Microvolts to Nanovolts Converter

How to Convert Microvolts to Nanovolts

To convert a voltage measurement from microvolts to nanovolts, multiply the voltage by the conversion factor. Since one microvolt is equal to 1,000 nanovolts, you can use this formula:

The voltage in nanovolts is equal to the microvolts multiplied by 1,000.

How Many Nanovolts Are in a Microvolt?

There are 1,000 nanovolts in one microvolt.

What Is a Microvolt?

The microvolt (symbol: μV) is a unit of electric potential equal to one millionth (10⁻⁶) of a volt. The prefix “micro” denotes a factor of 10⁻⁶ in the International System of Units. Microvolts are important in biomedical instrumentation, audio engineering, and precision measurement. Electroencephalography (EEG) signals from the brain are typically 10–100 μV in amplitude. Electrocardiogram (ECG) signals from the heart range from about 100 μV to 3 mV. In audio engineering, the output of moving-coil phono cartridges is typically 0.2–0.5 mV (200–500 μV), requiring specialised phono preamplifiers. Microphone sensitivities are sometimes specified in microvolts per pascal. In electronics, the input offset voltage of precision operational amplifiers can be as low as 1–10 μV, and the noise floor of sensitive receivers is often measured in microvolts.

One microvolt is equal to:

• 10⁻⁶ volts (V)
• 1,000 nanovolts (nV)
• 0.001 millivolts (mV)
• 10⁻⁹ kilovolts (kV)
• 3.3356 × 10⁻⁹ statvolts (stV)
• 10,000 abvolts (abV)

What Is a Nanovolt?

The nanovolt (symbol: nV) is a unit of electric potential equal to one billionth (10⁻⁹) of a volt. The prefix “nano” denotes a factor of 10⁻⁹ in the International System of Units. Nanovolts are encountered in precision measurement, low-noise electronics, and fundamental physics research. Sensitive magnetometers, such as superconducting quantum interference devices (SQUIDs), can detect magnetic flux changes that produce signals in the nanovolt range. In materials science, thermoelectric voltages generated across junctions of different metals at very small temperature differences can be in the nanovolt range. Nanovolt-level measurements require specialised low-noise amplifiers and shielded environments to avoid interference from electromagnetic noise. In neuroscience, while typical EEG signals are in the microvolt range, some subthreshold neural signals and field potentials can approach nanovolt levels, pushing the limits of current measurement technology.

One nanovolt is equal to:

• 10⁻⁹ volts (V)
• 0.001 microvolts (μV)
• 10⁻⁶ millivolts (mV)
• 10⁻¹² kilovolts (kV)
• 3.3356 × 10⁻¹² statvolts (stV)
• 10 abvolts (abV)

Understanding Voltage Units

Voltage (also called electric potential difference or electromotive force) is a measure of the work needed to move a unit electric charge from one point to another in an electric field. It is one of the most fundamental quantities in electricity and electronics, analogous to pressure in a water system.

Ohm’s law (V = I × R) relates voltage (V) to current (I) and resistance (R), and the power equation (P = V × I) connects voltage to electrical power. These relationships are the foundation of all electrical engineering.

Major Voltage Unit Systems

• SI units (V with metric prefixes): The volt (V) is the SI derived unit of electric potential. Standard metric prefixes produce nanovolts (nV), microvolts (μV), millivolts (mV), kilovolts (kV), megavolts (MV), and gigavolts (GV). Each prefix step is a factor of 1,000.
• CGS electrostatic unit — Statvolt (stV): The voltage unit in the Gaussian/ESU system. One statvolt equals exactly 299.792458 V, a factor derived from the speed of light. Used in some theoretical physics contexts.
• CGS electromagnetic unit — Abvolt (abV): The voltage unit in the EMU system. One abvolt equals exactly 10⁻⁸ V (10 nanovolts). An extremely small unit, primarily of historical interest.

Voltage in Everyday Life

• Batteries: AA/AAA cells = 1.5 V, 9 V battery, car battery = 12 V, smartphone = 3.7–4.2 V.
• Household mains: 120 V (North America, Japan) or 230 V (Europe, Asia, Africa) at 50 or 60 Hz AC.
• USB power: USB 2.0/3.0 = 5 V, USB-C PD = 5/9/15/20 V (up to 48 V in Extended Power Range).
• Power transmission: 110–765 kV for long-distance lines, 4–35 kV for local distribution.
• Lightning: 100–300 MV potential difference, 20,000–200,000 A peak current.
• Static electricity: Walking on carpet can generate 1–25 kV.

Converting Between Voltage Units

SI voltage conversions follow simple powers of 10: each metric prefix step (nano → micro → milli → base → kilo → mega → giga) is a factor of 1,000. For CGS units, the key factors are: 1 stV = 299.792458 V (from the speed of light) and 1 abV = 10⁻⁸ V (exact).

Tips for Voltage Conversions

• For SI prefix conversions (nV, μV, mV, V, kV, MV, GV), each step is a factor of 1,000. So 1 kV = 1,000 V = 1,000,000 mV, and 1 V = 1,000 mV = 1,000,000 μV.
• The statvolt factor (299.792458 V) comes from the speed of light: c = 299,792,458 m/s, and 1 stV = c/(10⁶) V. This is an exact value.
• The abvolt is exactly 10 nanovolts (10⁻⁸ V). This is a very small voltage — it takes 100 million abvolts to make 1 volt.
• The relationship between statvolts and abvolts involves c²: 1 stV = c² × 10⁻⁸ abV ≈ 2.998 × 10¹⁰ abV.
• When dealing with very large or very small numbers, scientific notation is helpful: 1 GV = 10⁹ V, and 1 nV = 10⁻⁹ V.
• Don’t confuse voltage (electric potential, measured in volts) with current (charge flow, measured in amperes) or resistance (opposition to current, measured in ohms). Voltage “pushes” current through resistance.
• In practice, kilovolts are the most common “large” voltage unit (power lines, X-rays), while millivolts and microvolts are common “small” units (sensors, biomedical signals).

Microvolts to Nanovolts Conversion Table

The following table shows conversions from microvolts to nanovolts.

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