Two identical point charges (q = +7.30 x 10-6 C) are fixed at opposite corners of a square whose sides have a length of 0.310 m. A test charge (qo = -5.90 x 108 C), with a mass of 7.10 x 10-8 kg, is released from rest at one of the corners of the square. Determine the speed of the test charge when it reaches the center of the square. 90
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- A proton with a kinetic energy of 1.63 keV (1eV-1.602.10-19 J), that is at height 24.9 cm above a horizontal charged nonconducting plate with surface charge density - 3.60 μ C/m², is fired horizontally across this plate. What is the height of the proton after it has traveled a horizontal distance of 3.56 cm? 18.6 cm O 13.8 cm O 20.9 cm O 15.4 cm O 20.2 cm Save for Later Submit AnswerTwo negative charges, each with a charge of -7.7 nC, are at fixed locations as shown below. A proton is launched from the midpoint of the line joining the charges in a direction perpendicular to the line joining the charges. Find the minimum initial velocity of the proton that will allow it to escape to infinity. Ignore gravitational or any other influences on the proton. (k=1/480 = 8.99 × 109 Nm²/C2, e = 1.60 × 10-19 C, mproton = 1.67× 10-27 kg). [Hint: Conservation of energy might be helpful and you can assume that the proton is at rest at infinity] 5.0 mm 5.0 mm V 8.9 × 106 m/s 1.8 × 107 m/s None of these 4.6 × 106 m/s 2.3 × 106 m/sA positive charge of 4.20 μC is fixed in place. From a distance of 4.20 cm a particle of mass 6.20 g and charge +3.00 μC is fired with an initial speed of 62.0 m/s directly toward the fixed charge. How close to the fixed charge does the particle get before it comes to rest and starts traveling away? (in cm)
- Two equal charges are situated on the x axis at 40.0 cm on either side of the origin as shown in the figure below. Location A is on the perpendicular bisector at a distance of 21.0 cm from the origin on the y axis. (Assume that the +x axis is directed to the right and they axis is directed up.) 91 *A 92 (a) If q,- -3.50 C and q,- -3.50 C what is the net electric field due to both charges at location A? Express your answer in vector form. 1.64-10%) x Did you consider the symmetry of the situation? What is the net contribution to the field from the x components of the field from each charge? N/C (b) If a, 3a, (where q,- -3.50 pC), what is the net electric field at location A due to both charges? Express your answer in vector form -4.68-10%-4.1-10% x If the two charges are unequal, what is the net contribution to the field from each charge in the two perpendicular directions? N/CTwo identical point charges (q = +1.00 x 10-6 C) are fixed at opposite corners of a square whose sides have a length of 0.420 m. A test charge (90 = -7.50 × 10-8 C), with a mass of 2.80 x 10-8 kg, is released from rest at one of the corners of the square. Determine the speed of the test charge when it reaches the center of the square. Number i Units .90 VBTwo charges, each 6 µC, are on the x axis, one at the origin and the other at x = 8 m. Find the electric field on the x axis at each of the following locations. x = -2 m x = 2 m x = 6 m x = 10 m At what point on the x axis is the electric field zero?
- = A point charge q₁ 9.1 µC is held fixed at 0.42 μC and a mass origin. A second point charge 2 3.2 x 104 kg is placed on the x-axis, 0.96 m from the origin. The second point charge is released at rest. What is its speed when it is 0.24 m from the origin? =An negative point charge Q = - (1.000x10^0) µC is located at the origin. An electron is initially placed at at distance (2.8000x10^-1) m from Q. The initial velocity of the electron is zero. Under the electric force, the electron accelerates and moves to its final location, (9.40x10^-1) m from Q. What is the final kinetic energy of the electron? (assume there is no other forces on the electron) Give your answer in the unit of J with 3 s.f. Note: Your answer is assumed to be reduced to the highest power possible. Your Answer: x10 AnswerTwo air-filled balloons each have a mass of m = 3.9 g. Each balloon hangs from the same point by its own string of length L = 0.41 m. Each balloon is rubbed to give it a static charge. Both balloons are rubbed the same amount, so each balloon has the same unknown charge (q1 = q2). The hanging balloons push away until each makes and angle of θ = 16° with respect to the vertical. Determine the magnitude of the charge, in coulombs, on either one of the balloons. Remember that each balloon has the same charge. (q1 = q2)
- Consider the following. 60.0⁰ B 0.500 mm (a) Red blood cells often become charged and can be treated as point charges. Healthy red blood cells are negatively charged, but unhealthy cells (due to the presence of a bacteria, for example) can become positively charged. In the figure, three red blood cells are oriented such that they are located on the corners of an equilateral triangle. The red blood cell charges are A = 1.80 pC, B = 7.10 pC, and C= -4.30 pC. Given these charges, what would the magnitude and direction of the electric field be at cell A? (1 pC = 1 x 10-12 C.) magnitude N/C direction o counterclockwise from the +x-axis (b) If the charge of cell A were doubled, how would the electric field at cell A change? O The field would be unchanged. O The magnitude of the field would be doubled. O The magnitude of the field would be quadrupled. O The magnitude of the field would be halved.A point charge Q1 = +4.8 μC is fixed in space, while a point charge Q2 = -3.5 nC, with mass 6.4 μg, is free to move around nearby. If Q2 is released from rest at a point 0.44 m from Q1, what will be its speed, in meters per second, when it is 0.25 m from Q1?d -3q Q d d +9Q3 Q-3q d For the given figure only charge Q, mass of 3.0 g, can move which is initially at rest. Charges Q and Q are fixed. What is the kinetic energy of the charge Q, when it reaches the origin? (Take q = 400 uC and d= 2.3 mm) OA) 1.4 x 106 J Os 1.1 x 10+ J O c) 14 x 10s J 14 x 10 J 1.1 x 106 J