Explanation Given data: The infinite line charge with linear charge density ρ ℓ is along the z − axis. Calculation: Write the standard equation for the electric field intensity for the infinite line charge. E = r ^ ρ ℓ 2 π ε 0 r Here, E is the electric field intensity. r is the distance of the observational point from the charge element. ε 0 is the electrical permittivity. Write the standard relation for electric field and electric potential. V = − ∫ E ⋅ d l (1) Here, V is the electric potential. d l is the differential length. Write the standard expression for the differential length in cylindrical coordinates. d l = r ^ d r + ϕ ^ r d ϕ + z ^ d z Substitute r ^ d r + ϕ ^ r d ϕ + z ^ d z for d l and r ^ ρ ℓ 2 π ε 0 r for E in the equation (1). V = − ∫ r ^ ρ ℓ 2 π ε 0 r ⋅ ( r ^ d r + ϕ ^ r d ϕ + z ^ d z ) = − ∫ ρ ℓ 2 π ε 0 r d r Integrate the above equation from r = r 2 to r = r 1 to get the electric potential difference between two points in the air at the radial distance r 1 and r 2

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Chapter 4, Problem 33P

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The proof that the electric potential difference between two points in the air at the radial distance r1 and r2 for the given condition is V12=ρℓ2πε0lnr2r1.

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Chapter 4, Problem 32P

Chapter 4, Problem 34P

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Chapter 4 Solutions

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The proof that the electric potential difference between two points in the air at the radial distance r 1 and r 2 for the given condition is V 12 = ρ ℓ 2 π ε 0 ln r 2 r 1 .

Solution Summary: The author explains the electric potential difference between two points in the air at the radial distance r_1 and

The proof that the electric potential difference between two points in the air at the radial distance r1 and r2 for the given condition is V12=ρℓ2πε0lnr2r1.

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Chapter 4 Solutions