Steady State: Difference between revisions
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===Mathematical Models=== | ===Mathematical Models=== | ||
====Current==== | ====Current==== | ||
There are two ways to describe current in a circuit, the electron current (<math>i</math>), and the conventional current (<math>I</math>). Electron current describes the motion of charges as it actually happens in the circuit: electrons moving through the conductor. Conventional current has the same magnitude and opposite direction as electron current as it describes positive charges moving through a circuit. Although circuits will sometimes act like positive charges are moving through the circuit if there are “electron holes,” it is important to understand that there are not positively charged particles moving through circuits. Even though it is backwards from the physical reality, conventional current is more commonly used because the motion of electrons in circuits was not understood when the first discoveries of electricity were made. | |||
The following formulas can be used to describe electron and conventional current, respectively: | |||
<br><math>i= nA\bar{v}</math> | |||
<math>I= \left | q \right |nA\bar{v}</math> | <math>I= \left | q \right |nA\bar{v}</math> | ||
n = charge density, the number of charged particles per unit volume | |||
A = cross sectional area of the wire | |||
v = drift speed, the speed at which mobile charges move through a section of wire | |||
q=charge of the mobile particles being described (only matters for conventional current) | |||
Keep in mind that drift velocity <math>\bar{v}=\mu \left | E_{applied} \right |</math> | Keep in mind that drift velocity <math>\bar{v}=\mu \left | E_{applied} \right |</math> | ||
Where <math> \mu </math> = electron mobility. | Where <math> \mu </math> = electron mobility. | ||
If you have trouble thinking of this conceptually, imagine a pipe carrying water. For a certain amount of water to move through each part of the pipe per unit time, if the pipe is smaller, the water must move faster and for more water to be delivered, either the speed of the water must increase or the size of the pipe must increase. | |||
====Kirchoff's Node Rule==== | ====Kirchoff's Node Rule==== |
Revision as of 21:10, 18 April 2018
Claimed Alex Dulisse (Spring 2018)
Imagine a circuit in which the only battery has been disconnected. In such a setup there would be no electric field in the circuit and therefore no moving charges so the circuit would be in static equilibrium. When the battery is reconnected, an electric field will quickly propagate through the circuit and the charges in the circuit will accelerate. After a short time, the charges will move at a constant speed through the circuit and the electric field at each part of the circuit will remain unchanged. This means that at any given moment, all properties of the circuit remain unchanged even though an electric field is acting on the charges. At this time, when the state of the circuit does not change with the passage of time, the circuit is said to be in steady state.
The Main Idea
If a circuit is in steady state the following will be true:
- At each part of the circuit, the drift velocity of charges remains unchanged with time.
- The maximum amount of energy has been stored in capacitors, inductors.
- Excess charge only accumulates on the surface of the wire.
- An unchanging voltage exists between any two points in the system.
Each of these bullets is a different way of saying the same thing, that the state of the circuitry that acts on any charges remains unchanged with respect to time. It is important to remember that a circuit being in steady state does not mean that the drift speed is the same every where in the circuit, only that it is unchanging for each specific location in the circuit. Also, a circuit in which there is no current may still be in steady state (such as an RC circuit in which the capacitors are fully charged), as long as there is still a constant electric field in all conductive parts of the circuit.
Mathematical Models
Current
There are two ways to describe current in a circuit, the electron current ([math]\displaystyle{ i }[/math]), and the conventional current ([math]\displaystyle{ I }[/math]). Electron current describes the motion of charges as it actually happens in the circuit: electrons moving through the conductor. Conventional current has the same magnitude and opposite direction as electron current as it describes positive charges moving through a circuit. Although circuits will sometimes act like positive charges are moving through the circuit if there are “electron holes,” it is important to understand that there are not positively charged particles moving through circuits. Even though it is backwards from the physical reality, conventional current is more commonly used because the motion of electrons in circuits was not understood when the first discoveries of electricity were made.
The following formulas can be used to describe electron and conventional current, respectively:
[math]\displaystyle{ i= nA\bar{v} }[/math]
[math]\displaystyle{ I= \left | q \right |nA\bar{v} }[/math]
n = charge density, the number of charged particles per unit volume A = cross sectional area of the wire v = drift speed, the speed at which mobile charges move through a section of wire q=charge of the mobile particles being described (only matters for conventional current)
Keep in mind that drift velocity [math]\displaystyle{ \bar{v}=\mu \left | E_{applied} \right | }[/math]
Where [math]\displaystyle{ \mu }[/math] = electron mobility.
If you have trouble thinking of this conceptually, imagine a pipe carrying water. For a certain amount of water to move through each part of the pipe per unit time, if the pipe is smaller, the water must move faster and for more water to be delivered, either the speed of the water must increase or the size of the pipe must increase.
Kirchoff's Node Rule
In the steady state, each junction of wire (referred to as a "node") obeys the following properties in regard to conventional and electron current:
[math]\displaystyle{ \Sigma I_{in} = \Sigma I_{out} }[/math]
[math]\displaystyle{ \Sigma i_{in} = \Sigma i_{out} }[/math]
This property, known as the Node Rule, means that current is constant throughout a steady state circuit.
A Conceptual Understanding
Because mobile charges are moving (with constant drift speed) in the circuit, there must be an applied electric field inside the wire that causes the mobile charges to move. Since there is no excess charge inside the wire, the electric field must be produced from surface charges. And because this electric field is responsible for moving the mobile charges inside the wire, the direction of the electric field at each location in the circuit must be parallel to the wire.
Once a circuit is described as being in the steady state, there are three things we know to be true. It is true that:
- There must be a constant electric field in the wire.
- The electric field has uniform magnitude throughout wire sections with similar cross-sectional area.
- The electric field is parallel to the wire at every location along the wire.
The electric field and current inside the wire remain constant because the electric force ([math]\displaystyle{ F = qE }[/math]), which acts on the mobile charges and allows them to move through the circuit, is canceled out by the drag force produced by the moving charged particles (measured by the resistance of the wire). Therefore, the net force is zero and by extension, acceleration is also zero.
Steady State vs. Other States
When you assume that a circuit is in steady state, you are assuming that the circuit has been assembled and connected for a long time (such that the current is constant). However, there is a another state that occurs when the circuit is first assembled and before the circuit reaches steady state. While in this Non Steady State or Transient State, the current in the wires are not constant, so circuits have different properties than those in the steady state. This is also true of circuits that have reached Static Equilibrium.
The following chart compares common properties of circuits across various states: at Static Equilibrium, at Steady State, and at Non Steady States.
Static Equilibrium | Steady State | Non Steady State | |
---|---|---|---|
[math]\displaystyle{ \bar{v} }[/math] | [math]\displaystyle{ = 0 }[/math] | [math]\displaystyle{ \neq 0 }[/math] | [math]\displaystyle{ \neq 0 }[/math] |
[math]\displaystyle{ \frac{d\bar{v}}{dt} }[/math] | [math]\displaystyle{ = 0 }[/math] | [math]\displaystyle{ = 0 }[/math] | [math]\displaystyle{ \neq 0 }[/math] |
[math]\displaystyle{ \sum E_{inside} }[/math] | [math]\displaystyle{ = 0 }[/math] | [math]\displaystyle{ \neq 0 }[/math] | [math]\displaystyle{ \neq 0 }[/math] |
Examples
Simple Problem
(Example taken from the OpenStax College Physics Textbook)
Calculate the drift velocity of electrons in a 12-gauge copper wire (which has a diameter of 2.053 mm) carrying a 20.0-A current, given that there is one free electron per copper atom. The density of copper is [math]\displaystyle{ 8.80\times 10^{3} kg/m^3 }[/math].
Solution
First, calculate the density of free electrons in copper. There is one free electron per copper atom. Therefore, is the same as the number of copper atoms per [math]\displaystyle{ m^3 }[/math]. We can now find [math]\displaystyle{ n }[/math] as follows:
[math]\displaystyle{ n= \frac{1e-}{atom}\times \frac{6.02\times10^{23}atoms}{mol}\times \frac{1 mol}{63.54 g} \times \frac{1000 g}{kg} \times \frac{8.80 \times 10^3 kg}{1 m} }[/math]
[math]\displaystyle{ n= 8.342\times 10^{28}e−/m^3 }[/math]
The cross-sectional area of the wire is
[math]\displaystyle{ A= \pi r^2 = \pi(2.053\times10^{−3}m^2) = 23.310 \times 10^{–6}m^2 }[/math]
Rearranging [math]\displaystyle{ I= \left | q \right |nA\bar{v} }[/math] to isolate drift velocity gives you:
[math]\displaystyle{ \bar{v}= \frac{I}{n\left |q \right |A} }[/math]
[math]\displaystyle{ \bar{v}= \frac{20.0A}{(8.342\times10^{28}/m^3) (1.60\times10^{-19}C)(3.310\times10^{-6}m^2)} }[/math]
[math]\displaystyle{ \bar{v}= 4.53\times 10^{–4}m/s }[/math]
Difficult Problem
A circuit made of two wires is in the steady state. The battery has an emf of 1.5 V. Both wires are length 25 cm and made of the same material. The thin wire's diameter is 0.25 mm, and the thick wire's diameter is 0.31 mm. There are [math]\displaystyle{ 4\times 10^{28} }[/math] mobile electrons per cubic meter of this material, and the electron mobility of this material is 0.0006 (m/s)/(V/m).
- If the magnitude of the electric field in the thin wire is 3.5 V/m, what is the electric field in the thick wire?
- What is the drift velocity in the thin and thick wires?
Solution
Question 1
Based on the Node Rule, we know that the electric current is equal in both wires:
[math]\displaystyle{ i_{thick}=i_{thin} }[/math]
We also know that [math]\displaystyle{ i= nA\bar{v} = nA \mu E }[/math]. Therefore:
[math]\displaystyle{ nA_{thick} \mu E_{thick} = nA_{thin} \mu E_{thin} }[/math]
When we rearrange this to solve for [math]\displaystyle{ E_{thick} }[/math], the electron mobility ([math]\displaystyle{ \mu }[/math]) and electron density ([math]\displaystyle{ n }[/math]) cancel out and we are left with:
[math]\displaystyle{ E_{thick}= \frac{A_{thin}E_{thin}}{A_{thick}} }[/math]
The cross-sectional area of the thin wire is [math]\displaystyle{ A_{thin}= \pi (d_{thin}/2)^2 = \pi(0.125\times10^{−3}m^2) = 4.91 \times 10^{–8}m^2. }[/math]
The cross-sectional area of the thick wire is [math]\displaystyle{ A_{thick}= \pi (d_{thick}/2)^2 = \pi(0.155\times10^{−3}m^2) = 7.55 \times 10^{–8}m^2. }[/math]
[math]\displaystyle{ E_{thick}= \frac{(4.91 \times 10^{–8}m^2)(3.5 V/m)}{7.55 \times 10^{–8}m^2} }[/math]
[math]\displaystyle{ E_{thick}=2.28 V/m }[/math]
Question 2
We know that [math]\displaystyle{ \bar{v}=\mu \left | E_{applied} \right | }[/math].
The drift velocity of the thin wire is [math]\displaystyle{ \bar{v}=\mu E_{thin} = [0.0006 (m/s)/(V/m)][3.5 V/m]= 2.10 \times 10^{–3} m/s }[/math].
The drift velocity of the thick wire is [math]\displaystyle{ \bar{v}=\mu E_{thick} = [0.0006 (m/s)/(V/m)][2.28 V/m]= 1.37 \times 10^{–3} m/s }[/math].
Connectedness
As a biomedical engineer, the idea of steady state circuits is surprisingly interesting to me because the process of reaching steady state in a circuit is much like the process of maintaining homeostasis in the human body.
In the field of biochemistry, steady state can be related to cells. In ionic steady state, cells maintain different internal and external concentrations of various ionic species with the cell. If the cells are not in steady state, this means there is equilibrium. With steady state, there is not an equilibrium establishes meaning both the inner and outer cell are never equal in concentration. There are continuous ions moving within and out of the cell.
See also
- Current
- Fundamentals of Resistance
- Node Rule
- Loop Rule
- Ohm's Law
- RL Circuit
- Series Circuits
- Parallel Circuits