Skip to main content
Physics LibreTexts

18.8: Applications of Electrostatics

[ "article:topic", "authorname:openstax", "Van de Graaff generator", "xerography", "electrostatics", "electrostatic precipitators", "photoconductor", "grounded", "ink-jet printer", "laser printer" ]
  • Page ID
    2610
  • The study of electrostatics has proven useful in many areas. This module covers just a few of the many applications of electrostatics.

    The Van de Graaff Generator

    Van de Graaff generators (or Van de Graaffs) are not only spectacular devices used to demonstrate high voltage due to static electricity—they are also used for serious research. The first was built by Robert Van de Graaff in 1931 (based on original suggestions by Lord Kelvin) for use in nuclear physics research. Figure \(\PageIndex{1}\) shows a schematic of a large research version. Van de Graaffs utilize both smooth and pointed surfaces, and conductors and insulators to generate large static charges and, hence, large voltages.

    A very large excess charge can be deposited on the sphere, because it moves quickly to the outer surface. Practical limits arise because the large electric fields polarize and eventually ionize surrounding materials, creating free charges that neutralize excess charge or allow it to escape. Nevertheless, voltages of 15 million volts are well within practical limits.

    Figure \(\PageIndex{1}\): Schematic of Van de Graaff generator. A battery (A) supplies excess positive charge to a pointed conductor, the points of which spray the charge onto a moving insulating belt near the bottom. The pointed conductor (B) on top in the large sphere picks up the charge. (The induced electric field at the points is so large that it removes the charge from the belt.) This can be done because the charge does not remain inside the conducting sphere but moves to its outside surface. An ion source inside the sphere produces positive ions, which are accelerated away from the positive sphere to high velocities.

    TAKE-HOME EXPERIMENT: ELECTROSTATICS AND HUMIDITY

    Rub a comb through your hair and use it to lift pieces of paper. It may help to tear the pieces of paper rather than cut them neatly. Repeat the exercise in your bathroom after you have had a long shower and the air in the bathroom is moist. Is it easier to get electrostatic effects in dry or moist air? Why would torn paper be more attractive to the comb than cut paper? Explain your observations.

    Xerography

    Most copy machines use an electrostatic process called xerography—a word coined from the Greek words xeros for dry and graphos for writing. The heart of the process is shown in simplified form in Figure \(\PageIndex{2}\). A selenium-coated aluminum drum is sprayed with positive charge from points on a device called a corotron. Selenium is a substance with an interesting property—it is a photoconductor. That is, selenium is an insulator when in the dark and a conductor when exposed to light.

    In the first stage of the xerography process, the conducting aluminum drum is grounded so that a negative charge is induced under the thin layer of uniformly positively charged selenium. In the second stage, the surface of the drum is exposed to the image of whatever is to be copied. Where the image is light, the selenium becomes conducting, and the positive charge is neutralized. In dark areas, the positive charge remains, and so the image has been transferred to the drum.

    The third stage takes a dry black powder, called toner, and sprays it with a negative charge so that it will be attracted to the positive regions of the drum. Next, a blank piece of paper is given a greater positive charge than on the drum so that it will pull the toner from the drum. Finally, the paper and electrostatically held toner are passed through heated pressure rollers, which melt and permanently adhere the toner within the fibers of the paper.

    Figure \(\PageIndex{2}\): Xerography is a dry copying process based on electrostatics. The major steps in the process are the charging of the photoconducting drum, transfer of an image creating a positive charge duplicate, attraction of toner to the charged parts of the drum, and transfer of toner to the paper. Not shown are heat treatment of the paper and cleansing of the drum for the next copy.

    Laser Printers

    Laser printers use the xerographic process to make high-quality images on paper, employing a laser to produce an image on the photoconducting drum as shown in Figure \(\PageIndex{3}\). In its most common application, the laser printer receives output from a computer, and it can achieve high-quality output because of the precision with which laser light can be controlled. Many laser printers do significant information processing, such as making sophisticated letters or fonts, and may contain a computer more powerful than the one giving them the raw data to be printed.

    Figure \(\PageIndex{3}\): In a laser printer, a laser beam is scanned across a photoconducting drum, leaving a positive charge image. The other steps for charging the drum and transferring the image to paper are the same as in xerography. Laser light can be very precisely controlled, enabling laser printers to produce high-quality images.

    Ink Jet Printers and Electrostatic Painting

    The ink jet printer, commonly used to print computer-generated text and graphics, also employs electrostatics. A nozzle makes a fine spray of tiny ink droplets, which are then given an electrostatic charge (Figure \(\PageIndex{4}\)). Once charged, the droplets can be directed, using pairs of charged plates, with great precision to form letters and images on paper. Ink jet printers can produce color images by using a black jet and three other jets with primary colors, usually cyan, magenta, and yellow, much as a color television produces color (this is more difficult with xerography, requiring multiple drums and toners).

    Figure \(\PageIndex{4}\): The nozzle of an ink-jet printer produces small ink droplets, which are sprayed with electrostatic charge. Various computer-driven devices are then used to direct the droplets to the correct positions on a page.

    Electrostatic painting employs electrostatic charge to spray paint onto odd-shaped surfaces. Mutual repulsion of like charges causes the paint to fly away from its source. Surface tension forms drops, which are then attracted by unlike charges to the surface to be painted. Electrostatic painting can reach those hard-to-get at places, applying an even coat in a controlled manner. If the object is a conductor, the electric field is perpendicular to the surface, tending to bring the drops in perpendicularly. Corners and points on conductors will receive extra paint. Felt can similarly be applied.

    Smoke Precipitators and Electrostatic Air Cleaning

    Another important application of electrostatics is found in air cleaners, both large and small. The electrostatic part of the process places excess (usually positive) charge on smoke, dust, pollen, and other particles in the air and then passes the air through an oppositely charged grid that attracts and retains the charged particles (Figure \(\PageIndex{5}\)). Large electrostatic precipitators are used industrially to remove over 99% of the particles from stack gas emissions associated with the burning of coal and oil. Home precipitators, often in conjunction with the home heating and air conditioning system, are very effective in removing polluting particles, irritants, and allergens.

    Figure \(\PageIndex{5}\): (a) Schematic of an electrostatic precipitator. Air is passed through grids of opposite charge. The first grid charges airborne particles, while the second attracts and collects them. (b) The dramatic effect of electrostatic precipitators is seen by the absence of smoke from this power plant. (credit: Cmdalgleish, Wikimedia Commons)

    PROBLEM-SOLVING STRATEGIES FOR ELECTROSTATICS

    1. Examine the situation to determine if static electricity is involved. This may concern separated stationary charges, the forces among them, and the electric fields they create.
    2. Identify the system of interest. This includes noting the number, locations, and types of charges involved.
    3. Identify exactly what needs to be determined in the problem (identify the unknowns). A written list is useful. Determine whether the Coulomb force is to be considered directly—if so, it may be useful to draw a free-body diagram, using electric field lines.
    4. Make a list of what is given or can be inferred from the problem as stated (identify the knowns). It is important to distinguish the Coulomb force \(\mathbf{F}\) from the electric field \(\mathbf{E}\), for example.
    5. Solve the appropriate equation for the quantity to be determined (the unknown) or draw the field lines as requested.
    6. Examine the answer to see if it is reasonable: Does it make sense? Are units correct and the numbers involved reasonable?

    The following worked example illustrates how this strategy is applied:

    Example \(\PageIndex{1}\): Acceleration of a Charged Drop of Gasoline

    If steps are not taken to ground a gasoline pump, static electricity can be placed on gasoline when filling your car’s tank. Suppose a tiny drop of gasoline has a mass of \(4.00\times 10^{-15}kg\) and is given a positive charge of \(3.20\times 10^{-19}C\). (a) Find the weight of the drop. (b) Calculate the electric force on the drop if there is an upward electric field of strength \(3.00\times 10^{5} N/C\) due to other static electricity in the vicinity. (c) Calculate the drop’s acceleration.

    Strategy

    To solve an integrated concept problem, we must first identify the physical principles involved and identify the chapters in which they are found.

    The following solutions to each part of the example illustrate how the specific problem-solving strategies are applied. These involve identifying knowns and unknowns, checking to see if the answer is reasonable, and so on.

    Solution for (a)

    Weight is mass times the acceleration due to gravity, as first expressed in

    \[w=mg.\]

    Entering the given mass and the average acceleration due to gravity yields

    \[\begin{align*} w &=(4.00\times 10^{-15}kg)(9.80m/s^{2}) \\[5pt] &= 3.92\times 10^{-14}N.\end{align*} \]

    Discussion for (a)

    This is a small weight, consistent with the small mass of the drop.

    Solution for (b)

    The force an electric field exerts on a charge is given by rearranging the following equation:

    \[F=qE. \nonumber \]

    Here we are given the charge (\(3.20\times 10^{-19}C\) is twice the fundamental unit of charge) and the electric field strength, and so the electric force is found to be

    \[\begin{align*} F&=(3.20\times 10^{-19}C)(3.00\times 10^{5}N/C) \\[5pt] &=9.60\times 10^{-14}N. \end{align*} \]

    Discussion for (b)

    While this is a small force, it is greater than the weight of the drop.

    Solution for (c)

    The acceleration can be found using Newton’s second law, provided we can identify all of the external forces acting on the drop. We assume only the drop’s weight and the electric force are significant. Since the drop has a positive charge and the electric field is given to be upward, the electric force is upward. We thus have a one-dimensional (vertical direction) problem, and we can state Newton’s second law as

    \[a=\dfrac{F_{net}}{m}. \nonumber\]

    where \(F_{net}=F-w\). Entering this and the known values into the expression for Newton’s second law yields

    \[\begin{align*} a &=\dfrac{F-w}{m} \\[5pt] &=\dfrac{9.60\times 10^{-14}N-3.92\times 10^{-14}N}{4.00\times 10^{-15}kg} \\[5pt] &= 14.2m/s^{2}. \end{align*} \]

    Discussion for (c)

    This is an upward acceleration great enough to carry the drop to places where you might not wish to have gasoline.

    This worked example illustrates how to apply problem-solving strategies to situations that include topics in different chapters. The first step is to identify the physical principles involved in the problem. The second step is to solve for the unknown using familiar problem-solving strategies. These are found throughout the text, and many worked examples show how to use them for single topics. In this integrated concepts example, you can see how to apply them across several topics. You will find these techniques useful in applications of physics outside a physics course, such as in your profession, in other science disciplines, and in everyday life. The following problems will build your skills in the broad application of physical principles.

    UNREASONABLE RESULTS

    The Unreasonable Results exercises for this module have results that are unreasonable because some premise is unreasonable or because certain of the premises are inconsistent with one another. Physical principles applied correctly then produce unreasonable results. The purpose of these problems is to give practice in assessing whether nature is being accurately described, and if it is not to trace the source of difficulty.

    PROBLEM-SOLVING STRATEGY

    To determine if an answer is reasonable, and to determine the cause if it is not, do the following.

    1. Solve the problem using strategies as outlined above. Use the format followed in the worked examples in the text to solve the problem as usual.
    2. Check to see if the answer is reasonable. Is it too large or too small, or does it have the wrong sign, improper units, and so on?
    3. If the answer is unreasonable, look for what specifically could cause the identified difficulty. Usually, the manner in which the answer is unreasonable is an indication of the difficulty. For example, an extremely large Coulomb force could be due to the assumption of an excessively large separated charge.

    Summary

    • Electrostatics is the study of electric fields in static equilibrium.
    • In addition to research using equipment such as a Van de Graaff generator, many practical applications of electrostatics exist, including photocopiers, laser printers, ink-jet printers and electrostatic air filters.

    Glossary

    Van de Graaff generator
    a machine that produces a large amount of excess charge, used for experiments with high voltage
    electrostatics
    the study of electric forces that are static or slow-moving
    photoconductor
    a substance that is an insulator until it is exposed to light, when it becomes a conductor
    xerography
    a dry copying process based on electrostatics
    grounded
    connected to the ground with a conductor, so that charge flows freely to and from the Earth to the grounded object
    laser printer
    uses a laser to create a photoconductive image on a drum, which attracts dry ink particles that are then rolled onto a sheet of paper to print a high-quality copy of the image
    ink-jet printer
    small ink droplets sprayed with an electric charge are controlled by electrostatic plates to create images on paper
    electrostatic precipitators
    filters that apply charges to particles in the air, then attract those charges to a filter, removing them from the airstream

    Contributors

    • Paul Peter Urone (Professor Emeritus at California State University, Sacramento) and Roger Hinrichs (State University of New York, College at Oswego) with Contributing Authors: Kim Dirks (University of Auckland) and Manjula Sharma (University of Sydney). This work is licensed by OpenStax University Physics under a Creative Commons Attribution License (by 4.0).