LC-S A line of length I. with conastant linear charge density +λ(C/m) lies on the x...
LC-5 A line of length L with constant linear charge density +2(C/m) lies on the x axis. A point P lies on the perpendicular bisector of the line (the y axis). a) Show the details of the symmetry argument (pick dq's and show their dE's) to explain which of the two components (x or y) of the net field at point P are equal to zero due to the entire line of charge. Use the figure in your explanation. Explicitly...
LC-4 A vertical line of linear charge density λ 5.00x10-6cm y 0.750m lies on the y axis extending from the origin down to y-0.750m. a) Find the magnitude of Eneto the x component of the electric field at point P produced by the line of charge. Point P lies on the x axis at x=+0.750m. 750m b) Find the magnitude of Enety, the y component of the electric field at point P produced by the line of charge.
LC-3 A line of positive charge lies along the x axis extending from x-0 to x-L. The total charge Q on the lines is evenly distributed along the length L. Find the net electric field at point P, which is a distance 'a' from the origin on the x axis as shown in the figure to the right. Follow the steps in the "Procedure for Applying Coulomb's Law" that is in the "Worksheets" handed out the first day of class....
An infinite line of positive charge lies along the y axis, with charge density λ = 2.30 μC/m. A dipole is placed with its center along the x axis at x = 28.0 cm. The dipole consists of two charges ±10.0 μC separated by 2.00 cm. The axis of the dipole makes an angle of 45.0° with the x axis, and the positive charge is farther from the line of charge than the negative charge. Find the net force exerted...
An infinite line of positive charge lies along the y axis, with charge density λ = 2.20 µC/m. A dipole is placed with its center along the x axis at x = 27.0 cm. The dipole consists of two charges ±10.0 µC separated by 2.00 cm. The axis of the dipole makes an angle of 45.0° with the x axis, and the positive charge is farther from the line of charge than the negative charge. Find the net force exerted...
An infinite line of positive charge lies along the y axis, with charge density λ = 1.50 fC/m. A dipole is placed with its center along the x axis at x = 27.0 cm. The dipole consists of two charges ±10.0 pC separated by 2.00 cm. The axis of the dipole makes an angle of 30.0° with the x axis, and the positive charge is farther from the line of charge than the negative charge. Find the net force exerted...
An infinite line of positive charge lies along the y axis, with charge density λ = 1.80 µC/m. A dipole is placed with its center along the x axis at x = 21.0 cm. The dipole consists of two charges ±10.0 µC separated by 2.00 cm. The axis of the dipole makes an angle of 30.0° with the x axis, and the positive charge is farther from the line of charge than the negative charge. Find the net force exerted...
An infinitely long line of charge has a linear charge density λ, in units of C/m. (a) (3 pts.) Describe the shape Gaussian surface you would use for this charge configuration and the electric flux for this surface. Do all of the parts of this Gaussian surface have a nonzero electric flux? Explain. (b) (3 pts.) Derive an expression for the electric field in terms of the linear charge density λ. (c) (4 pts.) Briefly show how you would find...
An infinite line charge of uniform linear charge de sity λ--2.3 μC/m lies parallel to the y axis at x--2 m. A pont charge of 3.6 μC is located at x = 2.5 m, y = 3.5 m. Find the x component of the electric field at x 3.5 m,y-3.0 m. kN/C Enter Help
An infinite line charge of uniform linear charge density = -3.7 uC/m lies parallel to the y axis at x = -2 m. A point charge of 1.1 uC is located at x = 1.0 m, y = 2.0 m. Find the x component of the electric field at x = 2.0 m, y = 1.5 m.