A d The two charges in a given Figure are separated by a distance d = 9.8 cm, and Q = 8 nC. Find (a) the electric potential VA = V at A, (b) the electric potential VB = V at B, and (c) the electric potential difference VB - VA V between B and A.
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- A moving particle encounters an external electric field that decreases its kinetic energy from 9450 eV to 6990 eV as the particle moves from position A to position B. The electric potential at A is -43.0 V, and that at B is +39.0 V. Determine the charge of the particle. Include the algebraic sign (+ or -) with your answer. Number i Units Lower potential Higher potential VB E SUBROLFind the potential at points P₁, P2, P3, and P4 in the diagram due to the two given charges. PA 4 + +5 mC -4 cm Hint P₁ Figure Description a. Potential at P₁ = b. Potential at P₂ c. Potential at P3 = d. Potential at P₁ = = T 3 cm 2 cm- P31 -2 cm 3 cm 4 cm P2 V V V V 4 -10 MC (Yes, these numbers are quite large because even one millicoulomb is quite a large amount of charge. Use the "E" notation to enter your answers in scientific notation, if necessary, e.g. "3.14E12" for 3.14 × 10¹².)5. A 4.0-nm-diameter protein is in a 0.05 M KCl solution at 25°C. The protein has 9 positive and 20 negative charges. Model the protein as a sphere with a uniform surface charge density. What is the electric potential of the protein (a) at the surface and (b) 2.0 nm from the surface?
- The two charges in Figure P16.16 are separated by d = 2.00 cm. Find the electric potential d at (a) point A and (b) point B, which is halfway between the charges. 60.0° B --15.0 nC 27.0 nCWhich of the following is true regarding the potential given the electric field of a single point charge in vacuum? O The electric potential does not change even if it gets farther from the point charge. The electric potential decreases in magnitude as it gets farther from the point charge. The electric potential increases in magnitude as it gets farther from the point charge. O We have insufficient information to comment on the electric potential.The electric potential increases from 100 V to 800 V from the bottom plate to the top plate of a parallel-plate capacitor. a. What is the magnitude of the change in potential energy of a −3 × 10^−4 C charge that is moved from the bottom plate to the top plate? b. Does the potential energy increase or decrease in this process?