The relationship between the electric force F (e) and the gravitational force F (g) (or 1. weight) between two electron...
a) Calculate the electrical force between a gram of protons and the same number of electrons that are separated by 1 m. (There are about 5.979x1023 protons in a gram, each with a charge of +1.602x10-19 C; charge on an electron is the same magnitude but negative) b) Calculate the gravitational force between two 1g masses 1 meter apart, when F- Gmm2/r2 where G is equal to 6.67x10-11 N m2 / kg2 What is the magnitude difference between these two...
I need the answer for this question. It has to be step by step on a document or a paper and it has to be clear so I can understand. I would give thumbs up (Like) to the person that answers correctly. If I don't understand, I would not give thumbs up (like). Please read all the question and thank you. This is general physics and its from Coulomb law. Answer this question STEP by STEP on a document or...
It is known that the electric force of repulsion between two electrons is much stronger than the gravitational attraction. For two electrons at a distance d apart, calculate the ratio of the size of the electrostatic repulsion to that of the gravitational attraction at a disance d apart, calculate the ratio of the size of the electrostatic repulsion to that of the gravitational attraction Use the following data: k-8.99x 109 Nm2/C2, e-1.60x10-19 C, G-6.67x10-11 Nm2/kg2, me 9.11x10-31 kg.
force and Gravitational force Puntos:2 Two identical balls of mass 24 g are suspended from threads of length 1.1 m and carry equal charges of 19 nC as shown in the figure. Assume that 0 is so small that its tangent can be replaced by its sine and find the value of x. Enviar Respuesta Tries 0/5 If the two balls in the previous part are losing charge at the rate of 1e-9 C/s, at what instantaneous speed do the...
It is known that the electric force of repulsion between two electrons is much stronger than the gravitational attraction. For two electrons at a distance d apart, calculate the ratio of the size of the electrostatic repulsion to that of the gravitational attraction. Use the following data: k = 8.99×109 Nm2/C2, e = 1.60×10-19 C, G = 6.67×10-11 Nm2/kg2, me = 9.11×10-31 kg.
(a) Two protons in a molecule are 4.10 x 1010 m apart. Find the electric force exerted by one proton on the other. magnitude directionSelect (b) State how the magnitude of this force compares with the magnitude of the gravitational force exerted by one proton on the other (c) What must be a particle's charge-to-mass ratio if the magnitude of the gravitational force between two of these particles is equal to the magnitude of electric force between them? C/kg
Consider the following figure of two charged spheres suspended from insulating strings as shown. Electric Force suppose the charge q on each small sphere is 1.0 μC, the distance a is 30 cm, and L-50 cm. What is the magnitude of the electric force acting on each charged sphere? Use for the Coulomb constant ke 9,0x 10 Nm 1C The electric force magnitude isN. (Give the correct number) Your answer
It is known that the electric force of repulsion between two electrons is much stronger than the gravitational attraction. For two electrons at a distance d apart, calculate the ratio of the size of the electrostatic repulsion to that of the gravitational attraction. Use the following data: k = 8.99 Times 10^9 Nm^2/C^2, e = 1.60 Times 10^-19 C, G = 6.67 Times 10^-11 Nm^2/kg^2, m_e = 9.11 Times 10^-31 kg. Tries 0/20
(a) Two protons in a molecule are 3.40 x 1010 m apart. Find the electric force exerted by one proton on the other magnitude directionrepuisive (b) State how the magnitude of this force compares with the magnitude of the gravitational force exerted by one proton on the other. What is the equation for the electrical force acting between two charged objects? N What is the mass of a proton? (c) What must be a particle's charge-to-mass ratio if the magnitude...
2. (a) Two small metallic spheres, each of mass 2.00 g, are suspended as pendulums by light, non-conducting strings as shown below. The spheres are given the same electric charge, and it is found that they come to equilibrium when each string is at an angle of 30° with respect to the vertical. (a) If the strings are each 10.0 cm long, what is the magnitude of the charge on each sphere? Assume that the gravitational force between the two...