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Making connections: take-home investigation—filament observations

Find a lightbulb with a filament. Look carefully at the filament and describe its structure. To what points is the filament connected?

Note that simple drift velocity is not the entire story. The speed of an electron is much greater than its drift velocity. In addition, not all of the electrons in a conductor can move freely, and those that do might move somewhat faster or slower than the drift velocity. So what do we mean by free electrons? Atoms in a metallic conductor are packed in the form of a lattice structure. Some electrons are far enough away from the atomic nuclei that they do not experience the attraction of the nuclei as much as the inner electrons do. These are the free electrons. They are not bound to a single atom but can instead move freely among the atoms in a “sea” of electrons. These free electrons respond by accelerating when an electric field is applied. Of course as they move they collide with the atoms in the lattice and other electrons, generating thermal energy, and the conductor gets warmer. In an insulator, the organization of the atoms and the structure do not allow for such free electrons.

Section summary

  • Electric current I size 12{I } {} is the rate at which charge flows, given by
    I = Δ Q Δ t ,
    where Δ Q is the amount of charge passing through an area in time Δ t .
  • The direction of conventional current is taken as the direction in which positive charge moves.
  • The SI unit for current is the ampere (A), where 1 A = 1 C/s. size 12{1" A "=" 1 C/s."} {}
  • Current is the flow of free charges, such as electrons and ions.
  • Drift velocity v d size 12{v rSub { size 8{d} } } {} is the average speed at which these charges move.
  • Electrical signals travel at speeds about 10 12 size 12{"10" rSup { size 8{"12"} } } {} times greater than the drift velocity of free electrons.

Conceptual questions

Can a wire carry a current and still be neutral—that is, have a total charge of zero? Explain.

Car batteries are rated in ampere-hours ( A h size 12{A cdot h} {} ). To what physical quantity do ampere-hours correspond (voltage, charge, . . .), and what relationship do ampere-hours have to energy content?

Why are two conducting paths from a voltage source to an electrical device needed to operate the device?

In cars, one battery terminal is connected to the metal body. How does this allow a single wire to supply current to electrical devices rather than two wires?

Why isn’t a bird sitting on a high-voltage power line electrocuted? Contrast this with the situation in which a large bird hits two wires simultaneously with its wings.

Problems&Exercises

What is the current in milliamperes produced by the solar cells of a pocket calculator through which 4.00 C of charge passes in 4.00 h?

0.278 mA

A total of 600 C of charge passes through a flashlight in 0.500 h. What is the average current?

What is the current when a typical static charge of 0 . 250 μ C size 12{0 "." "250" mC} {} moves from your finger to a metal doorknob in 1.00 μ s size 12{1 "." "00" ms} {} ?

0.250 A

Find the current when 2.00 nC jumps between your comb and hair over a 0 . 500 - μ s size 12{0 "." "500"-μs} {} time interval.

A large lightning bolt had a 20,000-A current and moved 30.0 C of charge. What was its duration?

1.50ms

The 200-A current through a spark plug moves 0.300 mC of charge. How long does the spark last?

(a) A defibrillator sends a 6.00-A current through the chest of a patient by applying a 10,000-V potential as in the figure below. What is the resistance of the path? (b) The defibrillator paddles make contact with the patient through a conducting gel that greatly reduces the path resistance. Discuss the difficulties that would ensue if a larger voltage were used to produce the same current through the patient, but with the path having perhaps 50 times the resistance. (Hint: The current must be about the same, so a higher voltage would imply greater power. Use this equation for power: P = I 2 R size 12{P = I rSup { size 8{2} } R} {} .)

Figure represents a defibrillation unit used on a patient. The circuit is also represented. It shows a capacitor driving a current through the chest of a patient. The opposite plates of the capacitor are marked as positive Q and negative Q. The direction of current in the connecting wires from the capacitor to the defibrillation unit is shown in a clockwise direction with an arrow on the wire, and the direction of electrons is shown opposite to this direction with an arrow.
The capacitor in a defibrillation unit drives a current through the heart of a patient.

(a) 1 . 67 k Ω size 12{1 "." "67"" k" %OMEGA } {}

(b) If a 50 times larger resistance existed, keeping the current about the same, the power would be increased by a factor of about 50 (based on the equation P = I 2 R size 12{P = I rSup { size 8{2} } R} {} ), causing much more energy to be transferred to the skin, which could cause serious burns. The gel used reduces the resistance, and therefore reduces the power transferred to the skin.

During open-heart surgery, a defibrillator can be used to bring a patient out of cardiac arrest. The resistance of the path is 5 00 Ω size 12{5"00 " %OMEGA } {} and a 10.0-mA current is needed. What voltage should be applied?

(a) A defibrillator passes 12.0 A of current through the torso of a person for 0.0100 s. How much charge moves? (b) How many electrons pass through the wires connected to the patient? (See figure two problems earlier.)

(a) 0.120 C

(b) 7 . 50 × 10 17 electrons size 12{7 "." "50"´"10" rSup { size 8{"17"} } " electrons"} {}

A clock battery wears out after moving 10,000 C of charge through the clock at a rate of 0.500 mA. (a) How long did the clock run? (b) How many electrons per second flowed?

The batteries of a submerged non-nuclear submarine supply 1000 A at full speed ahead. How long does it take to move Avogadro’s number ( 6 . 02 × 10 23 size 12{6 "." "02"´"10" rSup { size 8{"23"} } } {} ) of electrons at this rate?

96.3 s

Electron guns are used in X-ray tubes. The electrons are accelerated through a relatively large voltage and directed onto a metal target, producing X-rays. (a) How many electrons per second strike the target if the current is 0.500 mA? (b) What charge strikes the target in 0.750 s?

A large cyclotron directs a beam of He ++ size 12{"He" rSup { size 8{"++"} } } {} nuclei onto a target with a beam current of 0.250 mA. (a) How many He ++ size 12{"He" rSup { size 8{"++"} } } {} nuclei per second is this? (b) How long does it take for 1.00 C to strike the target? (c) How long before 1.00 mol of He ++ size 12{"He" rSup { size 8{"++"} } } {} nuclei strike the target?

(a) 7.81 × 10 14 He ++ nuclei/s

(b) 4.00 × 10 3 s

(c) 7.71 × 10 8 s

Practice Key Terms 3

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Source:  OpenStax, Abe advanced level physics. OpenStax CNX. Jul 11, 2013 Download for free at http://legacy.cnx.org/content/col11534/1.3
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