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Capacitors and Dielectrics

Module by: OpenStax College. E-mail the author

Summary:

  • Describe the action of a capacitor and define capacitance.
  • Explain parallel plate capacitors and their capacitances.
  • Discuss the process of increasing the capacitance of a dielectric.
  • Determine capacitance given charge and voltage.

Note: You are viewing an old version of this document. The latest version is available here.

A capacitor is a device used to store electric charge. Capacitors have applications ranging from filtering static out of radio reception to energy storage in heart defibrillators. Typically, commercial capacitors have two conducting parts close to one another, but not touching, such as those in Figure 1. (Most of the time an insulator is used between the two plates to provide separation—see the discussion on dielectrics below.) When battery terminals are connected to an initially uncharged capacitor, equal amounts of positive and negative charge, +Q+Q size 12{Q} {} and QQ size 12{Q} {}, are separated into its two plates. The capacitor remains neutral overall, but we refer to it as storing a charge QQ size 12{Q} {} in this circumstance.

Capacitor:

A capacitor is a device used to store electric charge.

Figure 1: Both capacitors shown here were initially uncharged before being connected to a battery. They now have separated charges of +Q+Q size 12{Q} {} and QQ size 12{Q} {} on their two halves. (a) A parallel plate capacitor. (b) A rolled capacitor with an insulating material between its two conducting sheets.
Part a of the figure shows a charged parallel plate capacitor and part b of the figure shows a charged rolled capacitor. In the parallel plate capacitor, two rectangular plates are kept vertically facing each other separated by a distance d. These two plates are the conducting parts of the capacitor. One plate is connected to the positive terminal of the battery, and the other is connected to the negative terminal of the battery. One plate has a positive charge, plus Q, and the other plate has a negative charge, negative Q. The rolled capacitor has conducting parts in the form of a spiral coil. Between the two conducting parts is insulating material, also in the form of a coil. The conducting and insulating materials of the capacitor are rolled together to form a spiral. The outer conducting coil is connected to the positive terminal of the battery, and the inner coil is connected to the negative terminal of the battery.

The amount of charge QQ size 12{Q} {} a capacitor can store depends on two major factors—the voltage applied and the capacitor’s physical characteristics, such as its size.

The Amount of Charge QQ size 12{Q} {} a Capacitor Can Store:

The amount of charge QQ size 12{Q} {} a capacitor can store depends on two major factors—the voltage applied and the capacitor’s physical characteristics, such as its size.

A system composed of two identical, parallel conducting plates separated by a distance, as in Figure 2, is called a parallel plate capacitor. It is easy to see the relationship between the voltage and the stored charge for a parallel plate capacitor, as shown in Figure 2. Each electric field line starts on an individual positive charge and ends on a negative one, so that there will be more field lines if there is more charge. (Drawing a single field line per charge is a convenience, only. We can draw many field lines for each charge, but the total number is proportional to the number of charges.) The electric field strength is, thus, directly proportional to QQ size 12{Q} {}.

Figure 2: Electric field lines in this parallel plate capacitor, as always, start on positive charges and end on negative charges. Since the electric field strength is proportional to the density of field lines, it is also proportional to the amount of charge on the capacitor.
Two metal plates are positioned vertically facing each other. The plates are the conducting parts of a capacitor. The plate on the left-hand side is connected to the positive terminal of a battery, and the plate on the right-hand side is connected to the negative terminal of the battery. There is an electric field between the two plates of the capacitor. The electric field lines emanate from the positively charged plate and end on the negatively charged plate. The electric field E is proportional to the charge Q.

The field is proportional to the charge:

EQ,EQ, size 12{E prop Q} {}
(1)

where the symbol size 12{prop} {} means “proportional to.” From the discussion in Electric Potential in a Uniform Electric Field, we know that the voltage across parallel plates is V=EdV=Ed size 12{V= ital "Ed"} {}. Thus,

VE.VE. size 12{V prop E} {}
(2)

It follows, then, that V ∝QV ∝Q size 12{Va`Q} {}, and conversely,

QV.QV. size 12{Q prop V} {}
(3)

This is true in general: The greater the voltage applied to any capacitor, the greater the charge stored in it.

Different capacitors will store different amounts of charge for the same applied voltage, depending on their physical characteristics. We define their capacitance CC size 12{C} {} to be such that the charge QQ size 12{C} {} stored in a capacitor is proportional to CC size 12{C} {}. The charge stored in a capacitor is given by

Q = CV . Q = CV . size 12{Q= ital "CV"} {}
(4)

This equation expresses the two major factors affecting the amount of charge stored. Those factors are the physical characteristics of the capacitor, CC size 12{C} {}, and the voltage, VV. Rearranging the equation, we see that capacitance CC size 12{C} {} is the amount of charge stored per volt, or

C=QV.C=QV. size 12{C=Q/V} {}
(5)

Capacitance:

Capacitance CC size 12{C} {} is the amount of charge stored per volt, or

C=QV.C=QV. size 12{C=Q/V} {}
(6)

The unit of capacitance is the farad (F), named for Michael Faraday (1791–1867), an English scientist who contributed to the fields of electromagnetism and electrochemistry. Since capacitance is charge per unit voltage, we see that a farad is a coulomb per volt, or

1 F=1 C1 V.1 F=1 C1 V. size 12{F= { {"1 C"} over {"1 V"} } } {}
(7)

A 1-farad capacitor would be able to store 1 coulomb (a very large amount of charge) with the application of only 1 volt. One farad is, thus, a very large capacitance. Typical capacitors range from fractions of a picofarad 1 pF=10–12 F1 pF=10–12 F size 12{ left (1" pF"="10" rSup { size 8{-"12"} } " F" right )} {} to millifarads 1 mF=10–3 F1 mF=10–3 F size 12{ left (1" mF"="10" rSup { size 8{-3} } " F" right )} {}.

Figure 3 shows some common capacitors. Capacitors are primarily made of ceramic, glass, or plastic, depending upon purpose and size. Insulating materials, called dielectrics, are commonly used in their construction, as discussed below.

Figure 3: Some typical capacitors. Size and value of capacitance are not necessarily related. (credit: Windell Oskay)
There are various types of capacitors with varying shapes and color. Some are cylindrical in shape, some circular in shape, some rectangular in shape, with two strands of wire coming out of each.

Parallel Plate Capacitor

The parallel plate capacitor shown in Figure 4 has two identical conducting plates, each having a surface area AA size 12{A} {}, separated by a distance dd size 12{d} {} (with no material between the plates). When a voltage VV size 12{V} {} is applied to the capacitor, it stores a charge QQ size 12{Q} {}, as shown. We can see how its capacitance depends on AA size 12{A} {} and dd size 12{d} {} by considering the characteristics of the Coulomb force. We know that like charges repel, unlike charges attract, and the force between charges decreases with distance. So it seems quite reasonable that the bigger the plates are, the more charge they can store—because the charges can spread out more. Thus CC size 12{C} {} should be greater for larger AA size 12{A} {}. Similarly, the closer the plates are together, the greater the attraction of the opposite charges on them. So CC size 12{C} {} should be greater for smaller dd size 12{d} {}.

Figure 4: Parallel plate capacitor with plates separated by a distance dd size 12{d} {}. Each plate has an area AA size 12{A} {}.
Two parallel plates are placed facing each other. The area of each plate is A, and the distance between the plates is d. The plate on the left is connected to the positive terminal of the battery, and the plate on the right is connected to the negative terminal of the battery.

It can be shown that for a parallel plate capacitor there are only two factors (AA size 12{A} {} and dd size 12{d} {}) that affect its capacitance CC size 12{C} {}. The capacitance of a parallel plate capacitor in equation form is given by

C = ε 0 A d . C = ε 0 A d . size 12{C=e rSub { size 8{0} } A/d} {}
(8)

Capacitance of a Parallel Plate Capacitor:

C = ε 0 A d C = ε 0 A d size 12{C=e rSub { size 8{0} } A/d} {}
(9)

AA size 12{A} {} is the area of one plate in square meters, and d d is the distance between the plates in meters. The constant ε 0 ε 0 is the permittivity of free space; its numerical value in SI units is ε 0 = 8.85 × 10 12 F/m ε 0 = 8.85 × 10 12 F/m . The units of F/m are equivalent to C2/N·m2C2/N·m2 size 12{ left (C rSup { size 8{2} } "/N" cdot m rSup { size 8{2} } right )} {}. The small numerical value of ε0ε0 size 12{e rSub { size 8{0} } } {} is related to the large size of the farad. A parallel plate capacitor must have a large area to have a capacitance approaching a farad. (Note that the above equation is valid when the parallel plates are separated by air or free space. When another material is placed between the plates, the equation is modified, as discussed below.)

Example 1: Capacitance and Charge Stored in a Parallel Plate Capacitor

(a) What is the capacitance of a parallel plate capacitor with metal plates, each of area 1.00m21.00m2 size 12{m rSup { size 8{2} } } {}, separated by 1.00 mm? (b) What charge is stored in this capacitor if a voltage of 3.00 × 10 3 V 3.00 × 10 3 V is applied to it?

Strategy

Finding the capacitance CC size 12{C} {} is a straightforward application of the equation C=ε0A/dC=ε0A/d size 12{C=e rSub { size 8{0} } A/d} {}. Once CC size 12{C} {} is found, the charge stored can be found using the equation Q=CVQ=CV size 12{Q= ital "CV"} {}.

Solution for (a)

Entering the given values into the equation for the capacitance of a parallel plate capacitor yields

C = ε 0 A d = 8.85 × 10 –12 F m 1.00 m 2 1.00 × 10 –3 m = 8.85 × 10 –9 F=8.85 nF. C = ε 0 A d = 8.85 × 10 –12 F m 1.00 m 2 1.00 × 10 –3 m = 8.85 × 10 –9 F=8.85 nF.
(10)

Discussion for (a)

This small value for the capacitance indicates how difficult it is to make a device with a large capacitance. Special techniques help, such as using very large area thin foils placed close together.

Solution for (b)

The charge stored in any capacitor is given by the equation Q=CVQ=CV size 12{Q= ital "CV"} {}. Entering the known values into this equation gives

Q = CV = 8.85 × 10 –9 F 3.00 × 10 3 V = 26.6 μC. Q = CV = 8.85 × 10 –9 F 3.00 × 10 3 V = 26.6 μC. alignl { stack { size 12{Q= ital "CV"= left (8 "." "85"´"10" rSup { size 8{-9} } " F" right ) left (3 "." "00"´"10" rSup { size 8{3} } " V" right )} {} # ="26" "." 6 µC "." {} } } {}
(11)

Discussion for (b)

This charge is only slightly greater than those found in typical static electricity. Since air breaks down at about 3.00×106V/m3.00×106V/m size 12{3 "." "00" times "10" rSup { size 8{6} } } {}, more charge cannot be stored on this capacitor by increasing the voltage.

Another interesting biological example dealing with electric potential is found in the cell’s plasma membrane. The membrane sets a cell off from its surroundings and also allows ions to selectively pass in and out of the cell. There is a potential difference across the membrane of about –70 mV –70 mV . This is due to the mainly negatively charged ions in the cell and the predominance of positively charged sodium ( Na + Na + ) ions outside. Things change when a nerve cell is stimulated. Na + Na + ions are allowed to pass through the membrane into the cell, producing a positive membrane potential—the nerve signal. The cell membrane is about 7 to 10 nm thick. An approximate value of the electric field across it is given by

E= V d = –70 × 10 –3 V 8 × 10 –9 m =–9×106V/m. E= V d = –70 × 10 –3 V 8 × 10 –9 m =–9×106V/m. size 12{E=V/d"=-""70"´"10" rSup { size 8{-3} } V/ left (8´"10" rSup { size 8{-9} } m right )"=-"9´"10" rSup { size 8{+6} } "V/m"} {}
(12)

This electric field is enough to cause a breakdown in air.

Dielectric

The previous example highlights the difficulty of storing a large amount of charge in capacitors. If dd size 12{d} {} is made smaller to produce a larger capacitance, then the maximum voltage must be reduced proportionally to avoid breakdown (since E=V/dE=V/d size 12{E=V/d} {}). An important solution to this difficulty is to put an insulating material, called a dielectric, between the plates of a capacitor and allow d d size 12{d} {} to be as small as possible. Not only does the smaller dd size 12{d} {} make the capacitance greater, but many insulators can withstand greater electric fields than air before breaking down.

There is another benefit to using a dielectric in a capacitor. Depending on the material used, the capacitance is greater than that given by the equation C=ε0AdC=ε0Ad size 12{C=e rSub { size 8{0} } { {A} over {d} } } {} by a factor κκ size 12{k} {}, called the dielectric constant. A parallel plate capacitor with a dielectric between its plates has a capacitance given by

C=κε0Ad(parallel plate capacitor with dielectric).C=κε0Ad(parallel plate capacitor with dielectric). size 12{C= ital "ke" rSub { size 8{0} } A/d} {}
(13)

Values of the dielectric constant κκ size 12{k} {} for various materials are given in Table 1. Note that κκ size 12{k} {} for vacuum is exactly 1, and so the above equation is valid in that case, too. If a dielectric is used, perhaps by placing Teflon between the plates of the capacitor in Example 1, then the capacitance is greater by the factor κκ size 12{k} {}, which for Teflon is 2.1.

Take-Home Experiment—Building a Capacitor:

How large a capacitor can you make using a chewing gum wrapper? The plates will be the aluminum foil, and the separation (dielectric) in between will be the paper.

Table 1: Dielectric Constants and Dielectric Strengths for Various Materials at 20ºC
Material Dielectric constant κκ size 12{?} {} Dielectric strength (V/m)
Vacuum 1.00000
Air 1.00059 3 × 10 6 3 × 10 6
Bakelite 4.9 24 × 10 6 24 × 10 6 size 12{"24" times "10" rSup { size 8{6} } } {}
Fused quartz 3.78 8 × 10 6 8 × 10 6 size 12{8 times "10" rSup { size 8{6} } } {}
Neoprene rubber 6.7 12 × 10 6 12 × 10 6 size 12{"12" times "10" rSup { size 8{6} } } {}
Nylon 3.4 14 × 10 6 14 × 10 6 size 12{"14" times "10" rSup { size 8{6} } } {}
Paper 3.7 16 × 10 6 16 × 10 6 size 12{"16" times "10" rSup { size 8{6} } } {}
Polystyrene 2.56 24 × 10 6 24 × 10 6 size 12{"24" times "10" rSup { size 8{6} } } {}
Pyrex glass 5.6 14 × 10 6 14 × 10 6 size 12{"14" times "10" rSup { size 8{6} } } {}
Silicon oil 2.5 15 × 10 6 15 × 10 6 size 12{"15" times "10" rSup { size 8{6} } } {}
Strontium titanate 233 8 × 10 6 8 × 10 6 size 12{8 times "10" rSup { size 8{6} } } {}
Teflon 2.1 60 × 10 6 60 × 10 6 size 12{"60" times "10" rSup { size 8{6} } } {}
Water 80

Note also that the dielectric constant for air is very close to 1, so that air-filled capacitors act much like those with vacuum between their plates except that the air can become conductive if the electric field strength becomes too great. (Recall that E=V/dE=V/d size 12{E=V/d} {} for a parallel plate capacitor.) Also shown in Table 1 are maximum electric field strengths in V/m, called dielectric strengths, for several materials. These are the fields above which the material begins to break down and conduct. The dielectric strength imposes a limit on the voltage that can be applied for a given plate separation. For instance, in Example 1, the separation is 1.00 mm, and so the voltage limit for air is

V = E d = ( 3 × 10 6 V/m ) ( 1 . 00 × 10 3 m ) = 3000 V. V = E d = ( 3 × 10 6 V/m ) ( 1 . 00 × 10 3 m ) = 3000 V.
(14)

However, the limit for a 1.00 mm separation filled with Teflon is 60,000 V, since the dielectric strength of Teflon is 60×10660×106 size 12{"60" times "10" rSup { size 8{6} } } {} V/m. So the same capacitor filled with Teflon has a greater capacitance and can be subjected to a much greater voltage. Using the capacitance we calculated in the above example for the air-filled parallel plate capacitor, we find that the Teflon-filled capacitor can store a maximum charge of

Q = CV = κC air V = ( 2.1 ) ( 8.85 nF ) ( 6.0 × 10 4 V ) = 1.1 mC . Q = CV = κC air V = ( 2.1 ) ( 8.85 nF ) ( 6.0 × 10 4 V ) = 1.1 mC .
(15)

This is 42 times the charge of the same air-filled capacitor.

Dielectric Strength:

The maximum electric field strength above which an insulating material begins to break down and conduct is called its dielectric strength.

Microscopically, how does a dielectric increase capacitance? Polarization of the insulator is responsible. The more easily it is polarized, the greater its dielectric constant κκ size 12{k} {}. Water, for example, is a polar molecule because one end of the molecule has a slight positive charge and the other end has a slight negative charge. The polarity of water causes it to have a relatively large dielectric constant of 80. The effect of polarization can be best explained in terms of the characteristics of the Coulomb force. Figure 5 shows the separation of charge schematically in the molecules of a dielectric material placed between the charged plates of a capacitor. The Coulomb force between the closest ends of the molecules and the charge on the plates is attractive and very strong, since they are very close together. This attracts more charge onto the plates than if the space were empty and the opposite charges were a distance dd size 12{d} {} away.

Figure 5: (a) The molecules in the insulating material between the plates of a capacitor are polarized by the charged plates. This produces a layer of opposite charge on the surface of the dielectric that attracts more charge onto the plate, increasing its capacitance. (b) The dielectric reduces the electric field strength inside the capacitor, resulting in a smaller voltage between the plates for the same charge. The capacitor stores the same charge for a smaller voltage, implying that it has a larger capacitance because of the dielectric.
(a) A dielectric is between the two plates of a parallel plate capacitor. A diagram shows the molecules that make up the dielectric. The molecules are polarized by the charged plates. The positive ends of the molecules are attracted toward the negatively charged plate of the capacitor and hence are oriented toward the right. The negative ends of the molecules are attracted toward the positively charged plate of the capacitor and hence are oriented toward the left. (b) There is a dielectric material between the two plates of the capacitor. Since the charged ends of the molecules are oriented toward the capacitor plates, there is reduced field strength inside the capacitor, resulting in a smaller voltage between the plates for the same charge.

Another way to understand how a dielectric increases capacitance is to consider its effect on the electric field inside the capacitor. Figure 5(b) shows the electric field lines with a dielectric in place. Since the field lines end on charges in the dielectric, there are fewer of them going from one side of the capacitor to the other. So the electric field strength is less than if there were a vacuum between the plates, even though the same charge is on the plates. The voltage between the plates is V=EdV=Ed size 12{V= ital "Ed"} {}, so it too is reduced by the dielectric. Thus there is a smaller voltage VV size 12{V} {} for the same charge QQ size 12{Q} {}; since C=Q/VC=Q/V size 12{C=Q/V} {}, the capacitance CC size 12{C} {} is greater.

The dielectric constant is generally defined to be κ=E0/Eκ=E0/E size 12{k=E rSub { size 8{0} } /E} {}, or the ratio of the electric field in a vacuum to that in the dielectric material, and is intimately related to the polarizability of the material.

Things Great and Small:

The Submicroscopic Origin of Polarization

Polarization is a separation of charge within an atom or molecule. As has been noted, the planetary model of the atom pictures it as having a positive nucleus orbited by negative electrons, analogous to the planets orbiting the Sun. Although this model is not completely accurate, it is very helpful in explaining a vast range of phenomena and will be refined elsewhere, such as in Atomic Physics. The submicroscopic origin of polarization can be modeled as shown in Figure 6.

Figure 6: Artist’s conception of a polarized atom. The orbits of electrons around the nucleus are shifted slightly by the external charges (shown exaggerated). The resulting separation of charge within the atom means that it is polarized. Note that the unlike charge is now closer to the external charges, causing the polarization.
The top part of the figure shows what an unpolarized atom would look like if the electrons moved along a circular path around the positively charged nucleus. Next, when there is an external negative and a positive charge, the electrons are attracted toward the positive external charge and the nucleus is attracted toward the negative external charge. The circular orbit of the electrons becomes an ellipse due to the pull of the external charges.

We will find in Atomic Physics that the orbits of electrons are more properly viewed as electron clouds with the density of the cloud related to the probability of finding an electron in that location (as opposed to the definite locations and paths of planets in their orbits around the Sun). This cloud is shifted by the Coulomb force so that the atom on average has a separation of charge. Although the atom remains neutral, it can now be the source of a Coulomb force, since a charge brought near the atom will be closer to one type of charge than the other.

Some molecules, such as those of water, have an inherent separation of charge and are thus called polar molecules. Figure 7 illustrates the separation of charge in a water molecule, which has two hydrogen atoms and one oxygen atom H2OH2O size 12{ left (H rSub { size 8{2} } O right )} {}. The water molecule is not symmetric—the hydrogen atoms are repelled to one side, giving the molecule a boomerang shape. The electrons in a water molecule are more concentrated around the more highly charged oxygen nucleus than around the hydrogen nuclei. This makes the oxygen end of the molecule slightly negative and leaves the hydrogen ends slightly positive. The inherent separation of charge in polar molecules makes it easier to align them with external fields and charges. Polar molecules therefore exhibit greater polarization effects and have greater dielectric constants. Those who study chemistry will find that the polar nature of water has many effects. For example, water molecules gather ions much more effectively because they have an electric field and a separation of charge to attract charges of both signs. Also, as brought out in the previous chapter, polar water provides a shield or screening of the electric fields in the highly charged molecules of interest in biological systems.

Figure 7: Artist’s conception of a water molecule. There is an inherent separation of charge, and so water is a polar molecule. Electrons in the molecule are attracted to the oxygen nucleus and leave an excess of positive charge near the two hydrogen nuclei. (Note that the schematic on the right is a rough illustration of the distribution of electrons in the water molecule. It does not show the actual numbers of protons and electrons involved in the structure.)
The two hydrogen atoms in the water molecule subtend an angle of one hundred and four point five degrees with oxygen at the center. This is a schematic arrangement of hydrogen and oxygen atoms in the water molecule. The molecule is polarized, with the electrons attracted more to the nucleus of the oxygen atom than toward the nuclei of the hydrogen atoms.

PhET Explorations: Capacitor Lab:

Explore how a capacitor works! Change the size of the plates and add a dielectric to see the effect on capacitance. Change the voltage and see charges built up on the plates. Observe the electric field in the capacitor. Measure the voltage and the electric field.

Figure 8: Capacitor Lab
Figure 8 (capacitor-lab_en.jar)

Section Summary

  • A capacitor is a device used to store charge.
  • The amount of charge QQ size 12{Q} {} a capacitor can store depends on two major factors—the voltage applied and the capacitor’s physical characteristics, such as its size.
  • The capacitance CC size 12{C} {} is the amount of charge stored per volt, or
    C=QV.C=QV. size 12{C=Q/V} {}
    (16)
  • The capacitance of a parallel plate capacitor is C=ε0AdC=ε0Ad size 12{C=e rSub { size 8{0} } A/d} {}, when the plates are separated by air or free space. ε 0 ε 0 is called the permittivity of free space.
  • A parallel plate capacitor with a dielectric between its plates has a capacitance given by
    C=κε0Ad,C=κε0Ad, size 12{C=e rSub { size 8{0} } A/d} {}
    (17)
    where κ κ is the dielectric constant of the material.
  • The maximum electric field strength above which an insulating material begins to break down and conduct is called dielectric strength.

Conceptual Questions

Exercise 1

Does the capacitance of a device depend on the applied voltage? What about the charge stored in it?

Exercise 2

Use the characteristics of the Coulomb force to explain why capacitance should be proportional to the plate area of a capacitor. Similarly, explain why capacitance should be inversely proportional to the separation between plates.

Exercise 3

Give the reason why a dielectric material increases capacitance compared with what it would be with air between the plates of a capacitor. What is the independent reason that a dielectric material also allows a greater voltage to be applied to a capacitor? (The dielectric thus increases CC size 12{C} {} and permits a greater VV size 12{V} {}.)

Exercise 4

How does the polar character of water molecules help to explain water’s relatively large dielectric constant? (Figure 7)

Exercise 5

Sparks will occur between the plates of an air-filled capacitor at lower voltage when the air is humid than when dry. Explain why, considering the polar character of water molecules.

Exercise 6

Water has a large dielectric constant, but it is rarely used in capacitors. Explain why.

Exercise 7

Membranes in living cells, including those in humans, are characterized by a separation of charge across the membrane. Effectively, the membranes are thus charged capacitors with important functions related to the potential difference across the membrane. Is energy required to separate these charges in living membranes and, if so, is its source the metabolization of food energy or some other source?

Figure 9: The semipermeable membrane of a cell has different concentrations of ions inside and out. Diffusion moves the K + K + (potassium) and Cl Cl (chloride) ions in the directions shown, until the Coulomb force halts further transfer. This results in a layer of positive charge on the outside, a layer of negative charge on the inside, and thus a voltage across the cell membrane. The membrane is normally impermeable to Na + Na + (sodium ions).
The semipermeable membrane of a cell is shown, with different concentrations of potassium cations, sodium cations, and chloride anions inside and outside the cell. The ions are represented by small, colored circles. In its resting state, the cell membrane is permeable to potassium and chloride ions, but it is impermeable to sodium ions. By diffusion, potassium cations travel out of the cell, going through the cell membrane and forming a layer of positive charge on the outer surface of the membrane. By diffusion, chloride anions go into the cell, going through the cell membrane and forming a layer of negative charge on the inner surface of the membrane. As a result, a voltage is set up across the cell membrane. The Coulomb force prevents all the ions from crossing the membrane.

Problems & Exercises

Exercise 1

What charge is stored in a 180 µF180 µF size 12{"190" µF} {} capacitor when 120 V is applied to it?

Solution

21 . 6 mC 21 . 6 mC size 12{"21" "." 6" mC"} {}

Exercise 2

Find the charge stored when 5.50 V is applied to an 8.00 pF capacitor.

Exercise 3

What charge is stored in the capacitor in Example 1?

Solution

80 . 0 mC 80 . 0 mC size 12{"80" "." 0" mC"} {}

Exercise 4

Calculate the voltage applied to a 2 .00 µF2 .00 µF size 12{2 "." "00" mF} {} capacitor when it holds 3.10 µC3.10 µC size 12{3 "." "10" mC} {} of charge.

Exercise 5

What voltage must be applied to an 8.00 nF capacitor to store 0.160 mC of charge?

Solution

20.0 kV

Exercise 6

What capacitance is needed to store 3.00 µC3.00 µC size 12{3 "." "00" mC} {} of charge at a voltage of 120 V?

Exercise 7

What is the capacitance of a large Van de Graaff generator’s terminal, given that it stores 8.00 mC of charge at a voltage of 12.0 MV?

Solution

667 pF 667 pF size 12{"667"" pF"} {}

Exercise 8

Find the capacitance of a parallel plate capacitor having plates of area 5.00m25.00m2 size 12{5 "." "00"`m rSup { size 8{2} } } {} that are separated by 0.100 mm of Teflon.

Exercise 9

(a)What is the capacitance of a parallel plate capacitor having plates of area 1.50 m21.50 m2 size 12{m rSup { size 8{2} } } {} that are separated by 0.0200 mm of neoprene rubber? (b) What charge does it hold when 9.00 V is applied to it?

Solution

(a) 4.4 µF4.4 µF size 12{4 "." "4 "mF} {}

(b) 4.0×105 C4.0×105 C size 12{4 "." 0 times "10" rSup { size 8{ - 5} } " C"} {}

Exercise 10

Integrated Concepts

A prankster applies 450 V to an 80.0 µF80.0 µF size 12{"80" "." 0 mF} {} capacitor and then tosses it to an unsuspecting victim. The victim’s finger is burned by the discharge of the capacitor through 0.200 g of flesh. What is the temperature increase of the flesh? Is it reasonable to assume no phase change?

Exercise 11

Unreasonable Results

(a) A certain parallel plate capacitor has plates of area 4.00 m24.00 m2 size 12{m rSup { size 8{2} } } {}, separated by 0.0100 mm of nylon, and stores 0.170 C of charge. What is the applied voltage? (b) What is unreasonable about this result? (c) Which assumptions are responsible or inconsistent?

Solution

(a) 14.2 kV

(b) The voltage is unreasonably large, more than 100 times the breakdown voltage of nylon.

(c) The assumed charge is unreasonably large and cannot be stored in a capacitor of these dimensions.

Glossary

capacitor:
a device that stores electric charge
capacitance:
amount of charge stored per unit volt
dielectric:
an insulating material
dielectric strength:
the maximum electric field above which an insulating material begins to break down and conduct
parallel plate capacitor:
two identical conducting plates separated by a distance
polar molecule:
a molecule with inherent separation of charge

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'My Favorites' is a special kind of lens which you can use to bookmark modules and collections. 'My Favorites' can only be seen by you, and collections saved in 'My Favorites' can remember the last module you were on. You need an account to use 'My Favorites'.

| A lens I own (?)

Definition of a lens

Lenses

A lens is a custom view of the content in the repository. You can think of it as a fancy kind of list that will let you see content through the eyes of organizations and people you trust.

What is in a lens?

Lens makers point to materials (modules and collections), creating a guide that includes their own comments and descriptive tags about the content.

Who can create a lens?

Any individual member, a community, or a respected organization.

What are tags? tag icon

Tags are descriptors added by lens makers to help label content, attaching a vocabulary that is meaningful in the context of the lens.

| External bookmarks