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Claimed by Katherine Freesemann
<h1><strong>Edited by Adeline Boswell Fall 2019, Edited by Alayna Baker Spring 2020</strong></h1>


edited by Tim Reardon
The Hall Effect is the electric polarization of a block or slab of metal that occurs when a current is run through it while it is subject to a magnetic field perpendicular to the current.


edited by Megan Walden
==The Main Idea==


edited by Morgan Mango (Spring 2017)
When a mobile charge, either positive or negative, flows through a metal block and is influenced by a magnetic field, the magnetic force on the charges force them to begin concentrating on one side of the block. Thus the block polarizes and has negative charges on one side and positive on the other in order to remain neutral. This grouping of positive charges in one part of the block and negative charges in another part of the block creates an electric field and thus an electric force equal on magnitude to the magnetic force that causes the initial polarization, but opposite in direction. The magnetic and electric forces cancel each other out and after some time, the charges flow normally through the block and do not group on one side or the other of the block. This perpendicular electric field also creates a potential difference known as the "Hall Voltage."


edited by Sergio Prudencio (Fall 2017)
===Part 1: Normal circuit (No Magnetic Field Yet)===
 
(For simplicity, the mobile charges in this example have already been determined to be negatively charged electrons. This will not always be the case and it should not be assumed that the mobile charges are electrons)
edited by Joon Park (Fall 2018)


Mobile electrons flow through a wire due to a parallel electric field inside the wire. This electric field is caused by an energy source, most commonly a battery. The parallel electric field flows from an area of high potential (i.e. the positive end of the battery) to an area of low potential (i.e. the negative end of the battery). This is the same direction as the conventional current. Since electrons are negatively charged, they flow in the opposite direction of the parallel electric field.


=== Part 2: Initial Transient State (Magnetic Field Present) ===


The hall effect is the difference across an electrical conductor. transversal to a electrical current. This is information covered in Chapter 20 of your textbook (Modern Students) and chapter 23 (Classical).  
Mobile electrons are subjected to a magnetic field perpendicular to their motion as they flow through the wire. This results in the mobile charges being forced onto one side of the block by the magnetic force. This grouping of mobile charges on one side of the block creates an electric force. As time passes, more mobile charges are deposited on the side of the block and the electric force increases in magnitude.


The Hall Effect uses the idea of Fnet being equal and Fnet being the Lorentz Force in these "Hall Effect" questions. This Fnet of zero is achieved due to the polarization properties of metal. Using what we know about how to calculate the Lorentz Force, we can determine things such as the sign of a mobile charge carrier. The Hall Voltage (which is not discussed in this Wiki Page) is a continuation of this idea of the Hall Effect and can be used to determine things such as the density of a mobile charge and can provide more information about the perpendicular electric field. This page is mainly about observations that can be made using Hall Effect without even having to calculate numbers. It is fundamental to understand this page before moving on to calculations with the Hall Effect.
===Part 3: Steady State (Magnetic Field Still Present, but abated)===
 
==The Main Idea==


When a mobile charge flows through a wire or metal block and are also influenced by a magnetic force, the mobile charges begin to build up on one side or the other of the block. Because metals have the unique ability to have very mobile charges (unlike insulators) the block polarizes and has negative charges on one side and positive on the other so that the block is able to remain neutral. This grouping of positive charges in one part of the block and negative charges in another part of the block creates an electric field and thus an electric force perpendicular to the flow of the mobile charges through the wire. The magnetic and electric forces cancel each other out and after some time, the charges flow right through the block and do not group on one side or the other of the block. This perpendicular electric field also creates a potential difference known as the "Hall Voltage."
Over time massive quantities of charges are concentrated on one side of the block. As the charges build up, they will begin to create a charged area on one surface of the conductor. The charged surface will create an electric force to oppose the magnetic force that is pushing new electrons onto this charged surface. This opposing electric force is called the transverse electric force. When enough mobile charges have collected, their combined transverse electric force will be equal in magnitude to the magnetic force that is holding them. At this point, there is no net vertical force pushing more electrons against the surface of the conductor and these electrons will flow normally again, as they would if there was no magnetic field present. This is called the steady state.  


==A Mathematical Model==


===Part 1: Normal circuit (No Magnetic Field Yet)===
===Part 1: Normal circuit (No Magnetic Field Yet)===
(For simplicity, the mobile charges have already been determined to be negatively charged electrons. This will not always be the case and it should not be assumed that the mobile charges are electrons)


Mobile electrons flow through a wire due to a parallel electric field inside the wire. This electric field is caused by an energy source such as a battery or power supply. The parallel electric field flows from an area of high potential (i.e. the positive end of the battery) to an area of low potential (i.e. the negative end of the battery). This is the same direction as the conventional current. Since electrons are negatively charged, they flow in the opposite direction of the parallel electric field. This can be summarized by the equation:
<math> F_{electric, parallel} = qE_{parallel} </math>


[[File:Electric_force.png]]
Where q is the electric charge of the mobile charge. As F and E are vectors, a negative charge results in an electric force in the opposite direction of the electric field.


=== Part 2: Initial Transient State (Magnetic Field Present) ===
=== Part 2: Initial Transient State (Magnetic Field Present) ===


Mobile electrons are subjected to a magnetic field as they flow through the wire. Since electrons are negatively charged, they experience a magnetic force in the downward direction due to the magnetic field. This can be summarized by the equation:
<math> F_{magnetic} = q(v\; &Chi; \;B)</math>


[[File:Mag_force.png]]
Where v is the velocity of the mobile charge and B is the magnetic field. For help calculating the cross product, including an example using the Hall Effect, see [[Right-Hand_Rule]]. REMEMBER, the mobile charge will move in the opposite direction of the cross product if it is negative, similar to how it behaves in an electric field.


See aside for extra help on determining this direction.
===Part 3: Steady State (Magnetic Field Still Present, but abated)===


===Part 3: Steady State (Magnetic Field Still Present)===
<math> F_{electric, perpendicular} = qE_{perpendicular} </math>


Over time more and more charges are going to build up. As they build up, they will begin to create a charged area on one surface of the conductor. This charged surface will start to oppose the magnetic force that is holding the electrons. Essentially the electrons are being held against the side of the conductor by the magnetic force. As more and more electrons collect together against the surface of the conductor, they start to oppose the magnetic force that’s holding them. This opposing force is called the transverse electric force and is responsible for the existence of the perpendicular electric field. When enough electrons have collected, their combined transverse electric force will be equal in magnitude to the magnetic force that is holding them. At this point, there is no net vertical force pushing more electrons against the surface of the conductor and these electrons will flow normally again. This is called the steady state. As long as the magnetic field remains the same magnitude and in the same direction and the same number of electrons remain pushed against the conductor’s surface, the steady state will be maintained.
<math> |F_{electric, perpendicular}| = |F_{magnetic}| </math>


[[File:F_perp.png]]
==Computational Model==
In this diagram, it is assumed the charge carrier is a negatively charged electron. THIS IS NOT A SAFE ASSUMPTION on a real question, experiment, or exam but was done for the purpose of simplifying explanations.


==== Aside: Right Hand Rule====
===Part 1: Normal circuit (No Magnetic Field Yet)===


ASIDE: The Right Hand Rule is necessary to use in determining the direction that the magnetic force will point. This is also a great trick to determine the answer to other cross products used in the physics course. First, take your right hand and point your thumb in the direction that the mobile charges are flowing. In this case, this would be the direction that the electrons are flowing. Now with your thumb in that direction, point your index finger in the direction of the magnetic field (in this case, the magnetic field would point in into the page as is shown). Now the most important part; point the rest of your fingers so they are coming straight out of your palm. These fingers are pointing in the direction of the magnetic force FOR A POSITIVE CHARGE. Since we have electrons, the magnetic force will point in the exact opposite way. THIS LAST PART IS EXTREMELY IMPORTANT TO REMEMBER. If it makes it easier, you can do the same technique that was used for the right hand with your left hand anytime you have a negative charge.
[[File: Hall_Effect_part_1.png]]


In this diagram a solid conductive metal block is connected to two ends of a battery by wires. At this time there is no magnetic field present and electrons flow through the block in a straight line from wire to wire without interference or interruption.


===A Mathematical Model===
=== Part 2: Initial Transient State (Magnetic Field Present) ===
 
What are the mathematical equations that allow us to model this topic.  <math>\vec{F}_{magnetic}= \vec{F}_{electricperpendicular}</math> where '''F_magnetic''' is the force on the mobile charge by the magnetic field and '''F_electricperpendicular''' is the force the mobile charge experiences that is caused by the polarization of the metal.


===A Diagram of How the Hall Effect Works===
[[File: Hall_effect_part_2.png]]


In this diagram the circles containing x's represent a magnetic field (NOT a magnetic force) into the page. When the electrons begin to move across the block their initial velocity interacts with the magnetic field to create a magnetic force downward. This causes electrons to begin pooling on the bottom face of the slab. This polarizes the block and creates a vertical potential difference across the block. It also creates an electric force that opposes the magnetic force, but in this state it is smaller than the magnetic force, resulting in continued pooling of electrons.


In this diagram, I assumed that the mobile charge carrier was positive.
===Part 3: Steady State (Magnetic Field Still Present, but abated)===


[[File: Diagram1.JPG]]
[[File: Hall_effect_part_3.png]]


[[File: Diagram2.jpg]]
As time passes eventually sufficient quantities of electrons build up to create an electric force equal in magnitude to the magnetic force but opposite in direction. This allows the electrons to continue flow across the block as they did in part 1, however now the vertical voltage difference which was created in part 2 is not only still present but also at its maximum value. Most practice and exam problems will involve either the calculation or orientation of this voltage difference. It's important to remember that a voltmeter will have a positive reading if the positive node is connected to the end of the block which is positively charged and vice versa.


==Examples==
==Examples==


The following are 3 examples that help to reinforce the concepts of the Hall Effect and two examples that involves actual calculation. Make sure to understand the conceptual examples before doing the examples with calculation because many of the calculation require the application of these concepts into the problem.
===Simple===
 
[[File:Hall Effect 1.jpg]]
===Conceptual Examples===
[[File:Hall Effect 2.jpg]]
[[File:Hall effect cenceptual 1.png]]


Here are the 3 conceptual examples regarding the Hall Effect. They are categorized in level of difficulty.
A metal block is connected to a battery by two wires. Conventional current flows clockwise and the mobile charge in the block is positive.  The block also experiences a magnetic field out of the page denoted by concentric circles. The block is also connected to a voltmeter. The positive end of the voltmeter is connected to the bottom of the block and the negative end of the voltmeter is connected to the top of the block. See attached photo for a diagram. What sign will the voltmeter display?
 
====Simple====
 
Question: A metal slab is connected to a battery by two wires. Conventional current flows clockwise and the mobile charge in the block is positive.  The block also experiences a magnetic field out of the page. The slab is also connected to a voltmeter.The positive end of the voltmeter is connected to the bottom of the block and the negative end of the voltmeter is connected to the top of the block. See attached photo for a diagram.
 
[[File:HallEffectDiagram.JPG]]


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In order to determine this, we must determine what direction the magnetic force is. In this case, since magnetic force is qv X B, the magnetic force points up. This means that the mobile charges (positive) will be pushed towards the top of the block and the negative charge will be at the bottom of the block, so that the block will remain neutrally charged. Remember: a voltmeter will have a positive reading if the positive end is connected to the part with the larger potential. In this case, the larger potential is at the top because that is where the positive charge is, but the negative end of the voltmeter is connected there. The voltmeter will have a negative reading.
In this case, since magnetic force is q(v X B) and we know the charges are positive and thus follow the conventional current which moves across the block from left to right, the magnetic force points up. This means that the mobile charges (positive) will be pushed towards the bottom of the block. Remember: a voltmeter will have a positive reading if the positive end is connected to the positively charged side of the block. In this case, the bottom of the block is positively charged and the positive end of the voltmeter is connected there. The voltmeter will have a positive reading.


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====Middling====
[[File:Hall effect cenceptual 2.png]]


Question: A battery and metal block are connected by 2 wires. Conventional current flows counterclockwise. A voltmeter is attached to the block with its positive lead at the top of the block and its negative lead at the bottom of the block. The voltmeter has a positive reading. What sign does the mobile charge have? (See attached diagram)
A battery and metal block are connected by 2 wires. Conventional current flows clockwise. A magnetic field points out of the page, denoted by concentric circles. A voltmeter is attached to the block with its positive lead at the top of the block and its negative lead at the bottom of the block. The voltmeter has a positive reading. What sign does the mobile charge have?  
 
[[File:image2.jpg]]


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First of all, due to the Voltmeter having a positive reading, we know that the electric field perpendicular (or the electric field that the Voltmeter is telling us about) points from where the positive lead of the voltmeter is connected to the negative lead (in this example, from top to bottom). We also know that Fmagnetic + Felectric_perpendicular equals zero, so F_b and F_e must have opposite signs. F_b is calculated using    I*dl X B. The right hand rule tells us that F_b points in the positive y direction. This tells us that F_e perpendicular must point in the negative y direction. F_e is simply (E*q). As determined earlier, E already points in - y direction so we can conclude that the mobile charges are positive.
From the voltmeter reading we can deduce that the top of the block is positively charged and the bottom negatively charged. Thus, we check if positive mobile charge carriers satisfy this requirement. A positive charge moves with the conventional current, which in this case is from left to right, meaning its velocity would be in the positive x direction. When taking the cross product of the charge's velocity and the magnetic field (out of the page) we get a magnetic force pointing downward, thus meaning the positive charges would be forced downward as well. This is in conflict with the positive voltmeter reading and thus cannot be true. Next we check if negative charge carriers agree with the voltmeter readings. A negatively charged mobile charge carrier moves counter to the conventional current, in this case meaning it moves across the block from right to left resulting in a velocity in the negative x direction. When we take the cross product of this velocity and the magnetic field out of the page multiplied by the charge of the carrier we get a magnetic force pointing downwards (using F = q(v X B). This would result in the block's bottom being negatively charged and the top being positively charged. This result agrees with the given voltmeter reading. The mobile charge carriers are negative.  
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====Difficult====
===Middling===


Question: A battery and metal block are connected by two wires. There is also a magnetic field coming out of the page. You are told that the Efield perpendicular is point in the positive y direction. There is also a voltmeter with the positive lead on the top of the block and the negative lead is on the bottom of the block. You are asked to find: the sign of the potential difference that the voltmeter will measure, the polarization of the block, and the sign of the mobile charge. (See attached diagram)
[[File:Hall Effect Middling problem 1.png]]


[[File:PhotoC.jpg]]
<math>B = 1.8 T </math> out of the page (denoted by concentric circles)


===Examples with Calculation===
<math> n = 7*10^{25} /m^3 </math>


These are the questions that involves numerical calculation with the application of Hall Effect. There are two problem, which aren't necessarily categorized in level of difficulty.
<math> u = 3*10^{-5} </math>


====Problem #1====
# What does reading does the voltmeter display (both magnitude and sign)?
# What does reading does the Ammeter display(both magnitude and sign?


[[File:Problem1Question.jpg|480 × 640px]]
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;Step 1 Find <math> E_{Hall} </math>
: <math> ΣF_y = q(v\; &Chi; \;B) + q|E_{Hall}| </math>
: <math> 0 = q(v\; &Chi; \;B) + q|E_{Hall}| </math>
: <math> q(v\; &Chi; \;B) = q|E_{Hall}| </math>
: <math> |E_{Hall}| = (v\; &Chi; \;B)  </math>
: <math> |E_{Hall}| = |v| * |B|  </math>


[[File:Problem1Answer1.jpg|480 × 640px]]
;Step 2 Find v
: <math> I = q*n*A*v </math>
: <math> v = \frac{I}{q*n*A} </math>


[[File:Problem1Answer2.jpg|480 × 640px]]
;Step 3 Substitute v into our formula for <math> E_{Hall} </math>
: <math> |E_{Hall}| = \frac{I * |B|}{q*n*A} </math>


;Step 4
: <math> σ = q*n*u </math>


;Step 5
: <math> R = \frac{L}{σA} </math>


;Step 6 Substitute σ
: <math> R = \frac{L}{q*n*u*A} </math>


;Step 7
: <math> Emf = I*R </math>


;Step 8 Substitute R
: <math> Emf = \frac{I*L}{q*n*u*A} </math>


;Step 9 Solve for I
: <math> I = \frac{Emf*q*n*u*A}{L} </math>


;Step 10 Substitute I in our formula for <math> E_{Hall} </math>
: <math> |E_{Hall}| = \frac{Emf * u * |B|}{L} </math>


;Step 11
: <math> ∆V = E * d </math>


;Step 12 Substitute <math> E_{Hall} </math>
: <math> ∆V = \frac{Emf * u * |B|* h}{L} </math>


;Step 13 Plug in given values and solve for<math> ∆V </math>
: <math> ∆V = -1.767*10^{-5} </math>




Explanation:
The voltmeter reads the voltage of the bar between the given distance. Since this voltmeter is attached along the height of the bar, the distance is going to be the 3cm. We write out the Lorentz Force formula and set it equal to zero, which makes the magnetic force and electric force equal to each other. After manipulating the equation, the Hall Electric Field is drift sped times the magnetic field. The drift speed is found by manipulating the Current formula, Area density formula, and the Resistance Formula. After I is found, you plug it into the I in the drift speed formula, and plug drift speed v into the Hall electric field formula. Since Hall voltage is Hall electric times the distance, you multiply the calculated Hall electric field with 3 cm in order to get the final Hall voltage.
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<math> I = \frac{Emf*q*n*u*A}{L} </math>


<math> I = 2.19927 A </math>


Explanation:
You use the derivation of I from first portion of the question and plug in the values to calculate the conventional current. The Area here is the width times the height because the Ammeter is connected through the face created by the area of width and height.
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===Difficult===


[[File:Hall Effect difficult problem.png]]


<math> B = 1.5</math> T out of the page (denoted by concentric circles)


# Calculate the drift speed v of the mobile charges
# Calculate the charge density n of the mobile charges
# ∆V = 13 V along the length of the bar, calculate the mobility u of the mobile charge carrier in the metal


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===Important Tricks===
;Step 1 Find <math> E_{Hall} </math>
: <math> ΣF_y = q(v\; &Chi; \;B) + q*E_{Hall} </math>
: <math> 0 = q(v\; &Chi; \;B) + q*E_{Hall}</math>
: <math> q(v\; &Chi; \;B) = q*E_{Hall} </math>
: <math> E_{Hall} = (v\; &Chi; \;B)  </math>
: <math> E_{Hall} = v * B  </math>


Hall effect can only be tested so many ways. There are a few tricks to keep in mind.
;Step 2
: <math> E_{Hall} = \frac{∆V_H}{h}  </math>


[[File:HALL1.png]]
;Step 3 Substitute <math> E_{Hall} </math>
: <math> v * B = \frac{∆V_H}{h}  </math>


for example look at the photo above. There a Voltmeter connected to a sheet of metal. SInce the voltmeter reads a negative voltage, you can automatically assume that the side connected to the negative terminal of the voltmeter is connected to the positive side of the metal due to hall effect. This is because that a voltmeter is reading a charge in the opposite direction.
;Step 4 Solve for v
: <math> v = \frac{∆V_H}{h*B}  </math>


[[File:HALL2.png]]
;Step 5 Plug in given values
: <math> v = 1.367 </math> m/s


You can try this in lab as well. Use a voltmeter and measure the voltage across a battery, if you switch between the positive and negative sides, then you also which between a positive and negative values. If the value is negative, then you are going in the opposite direction of the current.


CASE 2:  
Explanation:
First, set the Lorentz Force Equation equal to zero. After a couple of algebraic manipulations similar to the middling question, the Hall electric field equals to the product of the drift speed and magnetic field. Since, the hall electric field is not given but hall voltage is, you have to substitute the hall electric field with hall voltage divided by the height of the bar (distance that voltmeter calculated). Afterwards, plug in all the given values, and calculate for the drift speed.
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You have a conductive metal passing a wire with a voltage the blue X's are a magnetic field going into the page.
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[[File:HALL4.png]]
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Current of the Box is moving from the right to the left though the middle of the box, and as you can see from the voltameter, the siders are negative and positive polarized as listed in the picture. The negative voltage is due to the defection of electrons to the sensors in the voltameters.
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;Step 1
: <math> I = |q|*n*A*v </math>


Equilibrium is met in a problem with electric force is equal to a magnetic force, in this example, the electric field is from the polarized conductor.
;Step 2
: <math> n = \frac{I}{|q|*A*v} </math>


So if Eh is the electric field from the hall effect,
;Step 3 Plug in given values and solve
then the following is true of the system above in Equilibrium.
: <math> n = 9.971 * 10^{23} /m^3</math>
Fe=Fb
q*Eh=q*v*B
so
Eh=v*B


Where v is the velocity of the block entering the square wire
Explanation:
Vh=(Voltage read on voltmeter)
In order to find the charge density of the mobile charge carriers  use the conventional current formula. Manipulate the conventional current formula to find a formula for charge density and plug in all the values.
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Also note that if d is the width of the conductor, then the hall voltage Vh measured by the voltmeter is:  
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;Step 1
: <math> v = u*E </math>


Vh=Eh*d=v*B*d
;Step 2 Find a formula for u
: <math> u = \frac{v}{E} </math>


In this case, because F_b is (I*dl) X B, we can say that F_b points in the negative y direction. Since F_b must equal -F_e, F_e must point in the + y direction. E perpendicular does, so this means that our mobile charge is positive (See the previous problem for more explanation of finding the mobile charge). The polarization is determined by analyzing which way the magnetic force (before the Electric force cancels it out) pushes the mobile charge. In this case, the magnetic force pushes the positive mobile charge to the bottom, so negative mobile charges are at the bottom of the block to maintain neutrality. If the positive lead is connected to the place of higher potential (the positive polarization of the block), then the volt meter would read positive. In this case, the positive lead is connected to the place of lower potential, so the voltmeter would be negative.
;Step 3 Substitute for E using <math> ∆V = E*L </math>
: <math> u = \frac{v*L}{∆V} </math>


==Connectedness==
;Step 4 Plug in known  and calculated values
====How is this topic connected to something that you are interested in?====
: <math> u = 2.41*10^{-3} </math>
 
The Hall Effect can be as enjoyable as a puzzle. One has to pull the threads with all of the information that is given and connect the dots. Several key physics laws have to be applied, and the results can be quite practical.
Explanation:
One practical application of the Hall Effect is the Hall Effect Sensor. It is a small sensor that will output a difference in voltage depending on the change in the magnetic field near the sensor. Thanks to this, one of the ways it is used is as a motion sensor, as described below.  
The drift speed of the charge carriers is the product of the electric field and mobility of the charge carriers. Since electric field is not given, but the voltage along the length of the bar is, you have to substitute the electric field with the given voltage divided by the length of the bar. Afterwards, plug in all the values given in the problem and the value calculated for the drift speed.
 
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====How is it connected to your major?====
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==Applications==
Hall effect is all about seeing the relationship between magnetic and electric forces while also remembering how metals polarize. This means that it has a lot of mechanical and machine applications. It can sense when a magnetic field or electric field changes, so it can control many machines, apply pressures, and report many values. All of these skills are very important for Mechanical Engineering, so this topic has a lot of relevance to my major. Moreover, a lot of engineering, in general, is about analyzing concepts before calculating values. The idea of the Hall Effect gives a lot of important data without the use of any numbers (of course it gives more info on the calculation of numbers). This reasoning process required for the Hall Effect is a very helpful skill for engineers to have.  
Hall effect is all about seeing the relationship between magnetic and electric forces while also remembering how metals polarize. This means that it has a lot of mechanical and machine applications. It can sense when a magnetic field or electric field changes, so it can control many machines, apply pressures, and report many values. All of these skills are very important for Mechanical Engineering, so this topic has a lot of relevance to my major. Moreover, a lot of engineering, in general, is about analyzing concepts before calculating values. The idea of the Hall Effect gives a lot of important data without the use of any numbers (of course it gives more info on the calculation of numbers). This reasoning process required for the Hall Effect is a very helpful skill for engineers to have.  


[[File:Screen Shot 2017-12-02 at 3.43.33 AM.png|200px|thumb|left|Hall Effect Sensor with an magnet]]
[[File:Hall sensor tach.gif|thumb|left|Hall Effect Sensor with a magnet]]
[[File:Screen Shot 2017-12-02 at 3.43.08 AM.png|200px|thumb|right|Hall Effect Sensor with an magnet]]
Another field that takes advantage of the Hall Effect is Electrical Engineering thanks to the Hall Effect Sensor. Electrical engineers can use the hall effect sensor to record movement. As seen in the picture to the left, the sensor will increase its voltage the closer the magnet is to the sensor. In fact, a VIP group here at Georgia Tech, the VIP Hands-on Learning team, researched the possibility of using the sensor to measure the movement of a two-degree of freedom spring-mass system.  
[[File:Screen Shot 2017-12-02 at 3.43.20 AM.png|200px|thumb|right|Hall Effect Sensor pinout]]
Another field that takes advantage of the Hall Effect is Electrical Engineering thanks to the Hall Effect Sensor. Electrical engineers can use the hall effect sensor to record movement. As seen in the pictures to the left and to the right, the sensor will increase its voltage the closer the magnet is to the sensor. In fact, a VIP group here at Georgia Tech, the VIP Hands-on Learning team, researched the possibility of using the sensor to measure the movement of a two-degree of freedom spring-mass system.  
Links to the VIP Research: https://vip.gatech.edu/wiki/index.php/Vibrations https://vip.gatech.edu/wiki/index.php/Hall_Effect_Sensor
Links to the VIP Research: https://vip.gatech.edu/wiki/index.php/Vibrations https://vip.gatech.edu/wiki/index.php/Hall_Effect_Sensor


====Is there an interesting industrial application?====
===Industrial===


Hall Effects are used in industry to aid in the control of Hydraulic systems such as moving cranes and backhoes. It is also used to help sense a car wheel's motion to aid in the use of anti-skid/anti-lock brakes. Every smartphone today uses a hall effect sensor as well. This is how the digital compass of a cell phone works. The hall effect senses the change in magnetic field to approximate direction. Another great way of using the hall effect in smartphones is to lock the screen when a case cover is flipped. The cover has a magnet that the smartphone senses, so it locks the screen automatically when the cover is on the screen. A test for this feature can be seen in the following video: https://www.youtube.com/watch?v=ITbT5vrvhX8 .
Hall Effects are used in industry to aid in the control of Hydraulic systems such as moving cranes and backhoes. It is also used to help sense a car wheel's motion to aid in the use of anti-skid/anti-lock brakes. Every smartphone today uses a hall effect sensor as well. This is how the digital compass of a cell phone works. The hall effect senses the change in magnetic field to approximate direction. Another great way of using the hall effect in smartphones is to lock the screen when a case cover is flipped. The cover has a magnet that the smartphone senses, so it locks the screen automatically when the cover is on the screen. A test for this feature can be seen in the following video: https://www.youtube.com/watch?v=ITbT5vrvhX8 .


===Explore its application in a lab setting===
===Laboratory===


Hall effect is also taken into consideration when hall probes are used as magnetometers.  
Hall effect is also taken into consideration when hall probes are used as magnetometers.  


A Hall probe is used to measure the difference of magnetic flux perpendicular to its sensor. this information is then fed to magnetometers to help read the difference in magnetic fields.  
A Hall probe is used to measure the difference of magnetic flux perpendicular to its sensor. This information is then fed to magnetometers to help read the difference in magnetic fields.  


This is a link to buys a hall effect sensor. if you would ever want to buy one!
Hall effect sensor:
http://www.ebay.com/sch/i.html?_nkw=hall+effect+sensor
http://www.ebay.com/sch/i.html?_nkw=hall+effect+sensor


and here is where you can buy a magnetometer
Magnetometer:
http://www.ebay.com/itm/EM2-EARTH-MAGNETOMETER-MAP-MAGNETIC-FIELDS-SURVEY-TOOL-/251324557405?hash=item3a841c685d:m:m8gnViuidubx7vMbMejiNNA
http://www.ebay.com/itm/EM2-EARTH-MAGNETOMETER-MAP-MAGNETIC-FIELDS-SURVEY-TOOL-/251324557405?hash=item3a841c685d:m:m8gnViuidubx7vMbMejiNNA


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[[File:HALL3.jpg|thumb|right|Edwin Herbert Hall]]
[[File:HALL3.jpg|thumb|right|Edwin Herbert Hall]]


The Hall Effect was discovered in 1879 by [[Edwin Hall]] while he was attending Johns Hopkins University for his Doctoral Degree. He exposed a gold leaf (metal slab) to a magnetic field perpendicular to its surface and had current flow through the slab. He observed a potential (delta V) perpendicular to the current and also the magnetic field. This means that potential is observed not only in the direction of current flow as usual. This is what led to Hall's discovery of the Hall Effect.
The Hall Effect was discovered in 1879 by [[Edwin Hall]] while attending Johns Hopkins University for his Doctoral Degree. While a solid mathematical groundwork for electric and magnetic phenomenon had already been discovered by James Clark Maxwell, many of the physical implications and practical uses for these theories was still being explored. The interaction of magnetic and electric fields was a particularly hot topic. Hall exposed a gold leaf (metal slab) to a magnetic field perpendicular to its surface and had current flow through the slab. He observed a potential difference perpendicular to the current and also the magnetic field. This means that potential is observed not only in the direction of current flow as usual. This is what led to Hall's discovery of the Hall Effect, originally published in his paper [https://www.jstor.org/stable/2369245?seq=1#metadata_info_tab_contents|"On a New Action of the Magnet on Electric Currents"].


==Conclusion: Tips to remember==


===CONCLUSION: IF YOU WANT TO REMEMBER ANYTHING, THIS IS IT===
1. When a current carrying metal/conductor is placed in a magnetic field, a voltage is formed perpendicular to both current and magnetic field  
1. When a current carrying metal/conductor is placed in a magnetic field, a voltage is formed perpendicular to both current and magnetic field  


2. The Hall effect is made when the charges create almost a polarized metal, as a result the conductor experience charge carriers
2. The Hall effect is made when the charges create almost a polarized metal, as a result of being subject to a magnetic field perpendicular to the flow of electrons.


3. Right-hand rule whenever in doubt.
3. Right-hand rule whenever in doubt.
Hall effect can only be tested so many ways. There are a few tricks to keep in mind.
[[File:HALL1.png]]
In the diagram above a voltmeter connected to a sheet of metal. Since the voltmeter reads a negative voltage, you can automatically assume that the side connected to the negative terminal of the voltmeter is connected to the positive side of the metal due to hall effect, because voltmeter is reading a charge in the opposite direction.
[[File:HALL2.png]]


== See also ==
== See also ==

Latest revision as of 20:51, 17 April 2020

Edited by Adeline Boswell Fall 2019, Edited by Alayna Baker Spring 2020

The Hall Effect is the electric polarization of a block or slab of metal that occurs when a current is run through it while it is subject to a magnetic field perpendicular to the current.

The Main Idea

When a mobile charge, either positive or negative, flows through a metal block and is influenced by a magnetic field, the magnetic force on the charges force them to begin concentrating on one side of the block. Thus the block polarizes and has negative charges on one side and positive on the other in order to remain neutral. This grouping of positive charges in one part of the block and negative charges in another part of the block creates an electric field and thus an electric force equal on magnitude to the magnetic force that causes the initial polarization, but opposite in direction. The magnetic and electric forces cancel each other out and after some time, the charges flow normally through the block and do not group on one side or the other of the block. This perpendicular electric field also creates a potential difference known as the "Hall Voltage."

Part 1: Normal circuit (No Magnetic Field Yet)

(For simplicity, the mobile charges in this example have already been determined to be negatively charged electrons. This will not always be the case and it should not be assumed that the mobile charges are electrons)

Mobile electrons flow through a wire due to a parallel electric field inside the wire. This electric field is caused by an energy source, most commonly a battery. The parallel electric field flows from an area of high potential (i.e. the positive end of the battery) to an area of low potential (i.e. the negative end of the battery). This is the same direction as the conventional current. Since electrons are negatively charged, they flow in the opposite direction of the parallel electric field.

Part 2: Initial Transient State (Magnetic Field Present)

Mobile electrons are subjected to a magnetic field perpendicular to their motion as they flow through the wire. This results in the mobile charges being forced onto one side of the block by the magnetic force. This grouping of mobile charges on one side of the block creates an electric force. As time passes, more mobile charges are deposited on the side of the block and the electric force increases in magnitude.

Part 3: Steady State (Magnetic Field Still Present, but abated)

Over time massive quantities of charges are concentrated on one side of the block. As the charges build up, they will begin to create a charged area on one surface of the conductor. The charged surface will create an electric force to oppose the magnetic force that is pushing new electrons onto this charged surface. This opposing electric force is called the transverse electric force. When enough mobile charges have collected, their combined transverse electric force will be equal in magnitude to the magnetic force that is holding them. At this point, there is no net vertical force pushing more electrons against the surface of the conductor and these electrons will flow normally again, as they would if there was no magnetic field present. This is called the steady state.

A Mathematical Model

Part 1: Normal circuit (No Magnetic Field Yet)

[math]\displaystyle{ F_{electric, parallel} = qE_{parallel} }[/math]

Where q is the electric charge of the mobile charge. As F and E are vectors, a negative charge results in an electric force in the opposite direction of the electric field.

Part 2: Initial Transient State (Magnetic Field Present)

[math]\displaystyle{ F_{magnetic} = q(v\; &Chi; \;B) }[/math]

Where v is the velocity of the mobile charge and B is the magnetic field. For help calculating the cross product, including an example using the Hall Effect, see Right-Hand_Rule. REMEMBER, the mobile charge will move in the opposite direction of the cross product if it is negative, similar to how it behaves in an electric field.

Part 3: Steady State (Magnetic Field Still Present, but abated)

[math]\displaystyle{ F_{electric, perpendicular} = qE_{perpendicular} }[/math]

[math]\displaystyle{ |F_{electric, perpendicular}| = |F_{magnetic}| }[/math]

Computational Model

In this diagram, it is assumed the charge carrier is a negatively charged electron. THIS IS NOT A SAFE ASSUMPTION on a real question, experiment, or exam but was done for the purpose of simplifying explanations.

Part 1: Normal circuit (No Magnetic Field Yet)

In this diagram a solid conductive metal block is connected to two ends of a battery by wires. At this time there is no magnetic field present and electrons flow through the block in a straight line from wire to wire without interference or interruption.

Part 2: Initial Transient State (Magnetic Field Present)

In this diagram the circles containing x's represent a magnetic field (NOT a magnetic force) into the page. When the electrons begin to move across the block their initial velocity interacts with the magnetic field to create a magnetic force downward. This causes electrons to begin pooling on the bottom face of the slab. This polarizes the block and creates a vertical potential difference across the block. It also creates an electric force that opposes the magnetic force, but in this state it is smaller than the magnetic force, resulting in continued pooling of electrons.

Part 3: Steady State (Magnetic Field Still Present, but abated)

As time passes eventually sufficient quantities of electrons build up to create an electric force equal in magnitude to the magnetic force but opposite in direction. This allows the electrons to continue flow across the block as they did in part 1, however now the vertical voltage difference which was created in part 2 is not only still present but also at its maximum value. Most practice and exam problems will involve either the calculation or orientation of this voltage difference. It's important to remember that a voltmeter will have a positive reading if the positive node is connected to the end of the block which is positively charged and vice versa.

Examples

Simple

A metal block is connected to a battery by two wires. Conventional current flows clockwise and the mobile charge in the block is positive. The block also experiences a magnetic field out of the page denoted by concentric circles. The block is also connected to a voltmeter. The positive end of the voltmeter is connected to the bottom of the block and the negative end of the voltmeter is connected to the top of the block. See attached photo for a diagram. What sign will the voltmeter display?

Click for Solution

In this case, since magnetic force is q(v X B) and we know the charges are positive and thus follow the conventional current which moves across the block from left to right, the magnetic force points up. This means that the mobile charges (positive) will be pushed towards the bottom of the block. Remember: a voltmeter will have a positive reading if the positive end is connected to the positively charged side of the block. In this case, the bottom of the block is positively charged and the positive end of the voltmeter is connected there. The voltmeter will have a positive reading.

A battery and metal block are connected by 2 wires. Conventional current flows clockwise. A magnetic field points out of the page, denoted by concentric circles. A voltmeter is attached to the block with its positive lead at the top of the block and its negative lead at the bottom of the block. The voltmeter has a positive reading. What sign does the mobile charge have?

Click for Solution

From the voltmeter reading we can deduce that the top of the block is positively charged and the bottom negatively charged. Thus, we check if positive mobile charge carriers satisfy this requirement. A positive charge moves with the conventional current, which in this case is from left to right, meaning its velocity would be in the positive x direction. When taking the cross product of the charge's velocity and the magnetic field (out of the page) we get a magnetic force pointing downward, thus meaning the positive charges would be forced downward as well. This is in conflict with the positive voltmeter reading and thus cannot be true. Next we check if negative charge carriers agree with the voltmeter readings. A negatively charged mobile charge carrier moves counter to the conventional current, in this case meaning it moves across the block from right to left resulting in a velocity in the negative x direction. When we take the cross product of this velocity and the magnetic field out of the page multiplied by the charge of the carrier we get a magnetic force pointing downwards (using F = q(v X B). This would result in the block's bottom being negatively charged and the top being positively charged. This result agrees with the given voltmeter reading. The mobile charge carriers are negative.

Middling

[math]\displaystyle{ B = 1.8 T }[/math] out of the page (denoted by concentric circles)

[math]\displaystyle{ n = 7*10^{25} /m^3 }[/math]

[math]\displaystyle{ u = 3*10^{-5} }[/math]

  1. What does reading does the voltmeter display (both magnitude and sign)?
  2. What does reading does the Ammeter display(both magnitude and sign?

Click for Solution to #1

Step 1 Find [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ ΣF_y = q(v\; &Chi; \;B) + q|E_{Hall}| }[/math]
[math]\displaystyle{ 0 = q(v\; &Chi; \;B) + q|E_{Hall}| }[/math]
[math]\displaystyle{ q(v\; &Chi; \;B) = q|E_{Hall}| }[/math]
[math]\displaystyle{ |E_{Hall}| = (v\; &Chi; \;B) }[/math]
[math]\displaystyle{ |E_{Hall}| = |v| * |B| }[/math]
Step 2 Find v
[math]\displaystyle{ I = q*n*A*v }[/math]
[math]\displaystyle{ v = \frac{I}{q*n*A} }[/math]
Step 3 Substitute v into our formula for [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ |E_{Hall}| = \frac{I * |B|}{q*n*A} }[/math]
Step 4
[math]\displaystyle{ σ = q*n*u }[/math]
Step 5
[math]\displaystyle{ R = \frac{L}{σA} }[/math]
Step 6 Substitute σ
[math]\displaystyle{ R = \frac{L}{q*n*u*A} }[/math]
Step 7
[math]\displaystyle{ Emf = I*R }[/math]
Step 8 Substitute R
[math]\displaystyle{ Emf = \frac{I*L}{q*n*u*A} }[/math]
Step 9 Solve for I
[math]\displaystyle{ I = \frac{Emf*q*n*u*A}{L} }[/math]
Step 10 Substitute I in our formula for [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ |E_{Hall}| = \frac{Emf * u * |B|}{L} }[/math]
Step 11
[math]\displaystyle{ ∆V = E * d }[/math]
Step 12 Substitute [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ ∆V = \frac{Emf * u * |B|* h}{L} }[/math]
Step 13 Plug in given values and solve for[math]\displaystyle{ ∆V }[/math]
[math]\displaystyle{ ∆V = -1.767*10^{-5} }[/math]


Explanation: The voltmeter reads the voltage of the bar between the given distance. Since this voltmeter is attached along the height of the bar, the distance is going to be the 3cm. We write out the Lorentz Force formula and set it equal to zero, which makes the magnetic force and electric force equal to each other. After manipulating the equation, the Hall Electric Field is drift sped times the magnetic field. The drift speed is found by manipulating the Current formula, Area density formula, and the Resistance Formula. After I is found, you plug it into the I in the drift speed formula, and plug drift speed v into the Hall electric field formula. Since Hall voltage is Hall electric times the distance, you multiply the calculated Hall electric field with 3 cm in order to get the final Hall voltage.

Click for Solution to #2

[math]\displaystyle{ I = \frac{Emf*q*n*u*A}{L} }[/math]

[math]\displaystyle{ I = 2.19927 A }[/math]

Explanation: You use the derivation of I from first portion of the question and plug in the values to calculate the conventional current. The Area here is the width times the height because the Ammeter is connected through the face created by the area of width and height.

Difficult

[math]\displaystyle{ B = 1.5 }[/math] T out of the page (denoted by concentric circles)

  1. Calculate the drift speed v of the mobile charges
  2. Calculate the charge density n of the mobile charges
  3. ∆V = 13 V along the length of the bar, calculate the mobility u of the mobile charge carrier in the metal

Click for Solution to #1

Step 1 Find [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ ΣF_y = q(v\; &Chi; \;B) + q*E_{Hall} }[/math]
[math]\displaystyle{ 0 = q(v\; &Chi; \;B) + q*E_{Hall} }[/math]
[math]\displaystyle{ q(v\; &Chi; \;B) = q*E_{Hall} }[/math]
[math]\displaystyle{ E_{Hall} = (v\; &Chi; \;B) }[/math]
[math]\displaystyle{ E_{Hall} = v * B }[/math]
Step 2
[math]\displaystyle{ E_{Hall} = \frac{∆V_H}{h} }[/math]
Step 3 Substitute [math]\displaystyle{ E_{Hall} }[/math]
[math]\displaystyle{ v * B = \frac{∆V_H}{h} }[/math]
Step 4 Solve for v
[math]\displaystyle{ v = \frac{∆V_H}{h*B} }[/math]
Step 5 Plug in given values
[math]\displaystyle{ v = 1.367 }[/math] m/s


Explanation: First, set the Lorentz Force Equation equal to zero. After a couple of algebraic manipulations similar to the middling question, the Hall electric field equals to the product of the drift speed and magnetic field. Since, the hall electric field is not given but hall voltage is, you have to substitute the hall electric field with hall voltage divided by the height of the bar (distance that voltmeter calculated). Afterwards, plug in all the given values, and calculate for the drift speed.

Click for Solution to #2

Step 1
[math]\displaystyle{ I = |q|*n*A*v }[/math]
Step 2
[math]\displaystyle{ n = \frac{I}{|q|*A*v} }[/math]
Step 3 Plug in given values and solve
[math]\displaystyle{ n = 9.971 * 10^{23} /m^3 }[/math]

Explanation: In order to find the charge density of the mobile charge carriers use the conventional current formula. Manipulate the conventional current formula to find a formula for charge density and plug in all the values.

Click for Solution to #3

Step 1
[math]\displaystyle{ v = u*E }[/math]
Step 2 Find a formula for u
[math]\displaystyle{ u = \frac{v}{E} }[/math]
Step 3 Substitute for E using [math]\displaystyle{ ∆V = E*L }[/math]
[math]\displaystyle{ u = \frac{v*L}{∆V} }[/math]
Step 4 Plug in known and calculated values
[math]\displaystyle{ u = 2.41*10^{-3} }[/math]

Explanation: The drift speed of the charge carriers is the product of the electric field and mobility of the charge carriers. Since electric field is not given, but the voltage along the length of the bar is, you have to substitute the electric field with the given voltage divided by the length of the bar. Afterwards, plug in all the values given in the problem and the value calculated for the drift speed.

Applications

Hall effect is all about seeing the relationship between magnetic and electric forces while also remembering how metals polarize. This means that it has a lot of mechanical and machine applications. It can sense when a magnetic field or electric field changes, so it can control many machines, apply pressures, and report many values. All of these skills are very important for Mechanical Engineering, so this topic has a lot of relevance to my major. Moreover, a lot of engineering, in general, is about analyzing concepts before calculating values. The idea of the Hall Effect gives a lot of important data without the use of any numbers (of course it gives more info on the calculation of numbers). This reasoning process required for the Hall Effect is a very helpful skill for engineers to have.

Hall Effect Sensor with a magnet

Another field that takes advantage of the Hall Effect is Electrical Engineering thanks to the Hall Effect Sensor. Electrical engineers can use the hall effect sensor to record movement. As seen in the picture to the left, the sensor will increase its voltage the closer the magnet is to the sensor. In fact, a VIP group here at Georgia Tech, the VIP Hands-on Learning team, researched the possibility of using the sensor to measure the movement of a two-degree of freedom spring-mass system. Links to the VIP Research: https://vip.gatech.edu/wiki/index.php/Vibrations https://vip.gatech.edu/wiki/index.php/Hall_Effect_Sensor

Industrial

Hall Effects are used in industry to aid in the control of Hydraulic systems such as moving cranes and backhoes. It is also used to help sense a car wheel's motion to aid in the use of anti-skid/anti-lock brakes. Every smartphone today uses a hall effect sensor as well. This is how the digital compass of a cell phone works. The hall effect senses the change in magnetic field to approximate direction. Another great way of using the hall effect in smartphones is to lock the screen when a case cover is flipped. The cover has a magnet that the smartphone senses, so it locks the screen automatically when the cover is on the screen. A test for this feature can be seen in the following video: https://www.youtube.com/watch?v=ITbT5vrvhX8 .

Laboratory

Hall effect is also taken into consideration when hall probes are used as magnetometers.

A Hall probe is used to measure the difference of magnetic flux perpendicular to its sensor. This information is then fed to magnetometers to help read the difference in magnetic fields.

Hall effect sensor: http://www.ebay.com/sch/i.html?_nkw=hall+effect+sensor

Magnetometer: http://www.ebay.com/itm/EM2-EARTH-MAGNETOMETER-MAP-MAGNETIC-FIELDS-SURVEY-TOOL-/251324557405?hash=item3a841c685d:m:m8gnViuidubx7vMbMejiNNA

To use this idea in a lab, simply create a circuit through a conductive material, like a piece of foil, and calculate the direction of the magnetic field using right-hand rule. Use this information to then properly add the hall probes to the foil so they are perpendicular to the magnetic field, and then BOOM! You will have information to read to a magnetometer.

History

Edwin Herbert Hall

The Hall Effect was discovered in 1879 by Edwin Hall while attending Johns Hopkins University for his Doctoral Degree. While a solid mathematical groundwork for electric and magnetic phenomenon had already been discovered by James Clark Maxwell, many of the physical implications and practical uses for these theories was still being explored. The interaction of magnetic and electric fields was a particularly hot topic. Hall exposed a gold leaf (metal slab) to a magnetic field perpendicular to its surface and had current flow through the slab. He observed a potential difference perpendicular to the current and also the magnetic field. This means that potential is observed not only in the direction of current flow as usual. This is what led to Hall's discovery of the Hall Effect, originally published in his paper "On a New Action of the Magnet on Electric Currents".

Conclusion: Tips to remember

1. When a current carrying metal/conductor is placed in a magnetic field, a voltage is formed perpendicular to both current and magnetic field

2. The Hall effect is made when the charges create almost a polarized metal, as a result of being subject to a magnetic field perpendicular to the flow of electrons.

3. Right-hand rule whenever in doubt.

Hall effect can only be tested so many ways. There are a few tricks to keep in mind.

In the diagram above a voltmeter connected to a sheet of metal. Since the voltmeter reads a negative voltage, you can automatically assume that the side connected to the negative terminal of the voltmeter is connected to the positive side of the metal due to hall effect, because voltmeter is reading a charge in the opposite direction.

See also

Are there related topics or categories in this wiki resource for the curious reader to explore? How does this topic fit into that context?

Combining Electric and Magnetic Forces

Biot-Savart Law for Currents

Lorentz Force

Further reading

Books, Articles or other print media on this topic

Matter and Interactions: Volume 2 by Ruth Chabay and Bruce Sherwood (4th Edition)

http://www.phys.utk.edu/labs/modphys/Hall%20Effect.pdf

External links

Internet resources on this topic

http://hyperphysics.phy-astr.gsu.edu/hbase/magnetic/hall.html

https://www.youtube.com/watch?v=_ATDraCQtpQ

References

https://en.wikipedia.org/wiki/Hall_effect

http://www.nobelprize.org/nobel_prizes/physics/laureates/1998/press.html

https://en.wikipedia.org/wiki/Edwin_Hall

Matter and Interactions: Volume 2 by Ruth Chabay and Bruce Sherwood (4th Edition)

http://www.nasonline.org/publications/biographical-memoirs/memoir-pdfs/hall-edwin.pdf

http://www.electronics-tutorials.ws/electromagnetism/hall-effect.html

https://www.quora.com/What-is-the-use-of-Hall-effect-sensors-in-smartphones