Determine the magnitude of the force between an electric dipole with a dipole moment of 2 ✕ 10-29 C m and an electron. The electron is positioned
r = 24
nm from the centre of the dipole, along the dipole axis. Hint: Assume that
r >> d,
with d the charge separation distance in the dipole.
Determine the magnitude of the force between an electric dipole with a dipole moment of 2...
Determine the magnitude of the force between an electric dipole with a dipole moment of 9 ✕ 10-29 C m and an electron. The electron is positioned r = 28 nm from the centre of the dipole, along the dipole axis. Hint: Assume that r >> d, with d the charge separation distance in the dipole.
Determine the magnitude of the free between an electric dipole with a dipole moment of 8 x 10-29 C m and an electron. The electron is the dipole, along the dipole axis. Hint: Assume that r >> d, with d the charge separation distance in the dipole. positioned r 16nm from the centre of
1) At a certain location close to Earth's surface, we observe a uniform electric field of magnitude 105 N/C directed straight down. What must be the charge (in C) that needs to be placed on a person of mass 84 kg in order to make them lose contact with the ground? Make sure to correctly identify the sign of the charge needed. 2) Determine the magnitude of the force between an electric dipole with a dipole moment of 4 ✕...
The dipole moment of the water molecule (H2O) is 6.17×10−30 C.m. Consider a water molecule located at the origin whose dipole moment p? points in the +x-direction. A chlorine ion (Cl-), of charge −1.60 × 10−19 C, is located at x = 3 nm. Assume that x is much larger than the separation d between the charges in the dipole, so that the approximate expression for the electric field along the dipole axis can be used. (a) Find the magnitude...
The dipole moment of the water molecule (H2O) is 6.17×10−30C⋅m. Consider a water molecule located at the origin whose dipole moment p⃗ points in the +x-direction. A chlorine ion (Cl−), of charge −1.60×10−19C, is located at x=3.00×10−9m. Assume that x is much larger than the separation d between the charges in the dipole, so that the approximate expression for the electric field along the dipole axis can be used. Find the magnitude of the electric force that the water molecule...
The dipole moment of the water molecule (H2O)is 6.17 x 10-30 C- m. Consider a water molecule located at the origin whose dipole moment p points in the +X-direction. A chlorine ion (Cl), of charge 1.60 x 10-19 C, is located at 3.00 x 10-9m. Assume that ac is much larger than the separation d between the charges in the dipole, so that the approximate expression for the electric field along the dipole axis can be used. Find the magnitude...
An electric dipole consists of a negative charge- located at (0,-) and a positive charge +q located at (0, +3). The dipole moment p is defined as a vector of magnitude qs directed from the negative charge of the dipole to the positive charge of the dipole. (a) Show that the net force exerted by the dipole on a charge +Q located on the r-axis at a distance r from the dipole is given by: s 2 -3/2 F- r"...
1 Dipole Forces Water is a polar molecule. It has an electric dipole strength of p 6-10-30 C-n This is roughly equivalent to a proton and an electron separated by a distance of d 4.101 m (about the radius of a hydrogen atom) In this problem, we will use Coulomb's law to compare the force between two protons, a proton and a water molecule, and two water molecules. Use the arrangement of the charges shown in the figure for your...
1 Dipole Forces Water is a polar molecule. It has an electric dipole strength of p-6-10-30 С . m. This is roughly equivalent to a proton and an electron separated by a distance of d- 4 10-11 m (about the radius of a hydrogen atom) In this problem, we will use Coulomb's law to compare the force between two protons, a proton and a water molecule, and two water molecules. Use the arrangement of the charges shown in the figure...
Some types of molecules that do not possess an intrinsic electric dipole moment can be given one by an external electric field in a process called charge separation, or polarization. In this process, their internal charge distribution becomes distorted by the field, which results in the region of a molecule on the side in the direction of the field gaining a positive net charge and the region on the other side gaining a negative net charge. Both charges have equal...