A neutral water molecule `(H_(2)O)` in its vapour state has an electric dipole moment of magnitudes `6.4xx10^(-30)C-m`. How far apart are the molecules centres of positive and negative charge

A neutral water molecule (H_(2)O) in its vapor state has an electric dipole moment of magnitude 6.2xx10^(-30)C*m . How far apart are the molecule's centers of positive and negative charge?

A neutral water molecule (H_2 O) in its vapour state has an electric dipole moment of magnitude 6.2 xx 10^-30 cm . a. How far apart are the molecules' centers of positive and negative charge ? b. If a molecule is placed in an electric field of 1.5 xx 10^4 NC^-1 , what maximum torque can the field exert on it ? (Such a field can easily be set up in the laboratory). c. How much work must an external agent do to turn this molecule end for end in this field, starting from its fully aligned position, for which theta = 0 ?

A neutral water molecule (H_(2)O) in its vapor state has an electric dipole moment of magnitude 6.2xx10^(-30)C*m . If the molecule is placed in a electric field of 1.5xx10^(4)N//C , what maximum torque can the field exert on it? (Such a field can easily be set up in the laboratory.)

A neutral water molecule (H_(2)O) in its vapor state has an electric dipole moment of magnitude 6.2xx10^(-30)C*m . How much work must an external agent do to rotate this molecule by 180^(@) in this field, starting from its fully aligned position , for which theta=0 ?

An ammonia molecule has permanent electric dipole moment = 1.47D, where 1D = 1 debye unit = 3.34xx10^(-30) Cm . Calculate electric potential due to this molecule at a point 52.0 nm away along with axis of the dipole. Assume V = 0 at infinity.