Fill in the table below according to measurements.V(V)Q(C)d(mm)?51.230.77?10150.60.5?20?250.42Cmeasuring amp.=0.22 x 10¬6 FVsupplyV Dielectric materialV Metal plates radiusA. Uc- cu, -= 2.5 kVQ = CU, =E0dair130 тm

The different parts of the problem is solved in the next step by using the formula provided.

Fill in the table below according to measurements. d(mm) V(V) Q(C) 5 1.23 10 0.77 ? 15 0.6 ? 20 0.5 25 0.42 ? Cmeasuring amp.=0.22 x 10-6 F A. Uc Vsupply = 2.5 kV V Dielectric material V Metal plates radius Q = CU. = E0 d air = 130 mm

Fill in the table below according to measurements. d(mm) V(V) Q(C) 5 1.23 10 0.77 ? 15 0.6 ? 20 0.5 25 0.42 ? Cmeasuring amp.=0.22 x 10-6 F A. Uc Vsupply = 2.5 kV V Dielectric material V Metal plates radius Q = CU. = E0 d air = 130 mm

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter23: Electric Fields

Section: Chapter Questions

Problem 23.2P: (a) Calculate the number of electrons in a small, electrically neutral silver pin that has a mass of...

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1) Consider the figure below. An electron is fired towards a conducting plate from a distance L. The plate has a surface charge density a and a radius that is much greater than the distance L.. When the electron strikes the plate, it is measured that AK. E. 10 eV, where AK. E. Ty-To is the difference between the electron's final kinetic energy and initial kinetic energy. = a) Draw a diagram of the configuration including the co-ordinate system you have chosen. b) Write the integral equation for the work done on the electron when moving from it's initial position to an arbitrary final position, x . c) Write the integral equation for the potential difference of the system for a path that begins at the electron's initial position and ends at an arbitrary position, x. d) Determine the equation for the potential difference between the initial position of the electron and an arbitrary position, x. e) Plot the potential difference from part d) f) If the electron is initially at rest and L=…
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1) Consider the figure below. An electron is fired towards a conducting plate from a distance L. The plate has a surface charge density and a radius that is much greater than the distance L. When the electron strikes the plate, it is measured that AK. E. = 10 eV, where AK.E.= Tf - To is the difference between the electron's final kinetic energy and initial kinetic energy. Using a co- ordinate system with the origin placed at the initial position of the electron: a) Draw a diagram of the configuration including the co-ordinate system you have chosen b) Write the integral equation for the work done on the electron when moving from it's initial position to an arbitrary final position, x c) Write the integral equation for the potential difference of the system for a path that begins at the electron's initial position and ends at an arbitrary position, x. d) Determine the equation for the potential difference between the initial position of the electron and an arbitrary position, x. e) Plot…
File 2 Undo A2 22 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Home Insert A B 1 Charge (C) Magnitue (N) 2 0.02 449.378 3 0.028 229.274 4 0.036 138.677 0.044 92.847 0.052 66.476 0.06 49.931 0.068 38.873 0.076 31.12 0.084 25.475 0.092 21.237 0.1 17.975 22 Paste XAY Clipboard 5 V X✓ Sheet1 Page Layout Calibri B I U- C 0.02 D Force magnitude (N) Formulas Data Review View Font 500 450 400 350 300 250 200 150 100 50 0 0 11 - AA a A V E F 0.02 5 229.274 G 138.677 92.847 0.04 Help Series1 44995ce magnitude (N) vs Distance(m) M Alignment H →= y=0.1798x2 R² = 1 0.06 Distance (m) General 0.08 $ % 98 Power (Series1) 66.47649.9338.87331.1225.47221.2377.975 J Number 0.1 K 0.12 5