(I only need D and E thank you!) A cylindrical shell of length 135 m and radius 6 cm carries a uniform surface charge density of σ = 12 nC/m2.
a) What is the total charge on the shell? 610.73nC .
b) Find the electric field at the ends of the following radial distances from the long axis of the cylinder. r = 3 cm 0 N/C
c)r = 5.9 cm 0 N/C
d) r = 6.1 cm _____N/C
e) r = 10 cm _____N/C
(I only need D and E thank you!) A cylindrical shell of length 135 m and...
A cylindrical shell of length 160 m and radius 8 cm carries a uniform surface charge density of σ = 11 nC/m2. (a) What is the total charge on the shell? nC Find the electric field at the ends of the following radial distances from the long axis of the cylinder. (b) r = 4 cm N/C (c) r = 7.9 cm N/C (d) r = 8.1 cm N/C (e) r = 12 cm N/C
0, + -/5 points Tipler6 22.P.049 A cylindrical shell of length 240 m and radius 4 cm carries a uniform surface charge density of σ 14 nC/m. (a) What is the total charge on the shell? nC Find the electric field at the ends of the following radial distances from the long axis of the cylinder. (b)r- 2 cm N/C (c) r 3.9 cm N/C (d) r4.1 cm N/C (e) r = 8 cm N/C eBook
15. + 0/5 points Previous Answers Tipler6 22.P.049. My Notes + Ask Your Teacher A cylindrical shell of length 180 m and radius 5 cm carries a uniform surface charge density of o = 15 nC/m2. (a) What is the total charge on the shell? 84.8 x nc Find the electric field at the ends of the following radial distances from the long axis of the cylinder. (b) r = 2.5 cm N/C (c) r = 4.9 cm N/C (d)...
A thin nonconducting spherical shell of radius 6 cm carries a uniform surface charge density σ = 9 nC/m2. (a) What is the total charge on the shell? Find the electric field at the following radii (b) r = 2.1 cm N/C (c) r = 5.9 cm N/C (d) r = 6.1 cm N/C (e) r = 18 cm N/C
A cylinder of length 210 m and radius 5.50 cm carries a uniform volume charge density of p 340 nC/m3 (a) What is the total charge of the cylinder? 678.54 Use the formulas given below to calculate the electric field at a point equidistant from the ends of following radial distances from the long axis of the cylinder. (where λ-pmR2 is the charge per unit length) (b) r-2.15 cm N/C (c) 5.37 cm KN/C (d)r5.57 cm kN/C (e) r 11.6...
A long, conductive cylinder of radius R 2.70 cm and uniform charge per unit length 151 pC/m is coaxial with a long, cylindrical, nonconducting shell of inner and outer radii R2 9.45 cm and R3 10.8 cm, respectively. If the cylindrical shell carries a uniform charge density of p 79.8 pC/m3, find the magnitude of the electric field at the following radial distances from the central axis: Number 1.51 cm 0 N/C Number RR, R 6.08 cm 44.65 N/C Incorrect....
A long, conductive cylinder of radius R1 = 3.00 cm and uniform charge per unit length λ = 604 pC/m is coaxial with a long, cylindrical, non-conducting shell of inner and outer radii R2 = 10.5 cm and R3 = 12.0 cm, respectively. If the cylindrical shell carries a uniform charge density of p = 79.8 pC/m, find the magnitude of the electric field at the following radial distances from the central axis:
A thin nonconducting spherical shell of radius 6 cm carries a uniform surface charge density 8 nC7m (a) What is the total charge on the shell? nC Find the electric field at the following radi (b) r 1.7 cm N/C (c) r 5.9 cm N/C (d) r 6.1 cm N/C e 12 cm N/C eBook +-12 points Tipler6 22 P041 A nonconducting solid sphere of radius 8.20 cm has a uniform volume charge density. The magnitude of the electric field...
A thin cylindrical shell of radius R1=6.2cm is surrounded by a second cylindrical shell of radius R2=9.3cm. Both cylinders are 5.0 m long and the inner one carries a total charge Q1=−0.77μC and the outer one Q2=+1.54μC. A) For points far from the ends of the cylinders, determine the electric field at a radial distance r from the central axis of 4.1 cm . B) For points far from the ends of the cylinders, determine the magnitude of the electric...