Equipotential lines indicate that at all the points on such line, value of potential will be the sam Electric Field: 1. Select +1nC charge. De-select Electric Field. Click on Values and Grid. And select Sensors from bottom. 2. Keep Sensor at a distance of 2 meter from charge. What is the value of electric field at this point? Calculate the value by using formula of electric field. Do both values match? a) Value of electric field in the simulation b) Value by using formula of electric field in the formula above c) Value by using formula of electric potential in the formula above V/m V/m 3. As sensor is moved away from charge, how does the magnitude of electric field change? a)

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Equipotential lines indicate that at all the points on such line, value of potential will be the same. Electric Field: 1. Select +1nC charge. De-select Electric Field. Click on Values and Grid. And select Sensors from bottom. 2. Keep Sensor at a distance of 2 meter from charge. What is the value of electric field at this point? Calculate the value by using formula of electric field. Do both values match? a) Value of electric field in the simulation_ bý Value by using formula of electric field in the formula above c) Value by using formula of electric potential in the formula above_ V/m _V/m 3. As sensor is moved away from charge, how does the magnitude of electric field change? a) 4. Keep sensor at one point. Take +1nc more charge and keep it above earlier +1nC charge. How does the magnitude and direction of electric field change? a) Magnitude of electrical field in the simulation _and the direction 5. Can you predict the value of electric field at this point when charge becomes +5nC? a) 6. Remove all positive charges. Let the sensor be at same point. Now take -1nC charge. What is the value of electric field? Do you observe any change? a) b) 7. Click on Electric Field. For a positive point charge, what is the pattern of electricfield