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3.A: Electric Potential (Answer)
https://phys.libretexts.org/Courses/Muhlenberg_College/Physics_122%3A_General_Physics_II_(Collett)/03%3A_Electric_Potential/3.A%3A_Electric_Potential_(Answer)
from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin...from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin and zero potential, with the positively charged plate located at +5mm in the z-direction, V=1.7×104VV=1.7×104Vso the potential is 0 for $\displaystyle z<0,1.7×10^4V(\frac{z}{5mm})$ for $\displaystyle 0≤z≤5mm,1.7×10^4V$ for $\displaystyle z>5mm;$
3.10: The Electric Potential (Answers)
https://phys.libretexts.org/Courses/Kettering_University/Electricity_and_Magnetism_with_Applications_to_Amateur_Radio_and_Wireless_Technology/03%3A_The_Electric_Potential/3.10%3A_The_Electric_Potential_(Answers)
from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin...from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin and zero potential, with the positively charged plate located at +5mm in the z-direction, V=1.7×104VV=1.7×104Vso the potential is 0 for $\displaystyle z<0,1.7×10^4V(\frac{z}{5mm})$ for $\displaystyle 0≤z≤5mm,1.7×10^4V$ for $\displaystyle z>5mm;$
4.8: Potential and Field Relationships (Answers)
https://phys.libretexts.org/Courses/Kettering_University/Electricity_and_Magnetism_with_Applications_to_Amateur_Radio_and_Wireless_Technology/04%3A_Potential_and_Field_Relationships/4.08%3A_Potential_and_Field_Relationships_(Answers)
from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin...from the previous chapter, the electric field has magnitude $\displaystyle \frac{σ}{ε_0}$ in the region between the plates and zero outside; defining the negatively charged plate to be at the origin and zero potential, with the positively charged plate located at +5mm in the z-direction, V=1.7×104VV=1.7×104Vso the potential is 0 for $\displaystyle z<0,1.7×10^4V(\frac{z}{5mm})$ for $\displaystyle 0≤z≤5mm,1.7×10^4V$ for $\displaystyle z>5mm;$

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