8.3 Electric Force
6 min read•november 29, 2021
Briana Dokken
Briana Dokken
Measuring and
What is ? 🔆
is a property of matter, just like mass, physical state, or density. When an atom has the same number of protons (positively charged particles) and electrons (negatively charged particles), the positive and negative charges of the atom cancel out, and its net is 0; we refer to the atom as uncharged when this occurs. However, when electrons are taken away or added to an atom, it becomes charged. depends entirely on the movement of electrons.
Image Courtesy of Vox.com
How Do Things Become Charged? 🚗
There are two kinds of : positive and negative . Electrons have a negative , so an atom becomes negatively charged when it has additional electrons. When you take away electrons from an atom, it becomes positively charged because the substance's protons outnumber the number of electrons. Like with magnets, opposite forces attract and like forces repel when discussing protons and electrons. Therefore:
Positive and negative charges attract one another
Similar charges (positive and positive, negative and negative) repel each other.
The arrangement of electrons can also influence . A substance can have a partial and repel or attract other charged objects, even if there is no change in electron count, like in the case of dipoles. For example, if a substance's electrons move to one side, that occupied half will have a partial negative , and the other side will have a partial positive . Physicists refer to this separation of positive and negative charges as a .
Measuring 🎛
is measured in coulombs (C). Since atoms become charged when electrons are added or removed, the of an atom is always a whole number multiple of an electron's . For example, if we take 3 electrons from an atom, its is now three times the of one electron. Similarly, if we gave an atom three additional electrons, its would be negative three times that of one electron. (For reference, the of an electron, also known as the , is 1.602 x 10-19 C.)
Often, we call charged particles "charges" or "point charges" if we assume that the focuses at a single point. If you see the word "" from here on out, know that it means a charged particle.
GIF courtesy of gyfcat.com
🔋
When two charges are near each other, each exerts the same force on the other. This force is either attractive or repulsive (remember, opposites attract and like forces repel). If two positive or negative charges are near each other, each charged particle exerts a repulsive force on the other; likewise, if a positively charged particle and a negatively charged particle are near each other, each exerts an attractive force on the other. We can quantify this force using :
Notice that as the distance between the two charges increases (r2), the force decreases, meaning they are inversely proportional. As either of the charges increases, increases, so and are directly proportional. This equation also includes Coulomb's constant k, which stays the same every time you use the formula. Sometimes, it is referred to as a proportionality constant.
Coulomb’s Law Example 🔌
Let's go over an example of how we can use to find how much force one exerts on another. Assume we have two atoms: Atom 1 has one additional electron added, and Atom 2 is missing 1 electron. Both of these two atoms are 0.5 m away from one another. What is the on one of the charges?
The first step to solving this problem is to plug each given variable into . After inserting values and solving for Fe, we should get:
In the end, each of these particles experiences an attractive force of 9.23 10-28 N on it. From this value, we know the force acting on Atom 1 points to the right towards Atom 2, and the force on Atom 2 points to the left towards Atom 1. If these two atoms had the same , Atom 1 would experience a force to the left, and Atom 2 would experience a rightward force since like charges repel.
➕
Like with other forces, when multiple electric forces act on one , we can add up those forces to find the on the . We treat forces as vectors and add up force like vectors.
In this example, let’s assume that Atoms 1 and 2 have a positive and Atom 3 has a negative . To find the on Atom 1, we would add up the forces from Atoms 2 and 3 to get a pointing towards the right, greater than each F2 and F3 individually. Atom 2 repulses Atom 1 to the right, and Atom 3 attracts 1 to the right, so we should have a pointing to the right equal to the sum of F2 and F3.
Net Forces at an Angle 💡
If a force acts on a at an angle, we can split it into an x and y component and then solve for the in the x-direction and y-direction. However, there are some limitations to this process. If we know the angle at which the force is acting and the overall , we can easily find the x and y-components of the . If we only know the x and y components of the , though, we can solve for the overall .
Suppose multiple electric forces are acting on a pointing in numerous directions. In that case, we can add up all of the x component forces to find the in the x-direction and add up all the y-component forces to find the in the y-direction. Then, we can use the and some trigonometry to find the total and its direction.
Practice Problems! ❔
Use and your knowledge of splitting apart and adding together components of forces to solve these practice problems! You'll need the following values to solve these questions:
of an electron = 1.602 x 10^(-19) C
and
k = 8.99 x 10^(9) Nm^(2)/C^(2)
4.16*10^(19) electrons are moved through a wire. How many Coulombs of were moved?
How strong is the attractive force between a sock with -2.00C of and a square of carpet with 3.00C of ? The sock and carpet are 0.500m apart, and we can assume they act like point charges.
Find the on q3. q1=-2.00*10^(-3)C, q2=-1.00*10^(-3)C, q3=+3.00*10^(-3)C. q1 is at (0,-3), q2 is at (3,0), and q3 is at (0,2).
What to Know about 👀
Overall, is very similar to other forces you have learned about so far. Objects that are charged (have gained or lost electrons) exert a force on each other, which we call the . Just like with all other forces, is a vector. The net acting on a can be found by adding up the x and y components of each acting on a . We find by using Coloumb’s Law, which says Fe=k|q1q2|/r^2.
🤝Connect with other students studying Physics with Rooms!
Key Terms to Review (11)
Charge
: Charge refers to an intrinsic property of matter that determines how it interacts with electromagnetic fields. It can be positive or negative, and like charges repel while opposite charges attract each other.Coulomb's Law
: Coulomb's Law states that the force between two charged objects is directly proportional to their charges and inversely proportional to the square of their distance apart.Dipole
: A dipole refers to a pair of equal but opposite charges separated by a distance. It can be formed within molecules or between two atoms.Electric Force
: Electric force refers to the attractive or repulsive force between two charged objects. Like charges repel each other, while opposite charges attract each other.Elementary Charge
: The elementary charge is the fundamental unit of electric charge carried by a single electron or proton. It has a magnitude of approximately 1.6 x 10^-19 coulombs.Net Force
: The net force is the overall force acting on an object, taking into account both magnitude and direction. It determines the object's acceleration or deceleration.Point Charge
: A point charge is an idealized model used in physics to represent a particle with all its charge concentrated at a single point. It has no physical size but possesses an electrical charge.Proton
: A proton is a subatomic particle found in the nucleus (center) of an atom. It has a positive electrical charge and contributes to the mass of the atom.Pythagorean Theorem
: The Pythagorean Theorem is a mathematical principle that relates the lengths of the sides in a right triangle. It states that the square of the hypotenuse (the side opposite the right angle) is equal to the sum of the squares of the other two sides.Superposition Principle
: The superposition principle states that when two or more waves or forces are present in the same system, the resulting wave or force is the algebraic sum of their individual effects.Vector Quantity
: A vector quantity is a physical quantity that has both magnitude and direction. It can be represented by an arrow, where the length of the arrow represents the magnitude and the direction of the arrow represents the direction.8.3 Electric Force
6 min read•november 29, 2021
Briana Dokken
Briana Dokken
Measuring and
What is ? 🔆
is a property of matter, just like mass, physical state, or density. When an atom has the same number of protons (positively charged particles) and electrons (negatively charged particles), the positive and negative charges of the atom cancel out, and its net is 0; we refer to the atom as uncharged when this occurs. However, when electrons are taken away or added to an atom, it becomes charged. depends entirely on the movement of electrons.
Image Courtesy of Vox.com
How Do Things Become Charged? 🚗
There are two kinds of : positive and negative . Electrons have a negative , so an atom becomes negatively charged when it has additional electrons. When you take away electrons from an atom, it becomes positively charged because the substance's protons outnumber the number of electrons. Like with magnets, opposite forces attract and like forces repel when discussing protons and electrons. Therefore:
Positive and negative charges attract one another
Similar charges (positive and positive, negative and negative) repel each other.
The arrangement of electrons can also influence . A substance can have a partial and repel or attract other charged objects, even if there is no change in electron count, like in the case of dipoles. For example, if a substance's electrons move to one side, that occupied half will have a partial negative , and the other side will have a partial positive . Physicists refer to this separation of positive and negative charges as a .
Measuring 🎛
is measured in coulombs (C). Since atoms become charged when electrons are added or removed, the of an atom is always a whole number multiple of an electron's . For example, if we take 3 electrons from an atom, its is now three times the of one electron. Similarly, if we gave an atom three additional electrons, its would be negative three times that of one electron. (For reference, the of an electron, also known as the , is 1.602 x 10-19 C.)
Often, we call charged particles "charges" or "point charges" if we assume that the focuses at a single point. If you see the word "" from here on out, know that it means a charged particle.
GIF courtesy of gyfcat.com
🔋
When two charges are near each other, each exerts the same force on the other. This force is either attractive or repulsive (remember, opposites attract and like forces repel). If two positive or negative charges are near each other, each charged particle exerts a repulsive force on the other; likewise, if a positively charged particle and a negatively charged particle are near each other, each exerts an attractive force on the other. We can quantify this force using :
Notice that as the distance between the two charges increases (r2), the force decreases, meaning they are inversely proportional. As either of the charges increases, increases, so and are directly proportional. This equation also includes Coulomb's constant k, which stays the same every time you use the formula. Sometimes, it is referred to as a proportionality constant.
Coulomb’s Law Example 🔌
Let's go over an example of how we can use to find how much force one exerts on another. Assume we have two atoms: Atom 1 has one additional electron added, and Atom 2 is missing 1 electron. Both of these two atoms are 0.5 m away from one another. What is the on one of the charges?
The first step to solving this problem is to plug each given variable into . After inserting values and solving for Fe, we should get:
In the end, each of these particles experiences an attractive force of 9.23 10-28 N on it. From this value, we know the force acting on Atom 1 points to the right towards Atom 2, and the force on Atom 2 points to the left towards Atom 1. If these two atoms had the same , Atom 1 would experience a force to the left, and Atom 2 would experience a rightward force since like charges repel.
➕
Like with other forces, when multiple electric forces act on one , we can add up those forces to find the on the . We treat forces as vectors and add up force like vectors.
In this example, let’s assume that Atoms 1 and 2 have a positive and Atom 3 has a negative . To find the on Atom 1, we would add up the forces from Atoms 2 and 3 to get a pointing towards the right, greater than each F2 and F3 individually. Atom 2 repulses Atom 1 to the right, and Atom 3 attracts 1 to the right, so we should have a pointing to the right equal to the sum of F2 and F3.
Net Forces at an Angle 💡
If a force acts on a at an angle, we can split it into an x and y component and then solve for the in the x-direction and y-direction. However, there are some limitations to this process. If we know the angle at which the force is acting and the overall , we can easily find the x and y-components of the . If we only know the x and y components of the , though, we can solve for the overall .
Suppose multiple electric forces are acting on a pointing in numerous directions. In that case, we can add up all of the x component forces to find the in the x-direction and add up all the y-component forces to find the in the y-direction. Then, we can use the and some trigonometry to find the total and its direction.
Practice Problems! ❔
Use and your knowledge of splitting apart and adding together components of forces to solve these practice problems! You'll need the following values to solve these questions:
of an electron = 1.602 x 10^(-19) C
and
k = 8.99 x 10^(9) Nm^(2)/C^(2)
4.16*10^(19) electrons are moved through a wire. How many Coulombs of were moved?
How strong is the attractive force between a sock with -2.00C of and a square of carpet with 3.00C of ? The sock and carpet are 0.500m apart, and we can assume they act like point charges.
Find the on q3. q1=-2.00*10^(-3)C, q2=-1.00*10^(-3)C, q3=+3.00*10^(-3)C. q1 is at (0,-3), q2 is at (3,0), and q3 is at (0,2).
What to Know about 👀
Overall, is very similar to other forces you have learned about so far. Objects that are charged (have gained or lost electrons) exert a force on each other, which we call the . Just like with all other forces, is a vector. The net acting on a can be found by adding up the x and y components of each acting on a . We find by using Coloumb’s Law, which says Fe=k|q1q2|/r^2.
🤝Connect with other students studying Physics with Rooms!
Key Terms to Review (11)
Charge
: Charge refers to an intrinsic property of matter that determines how it interacts with electromagnetic fields. It can be positive or negative, and like charges repel while opposite charges attract each other.Coulomb's Law
: Coulomb's Law states that the force between two charged objects is directly proportional to their charges and inversely proportional to the square of their distance apart.Dipole
: A dipole refers to a pair of equal but opposite charges separated by a distance. It can be formed within molecules or between two atoms.Electric Force
: Electric force refers to the attractive or repulsive force between two charged objects. Like charges repel each other, while opposite charges attract each other.Elementary Charge
: The elementary charge is the fundamental unit of electric charge carried by a single electron or proton. It has a magnitude of approximately 1.6 x 10^-19 coulombs.Net Force
: The net force is the overall force acting on an object, taking into account both magnitude and direction. It determines the object's acceleration or deceleration.Point Charge
: A point charge is an idealized model used in physics to represent a particle with all its charge concentrated at a single point. It has no physical size but possesses an electrical charge.Proton
: A proton is a subatomic particle found in the nucleus (center) of an atom. It has a positive electrical charge and contributes to the mass of the atom.Pythagorean Theorem
: The Pythagorean Theorem is a mathematical principle that relates the lengths of the sides in a right triangle. It states that the square of the hypotenuse (the side opposite the right angle) is equal to the sum of the squares of the other two sides.Superposition Principle
: The superposition principle states that when two or more waves or forces are present in the same system, the resulting wave or force is the algebraic sum of their individual effects.Vector Quantity
: A vector quantity is a physical quantity that has both magnitude and direction. It can be represented by an arrow, where the length of the arrow represents the magnitude and the direction of the arrow represents the direction.
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