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Electric Resistivity



Complete list of electric resistivity units for conversion

  • ohm meter
  • 1 ohm centimeter = 0.01 ohm meter
  • 1 ohm inch = 0.0254 ohm meter
  • 1 microhm centimeter = 1.0E-8 ohm meter
  • 1 microhm inch = 2.5400000000102E-8 ohm meter
  • 1 abohm centimeter = 1.0E-11 ohm meter
  • 1 statohm centimeter = 8987524324.0156 ohm meter
  • 1 circular mil ohm/foot = 1.6624261130101E-9 ohm meter

What is electric resistivity and the units?

Resistivity, measured in ohm meters (Ω·m), quantifies a material’s ability to resist electric current over a given length. Converting between units is crucial for accurate calculations in material science and electrical engineering. For instance, 1 ohm centimeter (Ω·cm) is equivalent to 0.01 ohm meters, while 1 ohm inch (Ω·in) equals 0.0254 ohm meters, showcasing the relationship between different length scales.

For smaller resistances, 1 microhm centimeter (μΩ·cm) equals 1.0E-8 ohm meters, and 1 microhm inch (μΩ·in) is approximately 2.54E-8 ohm meters. These conversions are particularly useful in measuring very low resistivities.

On the other end of the scale, 1 abohm centimeter equals 1.0E-11 ohm meters, while the statohm centimeter corresponds to a much larger value of approximately 8,987,524,324.0156 ohm meters. Additionally, 1 circular mil ohm per foot equals about 1.6624E-9 ohm meters. These conversions are essential for engineers and researchers to accurately assess and compare the resistive properties of various materials and components.

Conclusion

Understanding electricity resistivity and its units is essential for a variety of scientific and engineering applications. With this guide, you now have a comprehensive overview of common resistivity units, popular conversions, and a convenient conversion widget tool to assist in your calculations.

By mastering these concepts and tools, you can make more informed decisions in your electrical engineering projects and research. Remember, accurate resistivity measurements can significantly impact the performance of electrical components and systems.