrical shell of radius 6.10 cm carries charge of linear density 8.30 µC/m spread uniformly over its outer surface. (a) What would a voltmeter read if it were connected between the surface of the cylinder and a point 5.20 cm above the surface? (b) What would a voltmeter read if it were connected between the surface and a point 0.50 cm from the central axis of the cylinder?
please AAwith a good diagram if necessary and a well explained solvings for my understandignks 3.4.5. A very long cylinder of a radius 1.00 cm carries a uniform charge density of 0.5 nC/m. (a) Describe the shape of the equipotential surfaces for this cylinder. (b) Taking the reference level for the zero of potential to be the surface of the cylinder, find the radius of equipotential surfaces having potentials of 9.0 V, 18.0 V, and 27.0 V. (c) Are the...
P6. A very long cylinder of radius a 5.00 cm has a uniform charge density 15.0 nC/em. Plot the electric field created by this cylinder as a function of r, the distance from the axis of the cylinder, for 0〈r< 15.0 cm.
An infinite long insulating cylinder (radius 12 cm) has a uniformly distributed charge of density p 5.0 nC/m3. Determine the electric field a.) 5.0 cm from the central axis of the cylinder. b.) On the surface of the cylinder c.) 15.0 cm from the central axis of cylinder
An infinitely long cylinder of radius R = 3 cm carries a uniform charge density p = 17 Cm. Calculate the electric field at distance r = 18 cm from the axis of the cylinder. Select one: O a. 8.8x10° NC b. 2.8x10NC c. 6.8x103 N/C d. 0.8x10° NIC O O e. 4.8x10 N/C