electric force F = +E*q
net force F = m*a
acceleration a = Eq/m
a = 1*10^6*1.6*10^-19/(9.11*10^-31)
a = 1.75*10^17 m/s^2 <<<---answer
For the situation depicted in the diagram below, calculate the acceleration of the electron if it...
The figure below shows an electron at the origin that is released with initial speed vo = 3.1 106 m/s at an angle θ。= 45° between the plates of a parallel plate capacitor of plate separation D = 2.0 mm. If the potential difference between the plates is Δν 160 V, calculate the closest proximity, d, of the electron to the bottom plate (in mm) D 0 0o 0
The figure below shows an electron at the origin that is released with initial speed vo = 3.1 106 m/s at an angle θ。= 45° between the plates of a parallel plate capacitor of plate separation D = 2.0 mm. If the potential difference between the plates is Δν 160 V, calculate the closest proximity, d, of the electron to the bottom plate (in mm) D 0 0o 0
The figure below shows an electron at the origin that is released with initial speed v0 = 3.5 ✕ 106 m/s at an angle θ0 = 45° between the plates of a parallel plate capacitor of plate separation D = 2.0 mm. If the potential difference between the plates is ΔV = 185 V, calculate the closest proximity, d, of the electron to the bottom plate (in mm).
17 P The figure below shows an electron at the origin that is released with initial speed vo4 plate separation D -2.0 mm. If the potential difference plate separation D-2.0 mm. If the potential difference between the plates is aV - 125 V, calculate the closest proximity, d, of the electron to the bottom m/s at an angle 80 45 the plates of a parallel plate capacitor of
Three forces acting on a spherical mass M are depicted in the diagram below. Calculate the magnitude and direction (i.e., the angle with respect to the positive H-axis, measured positive as counter-clockwise) of the total force acting on M. Notice that the arrows representing the forces end on grid intersections. E40 O 20 -20 -30-20-10 θ 10 20 30 40 50 60 70 80 Force, Horizontal-component (N)
An electron is moving with a velocity of 2.56x10' m/s. Calculate the minimum possible uncertainty in its position. (a) 0.038x101 m c (b) 4.50 x10-10 m (c) 4.50 x101 m (d) None of the above
Three forces acting on a spherical mass M are depicted in the diagram below. A. Calculate the magnitude and direction (i.e., the angle with respect to the positive H-axis, measured positive as counter-clockwise) of the total force acting on M. Notice that the arrows representing the forces end on grid intersections. Magnitude: Direction: Incompatible units. No conversion found between "N" and the required units. Tries 0/20 Previous Tries B. When a fourth force is applied to the mass, it is...
Three forces acting on a spherical mass M are depicted in the diagram below. A. Calculate the magnitude and direction (i.e., the angle with respect to the positive H-axis, measured positive as counter-clockwise) of the total force acting on M. Notice that the arrows representing the forces end on grid intersections. Magnitude: Direction: E40 O 20 1 -20 -30-20-10 θ 10 20 30 40 50 60 70 80 Force, Horizontal-component (N)
Three forces acting on a spherical mass M are depicted in the diagram below. A. Calculate the magnitude and direction (i.e., the angle with respect to the positive H-axis, measured positive as counter-clockwise) of the total force acting on M. Notice that the arrows representing the forces end on grid intersections. Magnitude: Direction: Processing your submission ... Tries 0/20 B. When a fourth force is applied to the mass, it is observed that the velocity of the mass stops changing...
An electron is placed between the plated of a rectangular parallel plate capacitor. The capacitor has a voltage of V = 10 V and the physical dimensions are: length l= 10cm, width = 5cm and the separation distance is d = 3 mm. Calculate the acceleration of the electron one it is released.