# Electric Resistivity Converter > Convert between electric resistivity units: ohm meter (Ω·m), ohm centimeter (Ω·cm), microohm meter (µΩ·m), and more. **Category:** Conversion **Keywords:** electric resistivity, ohm meter, resistivity, specific resistance, conductor, semiconductor, material property **URL:** https://complete.tools/electric-resistivity-converter ## How it calculates The Electric Resistivity Converter uses a conversion factor to change values between different units of resistivity. The basic formula for converting resistivity is: 1 Ω·cm = 0.01 Ω·m. Thus, to convert from ohm centimeters to ohm meters, the formula is: Value in Ω·m = Value in Ω·cm × 0.01. Conversely, to convert from ohm meters to ohm centimeters, the formula is: Value in Ω·cm = Value in Ω·m ÷ 0.01. In these formulas, 'Value in Ω·m' represents the resistivity in ohm meters, and 'Value in Ω·cm' represents the resistivity in ohm centimeters. By understanding these relationships, users can accurately convert between various resistivity units based on their specific needs. ## Who should use this Electrical engineers conducting conductivity tests on materials, geophysicists studying subsurface resistivity in geological formations, and materials scientists researching the electrical properties of new compounds can all benefit from this tool. Additionally, educators in physics can use it to demonstrate principles of electrical conduction and resistance in laboratory settings. ## Worked examples Example 1: A materials engineer measures a resistivity of 5 Ω·cm for a new semiconductor material. To convert this to ohm meters, the calculation is: 5 Ω·cm × 0.01 = 0.05 Ω·m. Thus, the resistivity of the semiconductor in ohm meters is 0.05 Ω·m. Example 2: A geophysicist needs to report soil resistivity measured as 0.02 Ω·m for a site. To convert this to ohm centimeters, the calculation is: 0.02 Ω·m ÷ 0.01 = 2 Ω·cm. Therefore, the resistivity of the soil in ohm centimeters is 2 Ω·cm. These examples illustrate how resistivity measurements can vary in different units and the importance of accurate conversions in professional contexts. ## Limitations The Electric Resistivity Converter is limited to standard resistivity units such as ohm meters and ohm centimeters. It assumes that the user provides valid numerical inputs without error, as non-numeric entries will yield no conversion. The tool does not account for temperature variations that can affect resistivity values in real-world applications, potentially leading to inaccuracies. Furthermore, the converter may not provide precise results for extremely low or high resistivity values outside typical ranges, as these can introduce rounding errors in calculations. ## FAQs **Q:** How does temperature affect resistivity values in this conversion? **A:** Temperature significantly influences the resistivity of materials; however, this tool does not account for temperature variations, which can lead to discrepancies in calculated values. **Q:** Can this converter handle complex resistivity measurements? **A:** No, this converter is designed for standard units of resistivity and does not accommodate complex resistivity calculations involving frequency or phase shifts in electrical measurements. **Q:** Are there any specific materials where resistivity conversion is particularly critical? **A:** Yes, in semiconductor materials, accurate resistivity measurements are crucial for device performance, making precise unit conversion essential for engineers in electronics. **Q:** What is the maximum and minimum resistivity value that can be converted? **A:** The tool can convert typical resistivity values within a realistic range, but it may not yield accurate results for extremely low (near-zero) or extremely high resistivity values due to rounding errors. --- *Generated from [complete.tools/electric-resistivity-converter](https://complete.tools/electric-resistivity-converter)*