XConvertOther Unit ConvertersDownloadsCompress MP4

Millicoulombs to Coulombs conversion

Millicoulombs to Coulombs conversion table

Millicoulombs (mC)Coulombs (c)
00
10.001
20.002
30.003
40.004
50.005
60.006
70.007
80.008
90.009
100.01
200.02
300.03
400.04
500.05
600.06
700.07
800.08
900.09
1000.1
10001

How to convert millicoulombs to coulombs?

To convert millicoulombs (mC) to coulombs (C), you need to remember that "milli-" is a metric prefix meaning one-thousandth (1/1000 or 0.001). Therefore, 1 mC is equivalent to 0.001 C.

Here's the formula for conversion: 1 mC=1×0.001 C=0.001 C\text{1 mC} = 1 \times 0.001 \text{ C} = 0.001 \text{ C}

Example Conversions:

  • 5 mC: 5 mC=5×0.001 C=0.005 C5 \text{ mC} = 5 \times 0.001 \text{ C} = 0.005 \text{ C}

  • 20 mC: 20 mC=20×0.001 C=0.02 C20 \text{ mC} = 20 \times 0.001 \text{ C} = 0.02 \text{ C}

  • 100 mC: 100 mC=100×0.001 C=0.1 C100 \text{ mC} = 100 \times 0.001 \text{ C} = 0.1 \text{ C}

  • 750 mC: 750 mC=750×0.001 C=0.75 C750 \text{ mC} = 750 \times 0.001 \text{ C} = 0.75 \text{ C}

Real-world Examples of Various Quantities of Charge:

  1. Mobile Phone Battery: The charge capacity of a smartphone battery is typically measured in milliampere-hours (mAh), which is related to coulombs (C) as charge. For instance, a 3000 mAh battery would theoretically deplete a charge of 3000 mC when operated at 1V for 1 hour.

  2. Capacitor in Electronics: Small capacitors used in electronics might store charges in the range of 1 mC to 10 mC. For instance, a 1 mC charge on a capacitor is common in small circuit designs.

  3. Static Electricity: Walking across a carpeted room can generate a static charge on your body in the range of tens to hundreds of millicoulombs (mC). For example, 50 mC might build up and then discharge when you touch a metal object, causing a small shock.

  4. Electric Vehicles (EV): The amount of charge that can be stored in the batteries of electric vehicles can be substantial. While typically measured in terms of kilowatt-hours (kWh) for energy, the corresponding charge is extremely large, though still quantifiable in millicoulombs for smaller systems or subsystems within the vehicle.

Understanding these conversions and their real-world applications can be invaluable in fields ranging from electronics and engineering to everyday situations where electrical charge plays a role.

See below section for step by step unit conversion with formulas and explanations. Please refer to the table below for a list of all the Coulombs to other unit conversions.

What is millicoulombs?

The unit you are referring to is actually "milli-Coulombs" (mC), not "millicoulombs".

A mill coulomb (mC) is a unit of electric charge in the International System of Units (SI). It represents one-thousandth of a coulomb, which is the basic unit of electric charge.

One milli-Coulomb (mC) is equal to:

  • 0.001 Coulombs
  • 10^-3 C

To put it into perspective, here are some examples of electric charges measured in mill coulombs:

  • A typical smartphone battery can store around 5-7 mC of charge.
  • A small capacitor used in electronic devices might have a capacitance value of 1-10 micro-Coulombs (μC), which is 0.001 to 0.01 mC.

The unit of mill coulomb is useful when describing the charge storage capacity of batteries, capacitors, or other devices that handle small amounts of electric charge.

What is coulombs?

Coulomb's Law, also known as Coulomb's constant, is a fundamental concept in physics that describes the force between two charged particles. It was formulated by French physicist Charles-Augustin de Coulomb in 1785.

What does it do?

In essence, Coulomb's Law relates the electric force between two charges to their magnitudes and the distance between them. The law states:

"Every point charge experiences a force due to every other point charge."

More formally, if you have two charged particles with opposite signs (positive and negative), the force between them is attractive, while with same signs, it's repulsive.

The Math

Here's the math behind Coulomb's Law:

F = k * (q1 × q2) / r^2

Where:

  • F is the electric force in Newtons (N)
  • k is Coulomb's constant (approximately 8.9875 × 10^9 N m^2 C^-2)
  • q1 and q2 are the magnitudes of the charges in Coulombs (C)
  • r is the distance between the charges in meters (m)

Real-world Applications

Coulomb's Law has numerous practical applications:

  • Electrostatics: understanding how electric forces act on charged particles.
  • Electric fields: predicting how an electric field affects a charged particle.
  • Capacitance: calculating the energy stored in capacitors.
  • Electromagnetic induction: explaining the generation of currents and voltages.

Key Takeaway

Coulomb's Law describes the fundamental force between charged particles, which is crucial for understanding various electrical phenomena. It has far-reaching implications in physics and engineering!

Complete Millicoulombs conversion table

Enter # of Millicoulombs
Convert 1 mC to other unitsResult
Millicoulombs to Coulombs (mC to c)0.001
Millicoulombs to Microcoulombs (mC to μC)1000
Millicoulombs to Nanocoulombs (mC to nC)1000000
Millicoulombs to Picocoulombs (mC to pC)1000000000

Charge conversions