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2 years ago

A proton is suspended in the air by an electric field at the surface of Earth. What is the strength of this electric field?

Physics

1 answer:

ryzh [129]2 years ago

4 0

Answer:

The strength of the electric field is $1.02\times10^{-7}\frac{N}{C}$

Explanation:

By Newton's first law $\sum\overrightarrow{F}=0$ tells us that to maintain suspended the proton (at rest), the net force on it should be zero, assuming there's only gravitational interaction between earth and proton we should apply a force in the opposite direction equal to the weight of the proton ( $W=mg$ , at earth surface) to make net force zero.

So, the electrostatic force on the charge should be:

$F_{e}=mg$ (1)

with m the mass and g the gravity

but electrostatic force of a charge on an electric field is:

$F_{e}=Eq$ (2)

with E the magnitude of electric field and q the charge of the proton

Equating (1) and (2):

$Eq=mg$

Solving for E:

$E=\frac{mg}{q}$

A fast search on google give us the mass of the proton and its charge:

$E=\frac{(1.67\times10^{-27}kg)(9.81\frac{m}{s^{2}})}{1.60\times10^{-19}C}=1.02\times10^{-7}\frac{N}{C}$

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Assume that the electric field E is equal to zero at a given point. Does it mean that the electric potential V must also be equa

lyudmila [28]

Answer:

No, this doesn't mean the electric potential equals zero.

Explanation:

In electrostatics, the electric field $\vec{E}$ is related to the gradient of the electric potential V with :

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give an electric field of zero at point (0,0,0)

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