A 10-mg particle carries a charge of -5.9nC, and it is fired with an initial speed of 8m/s, directly toward a second small 58-mg particle that is carrying a charge of -3.2nC. the 2nd particle (initially held at a distance very far from the first particle) is held fixed throughout this process. what is the electric potential energy when the two particles are at the shortest distance possible.
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A 10-mg particle carries a charge of -5.9nC, and it is fired with an initial speed...
A small metal sphere of mass 5.7 g and charge 8.3 μC is fired with an initial speed of 1.7 m/s directly toward the center of a second metal sphere carrying charge 8.1 μC. This second sphere is held fixed. If the spheres are initially a large distance apart, how close do they get to each other? Treat the spheres as point charges.
A particle that carries a net charge of -23.8 ?C A particle that carries a net charge of -23.8 muC is held in a region of constant, uniform electric field. The electric field vector is oriented 55.2degree clockwise from the vertical axis, as shown. If the magnitude of the electric field is 4.82 N/C, how much work is done by the electric field as the particle is made to move a distance of d = 0.356 m straight up? What...
proton is fired from very far away directly at a fixed particle with charge q = 1.26 ✕ 10−18 C. the initial speed of the proton is 2.8 ✕ 105 m/s, what is its distance of closest approach to the fixed particle? mass of a proton is 1.67 ✕ 10−27 kg.
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A particle that carries a net charge of -41.8 μC is held in a region of constant, uniform electric field. The electric field vector is oriented 55.2° clockwise from the vertical axis, as shown. If the magnitude of the electric field is 5.82 N/C, how much work is done by the electric field as the particle is made to move a distance of d = 0.156 m straight up? What is the potential difference between the particle\'s initial and final...
A particle that carries a net charge of -95.8 μC is held in a region of constant, uniform electric field. The electric field vector is oriented 70.2° clockwise from the vertical axis, as shown. If the magnitude of the electric field is 5.32 N/C, how much work is done by the electric field as the particle is made to move a distance of d = 0.956 m straight up? What is the potential difference between the particle\'s initial and final...
A particle that carries a net charge of -41.8 HC is held in a region of constant, uniform electric field. The electric field vector is oriented 55.2° clockwise from the vertical axis, as shown. If the magnitude of the electric field is 5.82 N/C how much work is done by the electric field as the particle is made to move a distance of d- 0.956 m straight up? 55.20 Number What is the potential difference between the particle's initial and...
A particle that carries a net charge of-59.8 μC is held in a region of constant, uniform electric field. The electric field vector is oriented 55.2° clockwise from the vertical axis, as shown. If the magnitude of the electric field is 5.82 N/C, how much work is done by the electric field as the particle is made to move a distance of d = 0.956 m straight up? Number What is the potential difference between the particle's initial and final...
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