Completed installation of GroundLock Extreme ESD Interlocking Tile in a laboratory facility

Resistance, Resistivity, and Real World Application

[11 min read, 6 min videos]

If you don’t have an electrical engineering degree or real-world equivalent, the terms resistance and resistivity can be confusing. The terms are particularly confusing because people tend to use them interchangeably—and resistance and resistivity are not interchangeable.

Resistance

Resistance is the capacity of a material to resist, or stop, the flow of electrical currents.

Resistance readings are measured in ohms (Ω). The optimal resistance for ESD flooring materials is between 1 x 10E5 (100,000 or 1 hundred thousand) and 1 x 10E8 (100,000,000 or 1 hundred million) ohms.

As Ohm’s law tells us, resistance is equal to the ratio of voltage to current. Here’s the equation:

E=IR (for d.c. potentials)
R= V/I
R = resistance, V= voltage, I = current/amps

Graphic is titled "Voltage and Resistance" with the subtitle "How voltage affects the resistance of an ESD flooring material". The first graphic underneath shows a blue floor tile with boxing gloves (titled "ESD floor's resistance (r)") on the left side. On the right side is a smaller purple rhino (titled "Voltage (v). An arrow points from the rhino back to the tile. The arrow extends beyond the floor tile but is much thinner. The text underneath reads "When voltage is low a material has a much higher electrical resistance". In smaller text underneath it reads "* As indicated in resistance tests performed according to ESDA STM7.1 Underneath this is a second graphic, again with a carpet tile with boxing gloves but a much larger rhino. Again, an arrow is pointing back. This time the arrow that extends beyond the floor tile is much thicker. The text beneath reads "When voltage is high, the same material has trouble resisting (or stopping) the flow of current.
Graphic is titled "Voltage and Resistance" with the subtitle "How voltage affects the resistance of an ESD flooring material". The first graphic underneath shows a blue floor tile with boxing gloves (titled "ESD floor's resistance (r)") on the left side. On the right side is a smaller purple rhino (titled "Voltage (v). An arrow points from the rhino back to the tile. The arrow extends beyond the floor tile but is much thinner. The text underneath reads "When voltage is low a material has a much higher electrical resistance". In smaller text underneath it reads "* As indicated in resistance tests performed according to ESDA STM7.1 Underneath this is a second graphic, again with a carpet tile with boxing gloves but a much larger rhino. Again, an arrow is pointing back. This time the arrow that extends beyond the floor tile is much thicker. The text beneath reads "When voltage is high, the same material has trouble resisting (or stopping) the flow of current.

As you can see from the equation, current varies depending upon the applied voltage. Resistance readings are also affected by other factors, including temperature, humidity, the cleanliness of the test material, as well as size and shape of the probes used in the testing.

In laboratory testing, actual currents produced by applying AC voltage to an ESD flooring material were even higher than calculations based on Ohm’s law.

Calculated versus Actual Current
Calculated versus Actual Current

Resistivity

Resistivity, measured in ohms per square, is an inherent property of a homogeneous material.* Tests are done in a controlled manner that produces repeatable data. Absolute resistivity does not change, nor is it affected by temperature, humidity, or other external factors. However, as these external factors can affect the ability to measure resistivity, readings may vary.

In the ESD flooring industry, we don’t concern ourselves with resistivity. We’re more interested in knowing how a material will perform under real-world circumstances.

Resistance Testing

We use resistance tests to measure the resistance of ESD flooring materials. ANSI/ESD S20.20-2021 requires two resistance tests:

ANSI/ESD STM7.1-2013 Tests the resistive characterization of flooring materials.

In STM 7.1, two conductive probes are placed on a material or tile, 36” apart, then an ohmmeter applies 10 volts of d.c. current and the ohmmeter displays a reading, showing how much electrical resistance the current met as it crossed the material.

Illustration on a gray background titled "ANSI/ESD STM7.1 Resistance Tests". On the right side a "Point to Point" test set up is shown, with two probes connected to a surface analog resistance meter and placed 36" apart on the surface being tested. On the right side, the "Point to Ground" set up is shown with a surface analog resistance meter connected to ground and also to a probe on the surface being tested.
Illustration on a gray background titled "ANSI/ESD STM7.1 Resistance Tests". On the right side a "Point to Point" test set up is shown, with two probes connected to a surface analog resistance meter and placed 36" apart on the surface being tested. On the right side, the "Point to Ground" set up is shown with a surface analog resistance meter connected to ground and also to a probe on the surface being tested.

ANSI/ESD STM97.1 Measures the electrical system resistance of floor materials in combination with persons wearing static-control footwear.

In STM97.1 the test subject (person) stands on an installed floor. Completely different from 7.1, STM97.1 measures total system resistance—i.e., the resistance of the person, wearing shoes they’ll wear in the environment, the flooring material, and the adhesive.

Graphic labeled “System Resistance to Ground”. The illustration below shows a woman (labeled “Person wearing ESD shoes”) holding a wand (labeled “Metal want”). The floor beneath her has the ground symbol extending from it and is labeled “Grounded ESD floor”. The metal wand is connected to an ohmmeter (labeled “Wide ranging ohmmeter”). The ohmmeter also has a connection to ground.
Graphic labeled “System Resistance to Ground”. The illustration below shows a woman (labeled “Person wearing ESD shoes”) holding a wand (labeled “Metal want”). The floor beneath her has the ground symbol extending from it and is labeled “Grounded ESD floor”. The metal wand is connected to an ohmmeter (labeled “Wide ranging ohmmeter”). The ohmmeter also has a connection to ground.

To accurately predict system resistance—and charge generation in walking body voltage tests—the subject should wear the shoes that will actually be worn in the environment.

If ESD footwear is required, the person should wear the exact shoes or footwear (e.g., heel straps) ordered for use in the space. If people will wear regular footwear on the floor, the test should be done with the subject in various types of regular street shoes.

Is it important to perform both tests?

Absolutely! S7.1, typically done during the qualification or selection process, predicts how the floor will respond to electrical currents, and whether it will safely and effectively conduct charges to ground. As 97.1 includes actual real-world variables, results show how the material will perform in the environment. It also assures the buyer that the floor they specified is the floor they bought and installed. In other words, the promised and predicted resistance is the resistance they got.

In most cases, resistance values are a cumulative measurement of a conductive surface and a more conductive adhesive or underlayment. If the surface of the flooring material is highly conductive, or more conductive than the conductive underlayment or adhesive, the surface of the floor could form a ground circuit with a piece of nearby energized equipment, with much less resistance than intended. Standards like FAA 019f require resistance to measure above 1.0 x 10E6 for this very reason.

A split illustration demonstrating an issue with highly conductive floors. On the left side a data server is shown with the door open and a zoomed in cross section shows a split wire (labeled "Faulty wiring or short circuit". On the right side, a worker is shown reaching out to the data server. A yellow and red line running down her arm to ground shows the charge being carried. Text underneath reads "If direct body contact is made with an electrically energized part, while similar contact is made with another conductive surface (... at a different electrical potential), a current will enter the body at one contact point, traverse the body, and exit at the other contact point (usually the ground). Each year many employees suffer pain, injuries, and death from such electric shocks" attributed to OSHA. The source is given as "How Electrical Current Affects the Human Body," OSHA (Occupational Safety and Health Administration) website: (http://www.osha.gov.uk/SLTC/etools/construction/electrical_incidents/eleccurrent.html)
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Resistance Tests and Applied Voltage

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As noted above, applied voltage influences the results of resistance testing. Low resistance specifications are often based on an outdated standard, NFPA 99, designed by the National Fire Protection Association in the 1950s to protect against the explosion of flammable materials in hospital environments. For safety reasons, the NFPA set minimum resistance at no lower than 2.5 x 10E4.

NFPA 99 was done with two five-pound probes, following a method very similar to ESD 7.1. The difference—and it’s huge—is that NFPA 99 tested material resistance using 500 volts of applied current. Five hundred volts of applied current is a pretty big zap. Big enough for the resistance of a moderately conductive material to appear to be quite low. ANSI/ESD S7.1, on the other hand, tests with 10 or 100 volts (depending upon initial readings*). This far lower voltage generally yields much higher resistance readings.

As we know from Ohm’s law, the higher the applied voltage, the higher the current for a fixed resistance. Tested at 500 volts of applied potential, a material measuring 2.5 x 10E4 per STM7.1 (an already low reading) could yield a dangerously low resistance.*

Why Does Low Resistance Matter?

As the NFPA—and OSHA—acknowledge, excessively low resistance is a safety hazard.

Resulting current chart
Resulting current chart

As we’ve shown above, how resistance tests are done affects the results. When low readings are cited as an acceptable minimum resistance, we need to ask where the numbers came from. If someone claims a material is safe because it passes NFPA 99, with resistance readings of 2.5 x 10E4, either they tested the material in question with 500 volts of applied current or they’re pulling a fast one.

Furthermore, NFPA 99 no longer covers ESD flooring, so the standard doesn’t even apply.

Current standards set by the telecom industry and Federal Aviation Administration—Motorola R56 and FAA 019f—prohibit flooring materials measuring under 1 x 10E6 in areas where energized equipment is in use. Both OSHA and the data center industry use the same number.

Optimal Resistance

Resistance can be too low. It can also be too high. A flooring material with a resistance measuring 1.0 x 10E9 ohms, the upper limit permitted under ANSI/ESD S20.20-2021, may have too much electrical resistance to safely discharge static to ground. As noted above, resistance is affected by numerous factors—including temperature, humidity, and cleanliness. Even if a flooring material reading 10E9 performs well when it’s installed, low temperatures, dry air, and dirt can all raise electrical resistance to the point that the floor falls out of the acceptable range.

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Play Video

The Sweet Spot

To avoid resistances that are too low, posing a possible safety risk, or too high, potentially preventing the floor from adequately protecting equipment from the damaging effects of random ESD events, StaticWorx recommends a resistance range within what we call “the Sweet Spot.”

That is, between 1 x 10E5 and 1 x 10E8 ohms.

A diagram showing a range in Ohms from 25,000 (2.5 x 10E4) (marked “absolute limit”) to 1,000,000,000 (1.0 x 10E9) (also marked “absolute limit”). A blue shaded area runs from 25,000 to 1,000,000 (1.0 x 10E7) and is labelled “Conductive range”. A gray shaded area runs from 1,000,000 to 1,000,000,000 and is labelled “Dissipative range”. On orange shaded area in the middle runs from 100,000 (1.0 x 10E5) to 100,000,000 (1.0 x 10E8) and is labeled “Ideal zone”. A red arrow extends out to the left of it with the text “Approaching too conductive 25,000 to 100,000) and another red arrow extends to out to the right with the text “Approaching too insulate 100,000,000 to 1,000,000,000). Text underneath the graphic reads “All Staticworx static-control flooring tests within the safe range (sweet spot) shown above.
A diagram showing a range in Ohms from 25,000 (2.5 x 10E4) (marked “absolute limit”) to 1,000,000,000 (1.0 x 10E9) (also marked “absolute limit”). A blue shaded area runs from 25,000 to 1,000,000 (1.0 x 10E7) and is labelled “Conductive range”. A gray shaded area runs from 1,000,000 to 1,000,000,000 and is labelled “Dissipative range”. On orange shaded area in the middle runs from 100,000 (1.0 x 10E5) to 100,000,000 (1.0 x 10E8) and is labeled “Ideal zone”. A red arrow extends out to the left of it with the text “Approaching too conductive 25,000 to 100,000) and another red arrow extends to out to the right with the text “Approaching too insulate 100,000,000 to 1,000,000,000). Text underneath the graphic reads “All Staticworx static-control flooring tests within the safe range (sweet spot) shown above.

Materials at the low end of the range are perfectly acceptable—and safe—in electronics manufacturing and handling environments (EMA) where everyone in the space is required to use ESD footwear, and EPA mandates are enforced. In these spaces, low-resistive floors are safe because the built-in resistors in ESD footwear also protect the wearer from electrical shock.

At the high end, 1 x 10E8, the floor has ten times—an entire magnitude—less resistance than materials measuring 10E9. This gives the material plenty of wiggle room to stay within range.

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Background graphic is a still from the StaticWorx GroundSafe ESD Flooring – Your Trusted Partner explainer animation. In the foreground at the bottom are two boxes. The top is a bright blue with the StaticWorx logo and "GroundSafe ESD Flooring" underneath in white. The second is a dark blue-gray and includes the text in white: “GroundWorx ESD Flooring – Your Trusted Partner”
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StaticWorx high-performance static-control floors protect electronic components, explosives, and high-speed computers from damage caused by static electricity. ESD flooring is part of a system. Choices should always be based on objective, researched evidence. When you partner with us, we look at all possible items that may need to integrate with the floor, and, focusing on your goals and objectives, help you find the right floor for your application.