A proton is projected through a perpendicular uniform electric field as shown. The region of the electric field is 12cm long as shown. The distance between the upper and lower plates is 6.78mm. The proton starts at the vertical midpoint with an initial horizontal speed of 8.29 ×10*m/s. Determine the magnitude of the maximum electric field for which the proton can make it through without hitting the lower plate (inN/C). Answeredct AnswerA proton is projected through a perpendicular uniform electric field asshown. The region of the electric field is 12cm long as shown. Thedistance between the upper and lower plates is 6.78mm. The protonstarts at the vertical midpoint with an initial horizontal speed of 8.29x 10¹ m/s. Determine the magnitude of the maximum electric field forwhich the proton can make it through without hitting the lower plate (inN/C).1,03012.0 cm-d33.7311 margin of error +/- 1%

The mass and charge of a proton respectively are as follows.

A proton is projected through a perpendicular uniform electric field as shown. The region of the electric field is 12cm long as shown. The distance between the upper and lower plates is 6.78mm. The proton starts at the vertical midpoint with an initial horizontal speed of 8.29 x 10¹ m/s. Determine the magnitude of the maximum electric field for which the proton can make it through without hitting the lower plate (in N/C). 1,030 12.0 cm- 33.7311 margin of error+/- 1%

A proton is projected through a perpendicular uniform electric field as shown. The region of the electric field is 12cm long as shown. The distance between the upper and lower plates is 6.78mm. The proton starts at the vertical midpoint with an initial horizontal speed of 8.29 x 10¹ m/s. Determine the magnitude of the maximum electric field for which the proton can make it through without hitting the lower plate (in N/C). 1,030 12.0 cm- 33.7311 margin of error+/- 1%

Principles of Physics: A Calculus-Based Text

5th Edition

ISBN:9781133104261

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter19: Electric Forces And Electric Fields

Section: Chapter Questions

Problem 31P

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