A 0.0100 m diameter copper bus bar is maintained at a constant temperature of 20.0°C and is subjected to a voltage gradient of 1.00 V/m. Determine the Peltier heat flow, QP. The Seebeck coefficient for the copper is αcu = 3.50 × 10^−6 V/K, and its resistivity is ρe = 5.00 × 10^−9 ohm meters.

Question

A [latex]0.0100 ext{m}[/latex] diameter copper bus bar is maintained at a constant temperature of [latex]20.0° ext{C}[/latex] and is subjected to a voltage gradient of [latex]1.00 ext{V/m}[/latex]. Determine the Peltier heat flow, [latex]\dot{Q}_P[/latex]. The Seebeck coefficient for the copper is [latex]α_ ext{cu} = 3.50 × 10^{−6} ext{V/K}[/latex], and its resistivity is [latex]ρ_e = 5.00 × 10^{−9}[/latex] ohm meters.

Accepted Answer

The Peltier heat flow is given by Eq. (19.33) as

[latex]π = \frac{\dot{Q}_P}{I} = αT[/latex] (19.33)

[latex]\dot{Q}_P = πI = (αT)I[/latex]

where

[latex]I = AJ_E = \frac{A}{ρ_e} (- \frac{dϕ}{dx})[/latex]

Here, [latex]−dϕ/dx = ext{voltage gradient} = 1.00 ext{V/m}[/latex], so

[latex]I = \frac{(π/4) (0.0100 ext{m})^2 (1.00 ext{V/m})}{5.00 × 10^{−9} ext{Ω gm}} = 1.57 × 10^4 ext{V/Ω} = 1.57 × 10^4 ext{A}[/latex]

Then

[latex]\dot{Q}_P = (3.50 × 10^{−6} ext{V/K}) (20,0 + 273.16 ext{K}) (1.57 × 10^4 ext{A}) = 16.2 ext{V.A} = 16.2 ext{W}[/latex]

Question 19.1: A 0.0100 m diameter copper bus bar is maintained at a consta...

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