Answer:
2.15 m/s²
Explanation:
We'll begin by calculating the force of attraction between two charges. This can be obtained as follow:
Charge of 1st object (q₁) = +11.5 μC = +11.5×10¯⁶ C
Charge of 2nd object (q₂) = –7.55 μC = –7.55×10¯⁶ C
Electrical constant (K) = 9×10⁹ Nm²/C²
Distance apart (r) = 0.925 m
Force (F) =?
F = Kq₁q₂ / r²
F = 9×10⁹ × 11.5×10¯⁶ × 7.55×10¯⁶/ 0.925²
F = 0.781425 / 0.855625
F = 0.91 N
Finally, we shall determine the acceleration of the object. This can be obtained as follow:
Mass of object (m) = 0.423 Kg
Force (F) = 0.91 N
Acceleration (a) =?
F = ma
0.91 = 0.423 × a
Divide both side by 0.423
a = 0.91 / 0.423
a = 2.15 m/s²
Thus, the magnitude of the object's acceleration is 2.15 m/s²
Answer:
Elastic potential energy,
Explanation:
Charge,
Potential, V = 50 V
It is required to find the electric potential energy in a capacitor stored in it. The formula of the electric potential energy in a capacitor is given by :
So, the electric potential energy stored in the capacitor is
Answer:
A centripetal force (latin: towards the center) is a force shown in any motion that does NOT go in a straight line, related to the fact that your velocity vector changes in direction, and thus you have an acceleration that goes in the same direction - adding an image for more clarity. Rest is just having to remember that acceleration and the force that causes it have the same direction, as do acceleration and change in velocity.
Centrifugal force (latin again: away from the center) is an apparent force, related to the fact that bodies have a tendency - called inertia - of wanting to keep their state of straight motion (or stillness, in case they're not moving to begin with). The moment they get accelerated in a curved trajectory (think a ball on the back seat of a car rolling to the outer side of the curve, you yourself being pushed towards the door if someone drives quite aggressively, or if you are into flight, the ball in a steam gauge turn coordinator, the internet should have photos of it), they receive an apparent acceleration relative to the frame of the moving place where they are, while they try to keep thier relative motion compared to an inertial frame of reference (ie, the rest of the earth).
Uniform magnetic lines as the name suggests are composed of lines that point to the same direction and of the same magnitude. This means all of these lines exert the same force. Non-uniform relates to different directions of the lines and a varied magnitude.