Question

A small sphere is connected to a lightweight cord of length $L = 1.10 \text{ m}$ that is tied to a point $P$, as shown in the figure. The sphere, string, and point all lie on a frictionless, horizontal table. The sphere has a mass $m = 0.0100 \text{ kg}$, a charge $q = +1.80 \mu \text{C}$ and is released from rest when the string makes an angle $\theta = 60.0^\circ$ with a uniform electric field of magnitude $E = 310 \text{ V/m}$. Determine the speed (in m/s) of the sphere when the string is parallel to the electric field. Since the table is frictionless, and the sphere-field system is isolated, we may conserve energy. As a matter of convenience, set $V = 0$ at point $P$. Determine expressions for the electric potential energy and kinetic energy at the initial and final positions and conserve energy. m/s

          A small sphere is connected to a lightweight cord of length $L = 1.10 \text{ m}$ that is tied to a point $P$, as shown in the figure.

The sphere, string, and point all lie on a frictionless, horizontal table. The sphere has a mass $m = 0.0100 \text{ kg}$, a charge $q = +1.80 \mu \text{C}$ and is released from rest when the
string makes an angle $\theta = 60.0^\circ$ with a uniform electric field of magnitude $E = 310 \text{ V/m}$. Determine the speed (in m/s) of the sphere when the string is parallel to the
electric field.

Since the table is frictionless, and the sphere-field system is isolated, we may conserve energy. As a matter of convenience, set $V = 0$ at point $P$. Determine expressions for
the electric potential energy and kinetic energy at the initial and final positions and conserve energy. m/s

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A small sphere is connected to a lightweight cord of length L = 1.10 m that is tied to a point P, as shown in the figure.

The sphere, string, and point all lie on a frictionless, horizontal table. The sphere has a mass m = 0.0100 kg, a charge q = +1.80 μC and is released from rest when the
string makes an angle θ = 60.0^∘ with a uniform electric field of magnitude E = 310 V/m. Determine the speed (in m/s) of the sphere when the string is parallel to the
electric field.

Since the table is frictionless, and the sphere-field system is isolated, we may conserve energy. As a matter of convenience, set V = 0 at point P. Determine expressions for
the electric potential energy and kinetic energy at the initial and final positions and conserve energy. m/s

Added by Hailey B.

University Physics with Modern Physics

Hugh D. Young 14th Edition

Instant Answer

Solved by Expert Timothy James

10/14/2023

Step 1

Step 1: At the initial position when the string makes an angle of 60 degrees with the electric field, the electric potential energy (U_initial) can be calculated as U_initial = q * E * L * cos(theta), where q is the charge, E is the electric field magnitude, L is Show more…

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A small sphere is connected to a lightweight cord of length L=1.10m that is tied to a point P, as shown in the figure. (i) The sphere, string, and point all lie on a frictionless, horizontal table. The sphere has a mass m=0.0100kg, a charge q=+1.80mu C and is released from rest when the string makes an angle heta =60.0deg with a uniform electric field of magnitude E=310(V)/(m). Determine the speed (in (m)/(s) ) of the sphere when the string is parallel to the electric field. Since the table is frictionless, and the sphere-field system is isolated, we may conserve energy. As a matter of convenience, set V=0 at point P. Determine expressions for the electric potential energy and kinetic energy at the initial and final positions and conserve energy. (m)/(s) A small sphere is connected to a lightweight cord of length L = 1.10 m that is tied to a point P, as shown in the figure m + E V Topview ? The sphere, string, and point all lie on a frictionless, horizontal table. The sphere has a mass m = 0.0100 kg, a charge q = +1.80 C and is released from rest when the string makes an angle = 60.0 with a uniform electric field of magnitude E = 310 V/m. Determine the speed (in m/s) of the sphere when the string is parallel to the electric field 0.00247 X Since the table is frictionless, and the sphere-field system is isolated, we may conserve energy. As a matter of convenience, set V = 0 at point P. Determine expressions for

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