Register
Bare free charges do not remain stationary when close together. To illustrate this, calculate the acceleration of two isolated protons separated by 2.00 nm (a typical distance between gas atoms). Explicitly
161k views
2 votes
Bare free charges do not remain stationary when close together. To illustrate this, calculate the acceleration of two isolated protons separated by 2.00 nm (a typical distance between gas atoms). Explicitly show how you follow the steps in the Problem-Solving Strategy for electrostatics.

User Taile
by
7.1k points

1 Answer

5 votes

Answer:

Acceleration,
a=3.6* 10^(16)\ m/s^2

Step-by-step explanation:

It is given that, two isolated protons are separated by 2 nm. The force due to charged particles is given by :


F_e=(kq^2)/(d^2)

Force due to mass of proton,
F_g=ma


ma=(kq^2)/(d^2)


a=(kq^2)/(md^2)


a=(9* 10^9* (1.6* 10^(-19))^2)/(1.6* 10^(-27)* (2* 10^(-9))^2)


a=3.6* 10^(16)\ m/s^2

So, the acceleration of two isolated protons is
3.6* 10^(16)\ m/s^2. Hence, this is the required solution.

User Nidhish Krishnan
by
7.9k points
Ask a Question
Welcome to QAmmunity.org, where you can ask questions and receive answers from other members of our community.

8.6m questions

11.3m answers

Other Questions

At sea level, water boils at 100 degrees celcius and methane  boiled at -161 degrees celcius. Which of these substances has a stronger force of attraction between its particles? Explain your answer
Physical properties of minerals graphic organizer
A snowball is launched horizontally from the top of a building at v = 16.9 m/s. If it lands d = 44 meters from the bottom, how high (in m) was the building?
What type of rock is the Haystack rock (igneous, Metamorphic, or Sedimentary)
what is a device that transforms thermal energy to mechanical energy
Link Copied!