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A 0.200 kg block with a charge of 30.0 μC is pressed against a spring that is displaced 25.0 cm. The spring as a spring constant of 150 N/m. The block is released from rest and slides up a frictionless incline into an electric field of 50, 000 N/C pointed down the incline. Use Conservation of Energy. a. Setup the Energies for the block and spring. b. Solve for the distance traveled by the block up the incline. (ans: 1.89 m)

A 0.200 kg block with a charge of 30.0 μC is pressed against a spring that is displaced 25.0 cm. The spring as a spring constant of 150 N/m. The block is released from rest and slides up a frictionless incline into an electric field of 50, 000 N/C pointed down the incline. Use Conservation of Energy. a. Setup the Energies for the block and spring. b. Solve for the distance traveled by the block up the incline. (ans: 1.89 m)

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  1. A 0.200 kg block with a charge of 30.0 μ C is pressed against a spring that is displaced 25.0 cm . The spring as a spring constant of 150 N / m . The block is released from rest and slides up a frictionless incline into an electric field of 50,000 N C pointed down the incline. Use Conservation of Energy. a. Setup the Energies for the block and spring. b. Solve for the distance traveled by the block up the incline. (ans: 1.89 m )

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