resistivity experiment variables

Core Practical 7: Investigating Resistivity ( Edexcel International A Level Physics )

Revision note.

Core Practical 7: Investigating Resistivity

Aims of the experiment.

The aim of the experiment is to determine the resistivity of a length of wire
Independent variable = Length, L , of the wire (m)
Dependent variable = The current, I , through the wire (A)
Voltage across the wire
The material the wire is made from

Equipment List

Metre ruler = 1 mm
Micrometer screw gauge = 0.01 mm
Voltmeter = 0.1 V
Ammeter = 0.01 A

Apparatus diagram, downloadable AS & A Level Physics revision notes

The measurement should be taken between 5-10 times randomly along the wire.
Calculate the mean diameter from these values
The ammeter is connected in series and the voltmeter in parallel with the wire
Check that this is the voltage across the wire on the voltmeter
This is to prevent the wire from heating up and changing the resistivity
In this example, a 2.0 m wire is used.
The original length and the intervals can be changed (e.g. start at 0.1 m and increase in 0.1 m intervals), as long as there are 8-10 readings
Record the current for each length at least 3 times and calculate an average current, I
For each length, calculate the average resistance of the length of the wire using the equation

R = average resistance of the length of the wire (Ω)
V = potential difference across the circuit (V)
I = the average current through the wire for the chosen length (A)
An example of a table of results might look like this:

Example table of Results, downloadable AS & A Level Physics revision notes

Analysis of Results

The resistivity, ρ , of the wire is equal to

ρ = resistivity (Ω m)
R = resistance (Ω)
A = cross-sectional area of the wire (m 2 )
L = length of wire (m)
Rearranging for the resistance, R, gives:

Gradient, m = ρ / A
Plot a graph of the length of the wire, L , against the average resistance of the wire
Draw a line of best fit
Calculate the gradient
Multiply the gradient by cross-sectional area, A

ρ = gradient × A

Example Graph sketch, downloadable AS & A Level Physics revision notes

Evaluating the Experiment

Systematic Errors:

Otherwise, this could cause a zero error in your measurements of the length

Random Errors:

The resistivity of a material depends on its temperature
The current flowing through the wire will cause its temperature to increase
Therefore the temperature is kept constant by small currents
So that there isn't a temperature rise
This will reduce random errors in the reading
Make at least 5-10 measurements of the diameter of the wire with the micrometer

Safety Considerations

Make sure never to touch the wire directly when the circuit is switched on
Switch off the power supply right away if you smell burning
This could damage the electrical equipment
Or cause a short circuit which will affect the results

Worked example

A student conducts an experiment to find the resistivity of a constantan wire.

They attach one end of the wire to a circuit that contains a 6.0 V battery. The other end of the wire is attached by a flying lead to the wire at different lengths.

Worked example table 1, downloadable AS & A Level Physics revision notes

Step 1: Complete the average current and resistance columns in the table

The resistance is calculated using the equation

Worked example solution table, downloadable AS & A Level Physics revision notes

Step 2: Calculate the cross-sectional area of the wire from the diameter

The average diameter is 0.191 mm = 0.191 × 10 –3 m
The cross-sectional area is equal to

Step 3: Plot a graph of the length L against the resistance R

Worked example gradient from graph 1, downloadable AS & A Level Physics revision notes

Step 4: Calculate the gradient of the graph

Worked example gradient from graph, downloadable AS & A Level Physics revision notes

Step 5: Calculate the resistivity of the wire

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9.4: Resistivity and Resistance

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Learning Objectives

By the end of this section, you will be able to:

Differentiate between resistance and resistivity
Define the term conductivity
Describe the electrical component known as a resistor
State the relationship between resistance of a resistor and its length, cross-sectional area, and resistivity
State the relationship between resistivity and temperature

What drives current? We can think of various devices—such as batteries, generators, wall outlets, and so on—that are necessary to maintain a current. All such devices create a potential difference and are referred to as voltage sources. When a voltage source is connected to a conductor, it applies a potential difference V that creates an electrical field. The electrical field, in turn, exerts force on free charges, causing current. The amount of current depends not only on the magnitude of the voltage, but also on the characteristics of the material that the current is flowing through. The material can resist the flow of the charges, and the measure of how much a material resists the flow of charges is known as the resistivity . This resistivity is crudely analogous to the friction between two materials that resists motion.

Resistivity

When a voltage is applied to a conductor, an electrical field \(\vec{E}\) is created, and charges in the conductor feel a force due to the electrical field. The current density \(\vec{J}\) that results depends on the electrical field and the properties of the material. This dependence can be very complex. In some materials, including metals at a given temperature, the current density is approximately proportional to the electrical field. In these cases, the current density can be modeled as

\[\vec{J} = \sigma \vec{E},\]

where \(\sigma\) is the electrical conductivity . The electrical conductivity is analogous to thermal conductivity and is a measure of a material’s ability to conduct or transmit electricity. Conductors have a higher electrical conductivity than insulators. Since the electrical conductivity is \(\sigma = J/E\), the units are

\[\sigma = \dfrac{|J|}{|E|} = \dfrac{A/m^2}{V/m} = \dfrac{A}{V \cdot m}.\]

Here, we define a unit named the ohm with the Greek symbol uppercase omega, \(\Omega\). The unit is named after Georg Simon Ohm, whom we will discuss later in this chapter. The \(\Omega\) is used to avoid confusion with the number 0. One ohm equals one volt per amp: \(1 \, \Omega = 1 \, V/A\). The units of electrical conductivity are therefore \((\Omega \cdot m)^{-1}\).

Conductivity is an intrinsic property of a material. Another intrinsic property of a material is the resistivity , or electrical resistivity . The resistivity of a material is a measure of how strongly a material opposes the flow of electrical current. The symbol for resistivity is the lowercase Greek letter rho, \(\rho\), and resistivity is the reciprocal of electrical conductivity:

\[\rho = \dfrac{1}{\sigma}.\]

The unit of resistivity in SI units is the ohm-meter \((\Omega \cdot m\). We can define the resistivity in terms of the electrical field and the current density.

\[\rho = \dfrac{E}{J}.\]

The greater the resistivity, the larger the field needed to produce a given current density. The lower the resistivity, the larger the current density produced by a given electrical field. Good conductors have a high conductivity and low resistivity. Good insulators have a low conductivity and a high resistivity. Table \(\PageIndex{1}\) lists resistivity and conductivity values for various materials.

Table \(\PageIndex{1}\): Resistivities and Conductivities of Various Materials at 20 °C[1] Values depend strongly on amounts and types of impurities.
	\(\sigma\) \((\Omega \cdot m)^{-1}\)	\(\rho\) \((\Omega \cdot m)\)	\(\alpha\) \((^oC)^{-1}\)

Silver	\(6.29 \times 10^7\)	\(1.59 \times 10^{-8}\)	0.0038
Copper	\(5.95 \times 10^7\)	\(1.68 \times 10^{-8}\)	0.0039
Gold	\(4.10 \times 10^7\)	\(2.44 \times 10^{-8}\)	0.0034
Aluminum	\(3.77 \times 10^7\)	\(2.65 \times 10^{-8}\)	0.0039
Tungsten	\(1.79 \times 10^7\)	\(5.60 \times 10^{-8}\)	0.0045
Iron	\(1.03 \times 10^7\)	\(9.71 \times 10^{-8}\)	0.0065
Platinum	\(0.94 \times 10^7\)	\(10.60 \times 10^{-8}\)	0.0039
Steel	\(0.50 \times 10^7\)	\(20.00 \times 10^{-8}\)
Lead	\(0.45 \times 10^7\)	\(22.00 \times 10^{-8}\)
Manganin (Cu, Mn. Ni alloy)	\(0.21 \times 10^7\)	\(48.20 \times 10^{-8}\)	0.000002
Constantan (Cu, Ni alloy)	\(0.20 \times 10^7\)	\(49.00 \times 10^{-8}\)	0.00003
Mercury	\(0.10 \times 10^7\)	\(98.00 \times 10^{-8}\)	0.0009
Nichrome (Ni, Fe, Cr alloy)	\(0.10 \times 10^7\)	\(100.00 \times 10^{-8}\)	0.0004

Carbon (pure)	\(2.86 \times 10^{4}\)	\(3.50 \times 10^{-5}\)	-0.0005
Carbon	\((2.86 - 1.67) \times 10^{-6}\)	\((3.5 - 60) \times 10^{-5}\)	-0.0005
Germanium (pure)		\(600 \times 10^{-3}\)	-0.048
Germanium		\((1 - 600) \times 10^{-3}\)	-0.050
Silicon (pure)		2300	-0.075
Silicon		0.1 - 2300	-0.07

Amber	\(2.00 \times 10^{-15}\)	\(5 \times 10^{14}\)
Glass	\(10^{-9} - 19^{-14}\)	\(10^9 - 10^{14}\)
Lucite	\(< 10^{-13}\)	\(> 10^{13}\)
Mica	\(10^{-11} - 10^{-15}\)	\(10^{11} - 10^{15}\)
Quartz (fused)	\(1.33 \times 10^{-18}\)	\(75 \times 10^{16}\)
Rubber (hard)	\(10^{-13} - 10^{-16}\)	\(10^{13} - 10^{16}\)
Sulfur	\(10^{-15}\)	\(10^{15}\)
Teflon	\(< 10^{-13}\)	\(> 10^{13}\)
Wood	\(10^{-8} - 10^{-11}\)	\(10^8 - 10^{11}\)

The materials listed in the table are separated into categories of conductors, semiconductors, and insulators, based on broad groupings of resistivity. Conductors have the smallest resistivity, and insulators have the largest; semiconductors have intermediate resistivity. Conductors have varying but large, free charge densities, whereas most charges in insulators are bound to atoms and are not free to move. Semiconductors are intermediate, having far fewer free charges than conductors, but having properties that make the number of free charges depend strongly on the type and amount of impurities in the semiconductor. These unique properties of semiconductors are put to use in modern electronics, as we will explore in later chapters.

Example \(\PageIndex{1}\): Current Density, Resistance, and Electrical field for a Current-Carrying Wire

Calculate the current density, resistance, and electrical field of a 5-m length of copper wire with a diameter of 2.053 mm (12-gauge) carrying a current of \(I - 10 \, mA\).

We can calculate the current density by first finding the cross-sectional area of the wire, which is \(A = 3.31 \, mm^2\), and the definition of current density \(J = \dfrac{I}{A}\). The resistance can be found using the length of the wire \(L = 5.00 \, m\), the area, and the resistivity of copper \(\rho = 1.68 \times 10^{-8} \Omega \cdot m\), where \(R = \rho \dfrac{L}{A}\). The resistivity and current density can be used to find the electrical field.

First, we calculate the current density:

\[\begin {align*} J &= \dfrac{I}{A} \\[5pt] &= \dfrac{10 \times 10^{-3} A}{3.31 \times 10^{-6} m^2} \\[5pt] &= 3.02 \times 10^3 \dfrac{A}{m^2}. \end{align*}\]

The resistance of the wire is

\[\begin {align*}R &= \rho \dfrac{L}{A} \\[5pt] &= (1.68 \times 10^{-8} \Omega \cdot m) \dfrac{5.00 \, m}{3.31 \times 10^{-6}m^2} \\[5pt] &= 0.025 \, \Omega.\end{align*}\]

Finally, we can find the electrical field:

\[\begin {align*}E &= \rho J \\[5pt] &= 1.68 \times 10^{-8} \Omega \cdot m \left(3.02 \times 10^3 \dfrac{A}{m^2}\right) \\[5pt] &= 5.07 \times 10^{-5} \dfrac{V}{m}.\end{align*}\]

Significance

From these results, it is not surprising that copper is used for wires for carrying current because the resistance is quite small. Note that the current density and electrical field are independent of the length of the wire, but the voltage depends on the length.

Exercise \(\PageIndex{1}\)

Copper wires use routinely used for extension cords and house wiring for several reasons. Copper has the highest electrical conductivity rating, and therefore the lowest resistivity rating, of all nonprecious metals. Also important is the tensile strength, where the tensile strength is a measure of the force required to pull an object to the point where it breaks. The tensile strength of a material is the maximum amount of tensile stress it can take before breaking. Copper has a high tensile strength, \(2 \times 10^8 \, \dfrac{N}{m^2}\). A third important characteristic is ductility. Ductility is a measure of a material’s ability to be drawn into wires and a measure of the flexibility of the material, and copper has a high ductility. Summarizing, for a conductor to be a suitable candidate for making wire, there are at least three important characteristics: low resistivity, high tensile strength, and high ductility. What other materials are used for wiring and what are the advantages and disadvantages?

Silver, gold, and aluminum are all used for making wires. All four materials have a high conductivity, silver having the highest. All four can easily be drawn into wires and have a high tensile strength, though not as high as copper. The obvious disadvantage of gold and silver is the cost, but silver and gold wires are used for special applications, such as speaker wires. Gold does not oxidize, making better connections between components. Aluminum wires do have their drawbacks. Aluminum has a higher resistivity than copper, so a larger diameter is needed to match the resistance per length of copper wires, but aluminum is cheaper than copper, so this is not a major drawback. Aluminum wires do not have as high of a ductility and tensile strength as copper, but the ductility and tensile strength is within acceptable levels. There are a few concerns that must be addressed in using aluminum and care must be used when making connections. Aluminum has a higher rate of thermal expansion than copper, which can lead to loose connections and a possible fire hazard. The oxidation of aluminum does not conduct and can cause problems. Special techniques must be used when using aluminum wires and components, such as electrical outlets, must be designed to accept aluminum wires.

View this interactive simulation to see what the effects of the cross-sectional area, the length, and the resistivity of a wire are on the resistance of a conductor. Adjust the variables using slide bars and see if the resistance becomes smaller or larger.

Temperature Dependence of Resistivity

Looking back at Table \(\PageIndex{1}\), you will see a column labeled “Temperature Coefficient.” The resistivity of some materials has a strong temperature dependence. In some materials, such as copper, the resistivity increases with increasing temperature. In fact, in most conducting metals, the resistivity increases with increasing temperature. The increasing temperature causes increased vibrations of the atoms in the lattice structure of the metals, which impede the motion of the electrons. In other materials, such as carbon, the resistivity decreases with increasing temperature. In many materials, the dependence is approximately linear and can be modeled using a linear equation:

\[\rho \approx \rho_0 [1 + \alpha (T - T_0)],\]

where \(\rho\) is the resistivity of the material at temperature T , \(\alpha\) is the temperature coefficient of the material, and \(\rho_0\) is the resistivity at \(T_0\), usually taken as \(T_0 = 20.00^oC\).

Note also that the temperature coefficient \(\alpha\) is negative for the semiconductors listed in Table \(\PageIndex{1}\), meaning that their resistivity decreases with increasing temperature. They become better conductors at higher temperature, because increased thermal agitation increases the number of free charges available to carry current. This property of decreasing \(\rho\) with temperature is also related to the type and amount of impurities present in the semiconductors.

We now consider the resistance of a wire or component. The resistance is a measure of how difficult it is to pass current through a wire or component. Resistance depends on the resistivity. The resistivity is a characteristic of the material used to fabricate a wire or other electrical component, whereas the resistance is a characteristic of the wire or component.

To calculate the resistance, consider a section of conducting wire with cross-sectional area A , length L , and resistivity \(\rho\). A battery is connected across the conductor, providing a potential difference \(\Delta V\) across it (Figure \(\PageIndex{1}\)). The potential difference produces an electrical field that is proportional to the current density, according to \(\vec{E} = \rho \vec{J}\).

Picture is a schematic drawing of a battery connected to a conductor with the cross-sectional area A. Current flows from high potential side to the low potential side of the conductor.

The magnitude of the electrical field across the segment of the conductor is equal to the voltage divided by the length, \(E = V/L\), and the magnitude of the current density is equal to the current divided by the cross-sectional area, \(J = I/A\). Using this information and recalling that the electrical field is proportional to the resistivity and the current density, we can see that the voltage is proportional to the current:

\[\begin{align*} E &= \rho J \\[4pt] \dfrac{V}{L} &= \rho \dfrac{I}{A} \\[4pt] V &= \left(\rho \dfrac{L}{A}\right) I. \end{align*}\]

Definition: Resistance

The ratio of the voltage to the current is defined as the resistance \(R\):

\[R \equiv \dfrac{V}{I}.\]

The resistance of a cylindrical segment of a conductor is equal to the resistivity of the material times the length divided by the area:

\[R \equiv \dfrac{V}{I} = \rho \dfrac{L}{A}.\]

The unit of resistance is the ohm, \(\Omega\). For a given voltage, the higher the resistance, the lower the current.

A common component in electronic circuits is the resistor. The resistor can be used to reduce current flow or provide a voltage drop. Figure \(\PageIndex{2}\) shows the symbols used for a resistor in schematic diagrams of a circuit. Two commonly used standards for circuit diagrams are provided by the American National Standard Institute (ANSI, pronounced “AN-see”) and the International Electrotechnical Commission (IEC). Both systems are commonly used. We use the ANSI standard in this text for its visual recognition, but we note that for larger, more complex circuits, the IEC standard may have a cleaner presentation, making it easier to read.

Figure A shows the ANSI symbol for a resistor. Figure B shows the IEC symbol for a resistor.

Material and shape dependence of resistance

A resistor can be modeled as a cylinder with a cross-sectional area A and a length L , made of a material with a resistivity \(\rho\) (Figure \(\PageIndex{3}\)). The resistance of the resistor is \(R = \rho \dfrac{L}{A}\)

Picture is a schematic drawing of a resistor. It is a uniform cylinder of length L and cross-sectional area A.

The most common material used to make a resistor is carbon. A carbon track is wrapped around a ceramic core, and two copper leads are attached. A second type of resistor is the metal film resistor, which also has a ceramic core. The track is made from a metal oxide material, which has semiconductive properties similar to carbon. Again, copper leads are inserted into the ends of the resistor. The resistor is then painted and marked for identification. A resistor has four colored bands, as shown in Figure \(\PageIndex{4}\).

Picture is a schematic drawing of a resistor. It contains four colored bands: red, black, green, and grey.

Resistances range over many orders of magnitude. Some ceramic insulators, such as those used to support power lines, have resistances of \(10^{12} \, \Omega\) or more. A dry person may have a hand-to-foot resistance of \(10^5 \, \Omega\) whereas the resistance of the human heart is about \(10^3 \, \Omega\) A meter-long piece of large-diameter copper wire may have a resistance of \(10^{-5} \, \Omega\), and superconductors have no resistance at all at low temperatures. As we have seen, resistance is related to the shape of an object and the material of which it is composed.

The resistance of an object also depends on temperature, since \(R_0\) is directly proportional to \(\rho\). For a cylinder, we know \(R = \rho \dfrac{L}{A}\), so if L and A do not change greatly with temperature, R has the same temperature dependence as \(\rho\). (Examination of the coefficients of linear expansion shows them to be about two orders of magnitude less than typical temperature coefficients of resistivity, so the effect of temperature on L and A is about two orders of magnitude less than on \(\rho\).) Thus,

\[R = R_0(1 + \alpha \Delta T) \label{Tdep}\]

is the temperature dependence of the resistance of an object, where \(R_0\) is the original resistance (usually taken to be \(T = 20.00^oC\) and R is the resistance after a temperature change \(\Delta T\). The color code gives the resistance of the resistor at a temperature of \(T = 20.00^oC\).

Numerous thermometers are based on the effect of temperature on resistance (Figure \(\PageIndex{5}\)). One of the most common thermometers is based on the thermistor, a semiconductor crystal with a strong temperature dependence, the resistance of which is measured to obtain its temperature. The device is small, so that it quickly comes into thermal equilibrium with the part of a person it touches.

Picture is a photograph of two digital oral thermometers.

Example \(\PageIndex{2}\): Calculating Resistance

Although caution must be used in applying \(\rho = \rho_0 (1 + \alpha \Delta T)\) and \(R = R_0(1 + \alpha \Delta T)\) for temperature changes greater than \(100^oC\), for tungsten, the equations work reasonably well for very large temperature changes. A tungsten filament at \(20^oC\) has a resistance of \(0.350 \, \Omega\). What would the resistance be if the temperature is increased to \(2850^oC\)?

This is a straightforward application of Equation \ref{Tdep}, since the original resistance of the filament is given as \(R_0 = 0.350 \, \Omega\) and the temperature change is \(\Delta T = 2830^oC\).

The resistance of the hotter filament \(R\) is obtained by entering known values into the above equation:

\[\begin{align*} R &= R_0(1 + \alpha \Delta T) \\[5pt] &= (0.350 \, \Omega)\left(1 + \left(\dfrac{4.5 \times 10^{-3}}{^oC}\right)(2830^oC)\right) \\[5pt] &= 4.8 \, \Omega \end{align*} \]

Notice that the resistance changes by more than a factor of 10 as the filament warms to the high temperature and the current through the filament depends on the resistance of the filament and the voltage applied. If the filament is used in an incandescent light bulb, the initial current through the filament when the bulb is first energized will be higher than the current after the filament reaches the operating temperature.

Exercise \(\PageIndex{2}\)

A strain gauge is an electrical device to measure strain, as shown below. It consists of a flexible, insulating backing that supports a conduction foil pattern. The resistance of the foil changes as the backing is stretched. How does the strain gauge resistance change? Is the strain gauge affected by temperature changes?

Picture is a schematic drawing of a strain gauge device that consists of the conducting pattern deposited on the insulated surface. Metal contacts are made to the two large pads at the origin of the conducting pattern

The foil pattern stretches as the backing stretches, and the foil tracks become longer and thinner. Since the resistance is calculated as \(R = \rho \dfrac{L}{A}\), the resistance increases as the foil tracks are stretched. When the temperature changes, so does the resistivity of the foil tracks, changing the resistance. One way to combat this is to use two strain gauges, one used as a reference and the other used to measure the strain. The two strain gauges are kept at a constant temperature

The Resistance of Coaxial Cable

Long cables can sometimes act like antennas, picking up electronic noise, which are signals from other equipment and appliances. Coaxial cables are used for many applications that require this noise to be eliminated. For example, they can be found in the home in cable TV connections or other audiovisual connections. Coaxial cables consist of an inner conductor of radius \(r_i\) surrounded by a second, outer concentric conductor with radius \(r_0\) (Figure \(\PageIndex{6}\)). The space between the two is normally filled with an insulator such as polyethylene plastic. A small amount of radial leakage current occurs between the two conductors. Determine the resistance of a coaxial cable of length L .

Picture is a schematic drawing of a coaxial cable. It consists of a central metal core encapsulated by the dielectric insulator. Metal shield surrounds dielectric insulator. The whole assembly in inserted in the plastic jacket.

We cannot use the equation \(R = \rho \dfrac{L}{A}\) directly. Instead, we look at concentric cylindrical shells, with thickness dr , and integrate.

We first find an expression for \(dR\) and then integrate from \(r_i\) to \(r_0\),

\[\begin{align*} dR &= \dfrac{\rho}{A} dr \\[5pt] &= \dfrac{\rho}{2 \pi r L} dr, \end{align*}\]

Integrating both sides

\[\begin{align*} R &= \int_{r_i}^{r_0} dR \\[5pt] &= \int_{r_i}^{r_0} \dfrac{\rho}{2 \pi r L} dr \\[5pt] &= \dfrac{\rho}{2\pi L} \int_{r_i}^{r_0} \dfrac{1}{r} dr \\[5pt] &= \dfrac{\rho}{2\pi L} \ln \dfrac{r_0}{r_i}.\end{align*}\]

The resistance of a coaxial cable depends on its length, the inner and outer radii, and the resistivity of the material separating the two conductors. Since this resistance is not infinite, a small leakage current occurs between the two conductors. This leakage current leads to the attenuation (or weakening) of the signal being sent through the cable.

Exercise \(\PageIndex{3}\)

The resistance between the two conductors of a coaxial cable depends on the resistivity of the material separating the two conductors, the length of the cable and the inner and outer radius of the two conductor. If you are designing a coaxial cable, how does the resistance between the two conductors depend on these variables?

The longer the length, the smaller the resistance. The greater the resistivity, the higher the resistance. The larger the difference between the outer radius and the inner radius, that is, the greater the ratio between the two, the greater the resistance. If you are attempting to maximize the resistance, the choice of the values for these variables will depend on the application. For example, if the cable must be flexible, the choice of materials may be limited.

Phet: Battery-Resistor Circuit

View this simulation to see how the voltage applied and the resistance of the material the current flows through affects the current through the material. You can visualize the collisions of the electrons and the atoms of the material effect the temperature of the material.

9.3 Resistivity and Resistance

Learning objectives.

By the end of this section, you will be able to:

Differentiate between resistance and resistivity
Define the term conductivity
Describe the electrical component known as a resistor
State the relationship between resistance of a resistor and its length, cross-sectional area, and resistivity
State the relationship between resistivity and temperature

Resistivity

When a voltage is applied to a conductor, an electrical field E → E → is created, and charges in the conductor feel a force due to the electrical field. The current density J → J → that results depends on the electrical field and the properties of the material. This dependence can be very complex. In some materials, including metals at a given temperature, the current density is approximately proportional to the electrical field. In these cases, the current density can be modeled as

where σ σ is the electrical conductivity . The electrical conductivity is analogous to thermal conductivity and is a measure of a material’s ability to conduct or transmit electricity. Conductors have a higher electrical conductivity than insulators. Since the electrical conductivity is σ = J / E σ = J / E , the units are

Here, we define a unit named the ohm with the Greek symbol uppercase omega, Ω Ω . The unit is named after Georg Simon Ohm, whom we will discuss later in this chapter. The Ω Ω is used to avoid confusion with the number 0. One ohm equals one volt per amp: 1 Ω = 1 V/A 1 Ω = 1 V/A . The units of electrical conductivity are therefore ( Ω · m ) −1 ( Ω · m ) −1 .

Conductivity is an intrinsic property of a material. Another intrinsic property of a material is the resistivity , or electrical resistivity. The resistivity of a material is a measure of how strongly a material opposes the flow of electrical current. The symbol for resistivity is the lowercase Greek letter rho, ρ ρ , and resistivity is the reciprocal of electrical conductivity:

The unit of resistivity in SI units is the ohm-meter ( Ω · m ) ( Ω · m ) . We can define the resistivity in terms of the electrical field and the current density,

The greater the resistivity, the larger the field needed to produce a given current density. The lower the resistivity, the larger the current density produced by a given electrical field. Good conductors have a high conductivity and low resistivity. Good insulators have a low conductivity and a high resistivity. Table 9.1 lists resistivity and conductivity values for various materials.

Material	Resistivity,	Temperature Coefficient,

Silver		0.0038
Copper		0.0039
Gold		0.0034
Aluminum		0.0039
Tungsten		0.0045
Iron		0.0065
Platinum		0.0039
Steel
Lead
Manganin (Cu, Mn, Ni alloy)		0.000002
Constantan (Cu, Ni alloy)		0.00003
Mercury		0.0009
Nichrome (Ni, Fe, Cr alloy)		0.0004
[1]
Carbon (pure)		−0.0005
Carbon		−0.0005
Germanium (pure)		−0.048
Germanium		−0.050
Silicon (pure)	2300	−0.075
Silicon		−0.07

Amber
Glass
Lucite
Mica
Quartz (fused)
Rubber (hard)
Sulfur
Teflon
Wood

Check Your Understanding 9.5

Copper wires are routinely used for extension cords and house wiring for several reasons. Copper has the highest electrical conductivity rating, and therefore the lowest resistivity rating, of all nonprecious metals. Also important is the tensile strength, where the tensile strength is a measure of the force required to pull an object to the point where it breaks. The tensile strength of a material is the maximum amount of tensile stress it can take before breaking. Copper has a high tensile strength, 2 × 10 8 N m 2 2 × 10 8 N m 2 . A third important characteristic is ductility. Ductility is a measure of a material’s ability to be drawn into wires and a measure of the flexibility of the material, and copper has a high ductility. Summarizing, for a conductor to be a suitable candidate for making wire, there are at least three important characteristics: low resistivity, high tensile strength, and high ductility. What other materials are used for wiring and what are the advantages and disadvantages?

Temperature Dependence of Resistivity

Looking back at Table 9.1 , you will see a column labeled “Temperature Coefficient.” The resistivity of some materials has a strong temperature dependence. In some materials, such as copper, the resistivity increases with increasing temperature. In fact, in most conducting metals, the resistivity increases with increasing temperature. The increasing temperature causes increased vibrations of the atoms in the lattice structure of the metals, which impede the motion of the electrons. In other materials, such as carbon, the resistivity decreases with increasing temperature. In many materials, the dependence is approximately linear and can be modeled using a linear equation:

where ρ ρ is the resistivity of the material at temperature T , α α is the temperature coefficient of the material, and ρ 0 ρ 0 is the resistivity at T 0 T 0 , usually taken as T 0 = 20.00 ° C T 0 = 20.00 ° C .

Note also that the temperature coefficient α α is negative for the semiconductors listed in Table 9.1 , meaning that their resistivity decreases with increasing temperature. They become better conductors at higher temperature, because increased thermal agitation increases the number of free charges available to carry current. This property of decreasing ρ ρ with temperature is also related to the type and amount of impurities present in the semiconductors.

To calculate the resistance, consider a section of conducting wire with cross-sectional area A , length L , and resistivity ρ . ρ . A battery is connected across the conductor, providing a potential difference Δ V Δ V across it ( Figure 9.13 ). The potential difference produces an electrical field that is proportional to the current density, according to E → = ρ J → E → = ρ J → .

The magnitude of the electrical field across the segment of the conductor is equal to the voltage divided by the length, E = V / L E = V / L , and the magnitude of the current density is equal to the current divided by the cross-sectional area, J = I / A . J = I / A . As with capacitance, we use V to represent the potential difference ΔV across the resistor. Using this information and recalling that the electrical field is proportional to the resistivity and the current density, we can see that the voltage is proportional to the current:

The ratio of the voltage to the current is defined as the resistance R :

The resistance of a cylindrical segment of a conductor is equal to the resistivity of the material times the length divided by the area:

The unit of resistance is the ohm, Ω Ω . For a given voltage, the higher the resistance, the lower the current.

A common component in electronic circuits is the resistor. The resistor can be used to reduce current flow or provide a voltage drop. Figure 9.14 shows the symbols used for a resistor in schematic diagrams of a circuit. Two commonly used standards for circuit diagrams are provided by the American National Standard Institute (ANSI, pronounced “AN-see”) and the International Electrotechnical Commission (IEC). Both systems are commonly used. We use the ANSI standard in this text for its visual recognition, but we note that for larger, more complex circuits, the IEC standard may have a cleaner presentation, making it easier to read.

Material and shape dependence of resistance

A resistor can be modeled as a cylinder with a cross-sectional area A and a length L , made of a material with a resistivity ρ ρ ( Figure 9.15 ). The resistance of the resistor is R = ρ L A R = ρ L A .

Resistances range over many orders of magnitude. Some ceramic insulators, such as those used to support power lines, have resistances of 10 12 Ω 10 12 Ω or more. A dry person may have a hand-to-foot resistance of 10 5 Ω 10 5 Ω , whereas the resistance of the human heart is about 10 3 Ω 10 3 Ω . A meter-long piece of large-diameter copper wire may have a resistance of 10 −5 Ω 10 −5 Ω , and superconductors have no resistance at all at low temperatures. As we have seen, resistance is related to the shape of an object and the material of which it is composed.

Example 9.5

Current density, resistance, and electrical field for a current-carrying wire.

The resistance of the wire is

Finally, we can find the electrical field:

Significance

Interactive.

Engage the simulation below to see what the effects of the cross-sectional area, the length, and the resistivity of a wire are on the resistance of a conductor. Adjust the variables using slide bars and see if the resistance becomes smaller or larger.

The resistance of an object also depends on temperature, since R 0 R 0 is directly proportional to ρ . ρ . For a cylinder, we know R = ρ L A R = ρ L A , so if L and A do not change greatly with temperature, R has the same temperature dependence as ρ . ρ . (Examination of the coefficients of linear expansion shows them to be about two orders of magnitude less than typical temperature coefficients of resistivity, so the effect of temperature on L and A is about two orders of magnitude less than on ρ . ) ρ . ) Thus,

is the temperature dependence of the resistance of an object, where R 0 R 0 is the original resistance (usually taken to be 20.00 ° C ) 20.00 ° C ) and R is the resistance after a temperature change Δ T . Δ T . The color code gives the resistance of the resistor at a temperature of T = 20.00 ° C T = 20.00 ° C .

Numerous thermometers are based on the effect of temperature on resistance ( Figure 9.17 ). One of the most common thermometers is based on the thermistor, a semiconductor crystal with a strong temperature dependence, the resistance of which is measured to obtain its temperature. The device is small, so that it quickly comes into thermal equilibrium with the part of a person it touches.

Example 9.6

Calculating resistance, check your understanding 9.6.

Example 9.7

The resistance of coaxial cable, check your understanding 9.7.

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Section URL: https://openstax.org/books/university-physics-volume-2/pages/9-3-resistivity-and-resistance

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Resistivity - Required Practical - A-level Physics

TLDR This educational video script offers a detailed walkthrough of an A-level physics practical investigation to determine the resistivity of a wire by exploring how resistance changes with length or cross-sectional area. The tutorial begins with the theoretical basis for resistivity, explaining equations and terminology, before moving on to the experimental setup involving a circuit with an ammeter, voltmeter, and variable resistor. The presenter emphasizes the importance of keeping the current below 1 amp to prevent the wire from heating, which could affect resistivity readings. Various aspects of the experiment, such as measuring voltage, current, and calculating resistance, are covered alongside considerations for accurate data collection and analysis, including uncertainty calculation and control variables. The video concludes with advice on plotting results and interpreting gradients to find the wire's resistivity, offering a comprehensive guide for students conducting physics experiments.

📚 The experiment aims to investigate the relationship between a wire's resistance and its length and cross-sectional area, ultimately determining the wire's resistivity.
🧪 The resistivity (Rho) is calculated using the formula Rho = R * A / L, where R is resistance, A is cross-sectional area, and L is length.
🔋 A circuit is required for the experiment, consisting of a power supply, ammeter, wire, and voltmeter.
🌡️ To avoid inaccuracies, the experiment should maintain a low current (below 1 amp) to prevent the wire from heating and changing its resistivity.
🔩 The length of the wire should be varied in controlled increments to observe how resistance changes, starting at a length that avoids shorting the circuit and excessive heating.
📏 The diameter of the wire is measured in three places using a micrometer to find the mean, which is used to calculate the cross-sectional area.
📈 The experiment involves plotting resistance against length to obtain a straight line, with the gradient representing Rho / A.
🔍 Uncertainties in the experiment arise from the resolution of the measuring instruments (voltmeter, ammeter, and micrometer) and must be accounted for in the results.
🏹 To determine the percentage uncertainty in resistivity, both the percentage uncertainty in the area and the gradient must be considered.
🎯 The final results should be compared to research values to validate the accuracy of the experiment.
📝 The process involves recording PD (potential difference) across the wire and the current, then calculating resistance using Ohm's law (R = V / I).

What is the main focus of the A-Level Physics practical investigation discussed in the transcript?

- The main focus is to investigate how the resistance of a wire changes with its length and cross-sectional area, and to find the resistivity of the wire material.

What is the formula for resistivity mentioned in the transcript?

- The formula for resistivity is given as Rhor (Rho) equals R times A over L, where R is resistance, A is the cross-sectional area, and L is the length of the wire.

Why is it important to maintain a low current during the experiment?

- Maintaining a low current, below 1 amp, is important to avoid heating the wire, which could lead to inaccurate readings due to changes in resistivity with temperature.

How does the temperature affect the resistivity of the metal?

- The resistivity of the metal can change with temperature. If the wire heats up, the resistivity may increase, leading to inaccurate experimental results.

What type of wire is recommended for this experiment?

- A wire made of constantan is recommended because its resistivity does not change significantly with temperature, making it suitable for this type of experiment.

How is the length of the wire changed during the experiment?

- The length of the wire can be changed either by physically cutting and reattaching it or by using a crocodile clip that can be moved along the wire to vary the length included in the circuit.

Where should the voltmeter be placed in the circuit to measure the potential difference (PD)?

- The voltmeter should be placed across the wire to measure the PD across it. Alternatively, it could be placed across the entire circuit, as the PD would be the same.

How can the uncertainty in the experiment be minimized?

- Uncertainty can be minimized by using the same gauge wire, ensuring the wire is taut to avoid parallax error, and keeping the current below 1 amp to prevent heating and changes in resistivity.

What is the method for calculating the cross-sectional area of the wire?

- The cross-sectional area is calculated by measuring the diameter of the wire in three places using a micrometer and finding the mean, then using the formula area equals PI times (diameter squared) / 4.

How can the percentage uncertainty in resistivity be determined?

- The percentage uncertainty in resistivity is determined by adding the percentage uncertainty in the area (which is twice the percentage uncertainty in the diameter) and the percentage uncertainty in the gradient of the length vs. resistance graph.

What is the final step in analyzing the results of the experiment?

- The final step is to compare the calculated resistivity with a research value to check for accuracy, and to draw error bars and a line of worst fit on the graph to determine the percentage uncertainty in the gradient.

🔬 Introduction to A-Level Physics Practical: Investigating Wire Resistance

This paragraph introduces an A-Level physics practical investigation focused on understanding how the resistance of a wire changes with its length and cross-sectional area. The goal is to determine the resistivity (Rho) of the wire, using the equation Rho equals R times A over L, where R is resistance, A is cross-sectional area, and L is length. The discussion includes the importance of setting up a circuit with a power supply, ammeter, and wire, and the considerations for changing wire length to observe resistance variations. It also touches on safety and accuracy, emphasizing the need to avoid overheating the wire and the importance of using low currents to maintain consistent resistivity throughout the experiment.

📏 Measuring Wire Resistivity and Addressing Uncertainties

The second paragraph delves into the methodology of measuring the wire's resistivity by focusing on the cross-sectional area and the importance of accurate diameter measurements using a micrometer. It discusses the controls needed for a consistent experiment, such as using the same gauge wire and metal to minimize variability in resistivity due to temperature changes. The paragraph also addresses the concept of uncertainties in measurements, explaining how to calculate the percentage uncertainty in resistance by considering the resolution of the voltmeter, ammeter, and micrometer used. Additionally, it provides guidance on plotting the results and estimating the overall percentage uncertainty in resistivity, suggesting comparison with research values for validation.

💡 Resistivity

💡 resistance, 💡 potential difference (pd), 💡 voltmeter, 💡 ohm's law, 💡 micrometer, 💡 temperature, 💡 uncertainty.

Investigating the relationship between resistance of a wire and its length and cross-sectional area.

Using the resistivity equation, Rho equals R a over L, to find the resistivity of a wire.

Measuring resistance as the dependent variable in the experiment.

Exploring how changing the length of the wire affects its resistance.

The importance of a circuit setup with a power supply, ammeter, and wire for the experiment.

Avoiding short circuits by starting with a lengthier wire.

Considering the impact of temperature on resistivity and ensuring consistent current to avoid heating.

Using a crocodile clip to adjust the length of the wire in the circuit.

Positioning the voltmeter across the wire to measure potential difference (PD).

Calculating resistance using Ohm's law, R is V over I.

Recording PD across the wire and the current to calculate resistance.

Plotting resistance against length (L) to obtain a straight line and determine the gradient.

Understanding that the gradient of the graph equals Rho divided by a.

Measuring the wire's diameter in three places to find the mean and calculate the cross-sectional area.

Accounting for uncertainties in V, I, and the area to determine the percentage uncertainty in resistance.

Mitigating uncertainties by using the same gauge wire, low current, and ensuring the wire is taut.

Drawing a line of best fit and a line of worst fit to estimate the percentage uncertainty in the gradient.

Calculating the overall percentage uncertainty in resistivity by combining uncertainties in area and gradient.

Comparing the experimental value of resistivity with research values for accuracy.

Transcripts

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IMAGES

resistivity-experiment
Lab 101 Experiment 9 Resistivity Measurements
Relation between resistance and resistivity through a simple experiment
Experiment to determine the resistivity of a metal wire
Four-Probe Experiment
Resistivity by Four Probe Method : Experiment [in English]

COMMENTS

Required Practical: Investigating Resistivity | AQA A Level ...
The aim of the experiment is to determine the resistivity of a 2 metre constantan wire. Variables: Independent variable = Length, L , of the wire (m) Dependent variable = The current, I, through the wire (A) Control variables: Voltage through the wire. The material the wire is made from.
Core Practical 2: Investigating Resistivity - Save My Exams
A student conducts an experiment to find the resistivity of a constantan wire. They attach one end of the wire to a circuit that contains a 6.0 V battery. The other end of the wire is attached by a flying lead to the wire at different lengths.
General Physics II Lab (PHYS-2021) Experiment ELEC-4: Resistivity
In this experiment, you will measure V and I to determine R for various lengths of wire. You will then make a graph of R versus length (L). The resistance of a wire depends on the length of the wire, the cross-sectional area (A), and the resistivity (ρ) of the material: R = ρ L/A (2)
Core Practical 7: Investigating Resistivity | Edexcel ...
Aims of the Experiment. The aim of the experiment is to determine the resistivity of a length of wire. Variables: Independent variable = Length, L , of the wire (m) Dependent variable = The current, I, through the wire (A) Control variables: Voltage across the wire. The material the wire is made from.
9.4: Resistivity and Resistance - Physics LibreTexts
Conductors have the smallest resistivity, and insulators have the largest; semiconductors have intermediate resistivity. Conductors have varying but large, free charge densities, whereas most charges in insulators are bound to atoms and are not free to move.
The Electrical Properties of Materials: Resistivity
The resistance of an object, then, is not a fundamental property of the material: it is derived, or extrinsic. From studying how resistance varies with shape (geometry), you can determine that there is a property of the material that is fundamental, or intrinsic, to the material. We call this property resistivity. 1.
E12b: Determining Resistance & Resistivity with a Wheatstone ...
al properties of the conductor, such as its length and resistivity. With a Slide-Wire Wheatstone Bridge, if several resistors are placed in a circuit, the relationships between the physical properties of the resistors (such as wire length and cross-sectional area) and the resistance they produce can be utilized to find u.
9.3 Resistivity and Resistance - University ... - OpenStax
Conductors have the smallest resistivity, and insulators have the largest; semiconductors have intermediate resistivity. Conductors have varying but large, free charge densities, whereas most charges in insulators are bound to atoms and are not free to move.
Online Lab: Resistivity - East Tennessee State University
The resistivity of different metals is determined by finding the resistance of wires of a known diameter as a function of their length. It is also shown that the resistance of a wire of fixed length is inversely proportional to its cross-sectional area.
Summary of Resistivity - Required Practical - A-level Physics
The tutorial begins with the theoretical basis for resistivity, explaining equations and terminology, before moving on to the experimental setup involving a circuit with an ammeter, voltmeter, and variable resistor.