Question 5Two equally charged particles each have a mass of .015kg. They are suspendedby light strings as shown in the image below, with string lengths of 0.4m fromthe suspension point to the center of each particle. They reach an equilibriumposition as shown in the image.60°Which equations will you need to utilize in order to determine the charge oneach particle? [check all that apply]O EF, =ension cos(30) – mg%3DF = Fy – mgTensionFCoulomb- mgTension · sin(60) = F – F;FCoulomb: A x =O F. = 0O F, = 0O A E =A KE+ A PEO FCouloumb91 92p2O F = Tension · sin(30) – FCoulombWhat is the charge on each particle for the situation described in the previousquestion. [ give your answer in units of microCoulombs (i.e. 1µC = 1x10-6Coulombs) to 2 decimal places of precision ]

Given Data : m = 0.015Kg length of string l=0.4m angle = 60 degree To Find : magnitude of charge in…

Answered: What is the charge on each particle for…

Similar questions

[Numbers change] In the early 1900's Robert Millikan discovered the peculiar property that charge came in little packets, no smaller than e = 1.602 x 10-19 C -- he had measured the charge of the electron. Here's (roughly) how he did it. He removed an electron from an initially neutral droplet of oil with diameter 0.8 um. In a vacuum, he positioned the droplet between two metallic plates separated by 4 mm and fiddled with the potential (voltage) across the plates until the droplet would hover against the force of gravity. Droplets of this size with +e charge would hover, but only for a particular voltage (otherwise they would sink or rise). Given the parameters stated here, and the fact that the density of the oil was 815 kg/m³, what was the voltage that made the droplets hover? (give your answer with 0.1 V precision)
Assume that you are way out in space, very very far away from other masses, and you have two identical particleseach of which has the charge of an electron. Suppose you hold both of these particles 0.1m apart from each other and then release them. What mass would these particles have to have in order for the gravitational force to exactly balance the electric force? (So that they don't move.) [Put units on all numbers.]
You Answered Correct Answer A line of charge is placed along the negative x axis from x=-0.4m to x=0. The charge is uniformly distributed with linear charge density 3.06pC/m. A proton is released from rest at a point on the positive x axis 2.53m. When the proton has a speed of 472.1m/s, how far will it have moved (in m}? 1.0975 margin of error +/-1%
Needs Complete solution with 100 % accuracy.
Question 6 and 7. Index to show all work said assume that R = 2.43 m and c = 1.47 nC/m^4 the total charge of the disk
[Numbers change] A proton is flying through space with an initial velocity v, = 1.9 x 106 m/s, as %3D shown below. It interacts with a fixed negative charge q = - 7 nC along the path shown. What is its speed in m/s when it reaches the point P, given that x = 1.3 cm and y = 5.6 cm? Give your answer to 3 significant digits. (note the drawing may not be to scale) y Vo 11
A square is 53.0 cm on a side. (Assume that the +x-axis is to the right and the +y-axis is up along the page) Find the total Coulomb force on the charge q in the figure below, given that q = +1.25 µC, qa = +2.25 µC, qb = −3.05 µC, qc = −4.10 µC, and qd = +1.25 µC. The answer should list both magnitude (in N) and direction (in degrees counterclockwise from the +x-axis)
In the early 1900's Robert Millikan discovered the peculiar property that charge came in little packets, no smaller than e = 1.602 x 10-19 C -- he had measured the charge of the electron. Here's (roughly) how he did it. He removed an electron from an initially neutral droplet of oil with diameter 0.5 ??μm. In a vacuum, he positioned the droplet between two metallic plates separated by 6 mm and fiddled with the potential (voltage) across the plates until the droplet would hover against the force of gravity. Droplets of this size with +e charge would hover, but only for a particular voltage (otherwise they would sink or rise). Given the parameters stated here, and the fact that the density of the oil was 831 kg/m3, what was the voltage that made the droplets hover? (give your answer with 0.1 V precision)

What is the charge on each particle for the situation described in the previous question. [ give your answer in units of microCoulombs (i.e. 1µC = 1x10-6 Coulombs) to 2 decimal places of precision ]