What is the Charge on a Bead Accelerating in a Uniform Electric Field?

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A small charged bead with a mass of 1.0 g is released in a uniform electric field of 200,000 N/C, resulting in an upward acceleration of 20 m/s². The discussion revolves around determining the charge on the bead using force equations. Participants clarify that the relevant equations include F = qE, F = mg, and F = ma, emphasizing the application of Newton's second law. By setting the sum of forces, Eq - mg = ma, the relationship between the forces becomes clearer. The problem highlights the importance of correctly applying dynamics principles to find the charge.
Sarah88
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Homework Statement



A small charged bead has a mass of 1.0 g. It is held in a uniform electric field E= 200,000 N/C up. When the bead is released, it accelerates upward with an acceleration of 20 m/s^2. What is the charge on the bead?

Homework Equations


F= qE
F= mg
(possibly F= ma)


The Attempt at a Solution



I tried this problem multiple different ways including:
mg-Eq= 0
as well as Eq= ma

However, I wasn't sure how to relate the three force equations (mg, ma, Eq) together for this problem (because all seem relevant in this problem). Thank you!
 
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Welcome to PF!

Hi Sarah! Welcome to PF! :smile:
Sarah88 said:
I tried this problem multiple different ways including:
mg-Eq= 0
as well as Eq= ma

However, I wasn't sure how to relate the three force equations (mg, ma, Eq) together for this problem (because all seem relevant in this problem). Thank you!

Well, you're nearly there :wink:

as in almost all dynamics problems, just apply good ol' Newton's second law …

sum of forces = mass times acceleration …

what do you get? :smile:
 
Hi,
Thanks for the welcome to the forum :)

Well, the sum of forces equal to ma: Eq- mg (oppose each-other) = ma, it makes a lot more sense when you take into account Newton's second law. Thank you for your help! :)
 

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