Consider the two charges arranged as shown in the figure with Q₁ = +5 μC and Q₂ = -5 µC. (a) Calculate the energy stored in this arrangement of charges. 1 (c) What is the force on Q₂ produced by the Q₁ charge? Q₁ 0 (b) Calculate the Electric Field vector at point P(1,1). (Write as a vector.) P (1,1) 1 W = E= F= 2 Q₂
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- An electric field of magnitude 457 V/m passing through a flat square plate of length 0.556 m on a side makes an angle of 63.8 degrees with the surface of plate. Determine the electric flux passing through the surface of the square plate. (Hint: the angle given here is the angle that the field makes with the surface, not with the area vector. In what direction does the area vector of a surface point relative to that surface?)At some instant the velocity components of an electron moving between two charged parallel plates are v. and vy. Suppose the electric field between the plates is E (it is uniform and points only in the y direction). NOTE: Express your answers in terms of the given variables, using e for the fundamental charge and me for the mass of an electron. (a) What is the magnitude of the acceleration of the electron? E a= X me (b) What is the y-component of electron's velocity when its x coordinate has changed by a distance d? Ed Vd=vy + X Ux meI need help on this? Could you write an explanation on how you came up with the answers
- Question 1 Four stationary electric charges produce an electric field in space. The electric field depends on the magnitude of the test charge used to trace the field O has different magnitudes but same direction everywhere in space is constant everywhere in space has different magnitude and different directions everywhere in space CANADSuppose we've managed to set up an electric field that can be described by the function E→=w1y2i+w2z2j+w3x2k, where w1=8 N/(C⋅ m2), w2=9 N/(C⋅ m2), and w3=9 N/(C⋅ m2). Let's look at a rectangular box in the Cartesian coordinate axes, shown below, with dimensions a=2.5 m along the x-axis, b=6 m along the y-axis, c=4 m along the z-axis. What is the magnitude of the electric flux passing through the shaded area?The plane z = 0 marks the boundary between free space (z 0 side) with a relative permittivity of e, =35. The electric field intensity next to the interface in free space is Ē = –10£ + 25ŷ + 92 V/m. Determine the electric field intensity on the other side of the interface.
- A thin-walled, hollow, conducting cylinder with radius rb is concentric with a solid conducting cylinder with radius ra<rb. Each has length L. The two cylinders are attached by conducting wires to the terminals of a battery that supplies potential V. A solid cylindrical shell, with inner radius ra and outer radius R<rb, made of a material with dielectric constant K, slides between the conducting cylinders, as shown in (Figure 1). By changing the insertion distance x, we can alter the capacitance seen by the battery and therefore alter the amount of charge stored in this device. a)Determine the capacitance as a function of x. Express your answer in terms of the variables K, L, ra, rb, R, x, and constants ϵ0, π. b) If L = 12.0 cm, ra = 1.00 cm, rb = 4.00 cm, R = 3.00 cm, and K = 3.21, what is the capacitance when x = 0? c) What is the capacitance when x = L? d) What value of x results in 6.00 nC of charge on the positively charged cylinder plate when V = 1.00 kV?A simple and common technique for accelerating electrons is shown in the figure, which depicts a uniform electric field between two plates. Electrons are released, usually from a hot filament, near the negative plate, and there is a small hole in the positive plate that allows the electrons to pass through. Randomized Variables E = 2.7 × 104 N/C Calculate the horizontal component of the electron's acceleration if the field strength is 2.7 × 104 N/C. Express your answer in meters per second squared, and assume the electric field is pointing in the negative x-direction as shown in the figure.The picture on the right shows a plate capacitor. You may assume that the two plates are very large compared to the separation between the plates (i.e. you may treat them as 'infinite' planes). The plates are charged to ±Q, each plate has an area of A, and the plates are separated by a distance d. The x-axis in this problem is pointing from the negative to the positive plate, with the origin at the negative plate. The electric field at point 2 has a magnitude of E. E=3000 A=1 m² d = 8 mm c. What is the electric field strength at point 1? d. What is the charge Q on the plates? ·area A IT +Q €0=8.85 x 10-12 -a X=0 e. What is the electric field strength at point 3? Part A: a. In the picture, sketch the electric field between the plates by drawing the field lines. b. Find the surface charge density n on each plate. Nm² 12 x(mm)
- answer parts c and dFigure 3: 4. Positive charge is distributed uniformly over each of two spherical volumes with radius R. One sphere of charge is centered at the origin and the other at x' = 2R (see Figure 3). The magnitude and direction of the net electric field due to these two distributions of charge at the following points are: (a)x = 0: Ē = E1 + Ē2 = 0 (True,False) (b)x = 5: E = Ē1 + Ē2 = Ē = E1 + E2 = 4r€0 (2R)2 Q 4r€0 R3 Q (True,False) 4T€0 (R)2 (c)x = R: Rî (True,False) 4TE0 R3 4T€0 R2 E = E1 + Ē2 = E = E1 + E2 (d)x = 2R: Q i +0 (True,False) 4T€0 (2R)2 Ri + 4περ R3 - Ri (e)x = 3R: (True,False) 4περ (3R) 2An electron is projected with an initial speed v0 = 1.70×106 m/s into the uniform field between the parallel plates in (Figure 1). Assume that the field between the plates is uniform and directed vertically downward, and that the field outside the plates is zero. The electron enters the field at a point midway between the plates. If the electron just misses the upper plate as it emerges from the field, find the magnitude of the electric field. Express your answer in newtons per coulomb. Suppose that in the figure the electron is replaced by a proton with the same initial speed v0v0. Would the proton hit one of the plates? What would be the direction of proton's displacement? displacement is upward displacement is downward