College Physics
College Physics
11th Edition
ISBN: 9781305952300
Author: Raymond A. Serway, Chris Vuille
Publisher: Cengage Learning
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Chapter 18, Problem 43P

Assume a length of axon membrane of about 0.10 m is excited by an action potential (length excited = nerve speed × pulse duration = 50.0 m/s × 2.0 × 10−3 s = 0.10 m). In the resting state, the outer surface of the axon wall is charged positively with K+ ions and the inner wall has an equal and opposite charge of negative organic ions, as shown in Figure P18.43. Model the axon as a parallel-plate capacitor and take C = κϵ0A/d and Q = C ΔV to investigate the charge as follows. Use typical values for a cylindrical axon of cell wall thickness d = 1.0 × 10−8 m, axon radius r = 1.0 × 101 μm, and cell-wall dielectric constant κ = 3.0. (a) Calculate the positive charge on the outside of a 0.10-m piece of axon when it is not conducting an electric pulse. How many K+ ions are on the outside of the axon assuming an initial potential difference of 7.0 × 10−2 V? Is this a large charge per unit area? Hint: Calculate the charge per unit area in terms of electronic charge e per squared (Å2). An atom has a cross section of about 1 Å2 (1 Å = 10−10 m). (b) How much positive charge must flow through the cell membrane to reach the excited state of + 3.0 × 10−2 V from the resting state of −7.0 × 10−2 V? How many sodium ions (Na+) is this? (c) If it takes 2.0 ms for the Na+ ions to enter the axon, what is the average current in the axon wall in this process? (d) How much energy does it take to raise the potential of the inner axon wall to + 3.0 × 10−2 V, starting from the resting potential of −7.0 × 10−2 V?

Chapter 18, Problem 43P, Assume a length of axon membrane of about 0.10 m is excited by an action potential (length excited =

Figure P18.43 Problem 43 and 44.

(a)

Expert Solution
Check Mark
To determine
The positive charge on the outside of axon piece and number of K+ ions.

Answer to Problem 43P

The positive charge on the outside of axon piece is 1.2×109C . The number of K+ ions is 7.5×109 .

Explanation of Solution

Given info: The length of the axon membrane (l) is 0.10 m. Thickness of the cell wall is d=1.0×108m . Radius of the axon is r=1.0×101μm . The cell wall dielectric constant is κ=3 . The initial potential difference is 7.0×102V .

Explanation:

Formula to calculate the charge is,

Q=C(ΔV)

  • C is the capacitance.
  • ΔV is the potential difference.

Formula to calculate the capacitance is,

C=κε0Ad

  • ε0 is the permittivity of free space.
  • A is the cross sectional area.

The area A is given by,

A=2πrl

From the above equations,

Q=(κ2πε0rld)(ΔV)

Substitute 8.85×1012m3kg1s4A2 for ε0 , 1.0×101μm for r, 3 for κ , 0.10 m for l and 7.0×102V for ΔV .

Q=(3)(8.85×1012m3kg1s4A2)(2π1.0×108m)(1.0×101μm)(0.10m)(7.0×102V)=(3)(8.85×1012m3kg1s4A2)(2π1.0×108m)(10×106m)(0.10m)(7.0×102V)=1.2×109C

Formula to calculate the number of K+ ions is,

n=Qe

  • e is the elementary charge.

Substitute 1.2×109C for Q and 1.6×1019C for e.

n=1.2×109C1.6×1019C=7.5×109

The corresponding charge per unit area is low. This is because the magnitude of charge is very less.

Conclusion:

The positive charge on the outside of axon piece is 1.2×109C . The number of K+ ions is 7.5×109

(b)

Expert Solution
Check Mark
To determine
The positive charge on the outside of axon piece and number of Na+ ions at the excited state.

Answer to Problem 43P

The positive charge on the outside of axon piece is 1.7×109C . The number of Na+ ions is 1.0×1010 .

Explanation of Solution

Given info: The length of the axon membrane (l) is 0.10 m. Thickness of the cell wall is d=1.0×108m . Radius of the axon is r=1.0×101μm . The cell wall dielectric constant is κ=3 . The potential difference of the excited state is 3.0×102V .

Explanation:

From (a),

Q'=(κ2πε0rld)(ΔV)

The total positive charge that passes through membrane is,

ΔQ=Q'Q

Therefore,

ΔQ=(κ2πε0rld)(ΔV)Q

Substitute 1.2×109C for Q, 8.85×1012m3kg1s4A2 for ε0 , 1.0×101μm for r, 3 for κ , 0.10 m for l and 3.0×102V for ΔV .

ΔQ=(3)(8.85×1012m3kg1s4A2)(2π1.0×108m)(1.0×101μm)(0.10m)(3.0×102V)(1.2×109C)=(3)(8.85×1012m3kg1s4A2)(2π1.0×108m)(10×106m)(0.10m)(3.0×102V)(1.2×109C)=1.7×109C

Formula to calculate the number of Na+ ions is,

n=ΔQe

Substitute 1.7×109C for ΔQ and 1.6×1019C for e.

n=1.7×109C1.6×1019C=1.0×1010

The corresponding charge per unit area is low. This is because the magnitude of charge is very less.

Conclusion:

The positive charge on the outside of axon piece is 1.7×109C . The number of Na+ ions is 1.0×1010 .

(c)

Expert Solution
Check Mark
To determine
The average current in the axon wall.

Answer to Problem 43P

The average current in the axon wall is 0.83μA .

Explanation of Solution

Given info: The length of the axon membrane (l) is 0.10 m. Thickness of the cell wall is d=1.0×108m . Radius of the axon is r=1.0×101μm . The cell wall dielectric constant is κ=3 . The potential difference of the excited state is 3.0×102V . Time taken for the Na+ ions to enter the axon is ( Δt ) 2.0 ms.

Explanation:

Formula to calculate the average current is,

I=ΔQΔt

Substitute 1.7×109C for ΔQ and 2.0 ms for Δt .

I=1.7×109C2.0ms=1.7×109C2.0×103s=8.3×107A=0.83μA

Conclusion:

The average current in the axon wall is 0.83μA .

(d)

Expert Solution
Check Mark
To determine
The energy required.

Answer to Problem 43P

The energy required is 7.5×1012J .

Explanation of Solution

Given info: The length of the axon membrane (l) is 0.10 m. Thickness of the cell wall is d=1.0×108m . Radius of the axon is r=1.0×101μm . The cell wall dielectric constant is κ=3 . The potential difference of the excited state is 3.0×102V . Time taken for the Na+ ions to enter the axon is ( Δt ) 2.0 ms.

Explanation:

Formula to calculate the energy required is,

E=12C(ΔV)2

From the (a),

C=κ2πε0rld

Therefore,

E=12(κ2πε0rld)(ΔV)2=(κπε0rld)(ΔV)2

Substitute 8.85×1012m3kg1s4A2 for ε0 , 1.0×101μm for r, 3 for κ , 0.10 m for l and 3.0×102V for ΔV .

E=(3)(8.85×1012m3kg1s4A2)(π1.0×108m)(1.0×101μm)(0.10m)(3.0×102V)2=(3)(8.85×1012m3kg1s4A2)(π1.0×108m)(10×106m)(0.10m)(3.0×102V)2=7.5×1012J

Conclusion:

The energy required is 7.5×1012J .

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