Statfarads to Abfarads Converter

Convert statfarads to abfarads instantly with our free capacitance conversion calculator. Enter any value for accurate results.

How to Convert Statfarads to Abfarads

To convert a capacitance measurement from statfarads to abfarads, divide the capacitance value by the conversion factor. Since one statfarad is equal to 1.1126 × 10^-21 abfarads, you can use this formula:

abfarads = statfarads ÷ 8.9876 × 10²⁰

The capacitance in abfarads is equal to the statfarads divided by 8.9876 × 10²⁰.

Example: Convert 5 statfarads to abfarads.

Using the formula: abfarads = statfarads ÷ 8.9876 × 10²⁰

abfarads = 5 stF ÷ 8.9876 × 10²⁰ = 5.5632E-21 abF

Therefore, 5 statfarads is equal to 5.5632E-21 abfarads.

How Many Abfarads Are in a Statfarad?

There are 1.1126 × 10^-21 abfarads in one statfarad, which is why we use this value in the formula above.

1 stF = 1.1126 × 10^-21 abF

What Is a Statfarad?

The statfarad (symbol: stF) is the unit of electrical capacitance in the centimetre–gram–second (CGS) electrostatic system of units. It is defined as the capacitance of a capacitor that has a potential difference of one statvolt when charged by one statcoulomb of electricity. One statfarad is approximately equal to 1.1126 picofarads (1.1126 × 10−¹² farads). This makes the statfarad a very small unit of capacitance, though it is much more practically sized than the farad for describing the capacitances of small components. The conversion factor between farads and statfarads is derived from the speed of light in vacuum (c ≈ 2.998 × 10¹&sup0; cm/s), as the relationship between SI and CGS electrostatic units depends on this fundamental constant. Specifically, 1 farad = c² × 10−&sup5; statfarads ≈ 898,755,224,014.74 statfarads. Like the abfarad, the statfarad is primarily of historical and theoretical interest. It appears in older physics literature using the CGS electrostatic system. Modern practice favors SI units for all capacitance measurements, though understanding CGS units remains important for reading historical scientific papers.

One statfarad is equal to:

≈ 1.1126 × 10^-12 farads (F)
≈ 1.1126 × 10^-9 millifarads (mF)
≈ 1.1126 × 10^-6 microfarads (μF)
≈ 0.001113 nanofarads (nF)
≈ 1.1126 picofarads (pF)
≈ 1.1126 × 10^-21 abfarads (abF)

What Is a Abfarad?

The abfarad (symbol: abF) is the unit of electrical capacitance in the centimetre–gram–second (CGS) electromagnetic system of units. One abfarad equals exactly one billion (10&sup9;) farads, making it an extraordinarily large unit of capacitance. The abfarad is defined as the capacitance of a capacitor that has a potential difference of one abvolt when charged by one abcoulomb of electricity. Since one abvolt equals 10−&sup8; volts and one abcoulomb equals 10 coulombs, the resulting capacitance unit is 10&sup9; times larger than the farad. The abfarad is considered an obsolete unit with very rare practical applications. No physical capacitor has ever been constructed with a capacitance approaching one abfarad. Even the largest supercapacitors available today have capacitances of only a few thousand farads, which is still millions of times smaller than one abfarad. The unit is primarily of historical and theoretical interest, appearing in older physics textbooks that use the CGS electromagnetic system. Modern electrical engineering and physics exclusively use SI units (farads and its sub-multiples) for capacitance measurements.

One abfarad is equal to:

1,000,000,000 farads (F)
1,000,000,000,000 millifarads (mF)
10¹⁵ microfarads (μF)
10¹⁸ nanofarads (nF)
10²¹ picofarads (pF)
8.988 × 10²⁰ statfarads (stF)

Understanding Capacitance

Capacitance is a fundamental electrical property that describes a component's ability to store electrical energy in an electric field. A capacitor, the component that exhibits capacitance, consists of two conductive plates separated by an insulating material called a dielectric.

When a voltage is applied across a capacitor, positive charge accumulates on one plate and negative charge on the other, creating an electric field in the dielectric. The capacitance (C) is defined as the ratio of the electric charge (Q) stored on each plate to the voltage (V) across the capacitor: C = Q / V.

The SI unit of capacitance is the farad (F), named after Michael Faraday. One farad equals the capacitance when one coulomb of charge produces one volt of potential difference. In practice, a farad is an extremely large unit, so capacitance values in electronic circuits are typically expressed in sub-multiples: millifarads (mF), microfarads (μF), nanofarads (nF), and picofarads (pF).

SI vs. CGS Units

The International System of Units (SI) uses the farad and its metric prefixed sub-multiples. The older centimetre–gram–second (CGS) system includes two capacitance units: the abfarad (from the electromagnetic sub-system, equal to 10&sup9; farads) and the statfarad (from the electrostatic sub-system, approximately 1.1126 × 10−¹² farads).

While CGS units are largely obsolete in modern engineering, they still appear in some physics textbooks and older scientific literature. Understanding the conversion between these systems is important for interpreting historical data and theoretical calculations.

Factors Affecting Capacitance

Plate area — Larger plate area increases capacitance
Distance between plates — Smaller separation increases capacitance
Dielectric material — Higher dielectric constant (κ) increases capacitance
Temperature — Can affect the dielectric constant and thus capacitance

Common Capacitance Values in Electronics

Supercapacitors: 0.1 F to 3,000+ F
Electrolytic capacitors: 0.1 μF to 100,000 μF
Film capacitors: 1 nF to 100 μF
Ceramic capacitors: 1 pF to 100 μF
Trimmer/variable capacitors: 1 pF to 500 pF

Practical Tips for Capacitance Conversion

When working with SI capacitance units (F, mF, μF, nF, pF), remember that each step is a factor of 1,000: 1 F = 1,000 mF = 1,000,000 μF = 1,000,000,000 nF = 1,000,000,000,000 pF.
To convert between adjacent SI prefix levels, simply move the decimal point three places. For example, 4,700 pF = 4.7 nF = 0.0047 μF.
Capacitor markings on small components (like ceramic capacitors) are often in picofarads using a three-digit code. The first two digits are significant figures and the third is the multiplier (number of zeros). For example, "473" means 47,000 pF = 47 nF.
When reading schematics, pay close attention to the unit prefix. Confusing μF and nF (a factor of 1,000 difference) is a common source of circuit errors.
For CGS units (abfarads and statfarads), remember that 1 abfarad = 10&sup9; F is enormous, while 1 statfarad ≈ 1.1126 pF is tiny. These units are rarely used in modern practice.
Online calculators and conversion tools are helpful, but always double-check critical calculations by hand, especially for precision applications in filter design or timing circuits.

Statfarads to Abfarads Conversion Table

The following table shows conversions from statfarads to abfarads.

Statfarads	Abfarads (abF)
1.0000E+20 stF	0.111265
2.0000E+20 stF	0.22253
3.0000E+20 stF	0.333795
4.0000E+20 stF	0.44506
5.0000E+20 stF	0.556325
6.0000E+20 stF	0.66759
7.0000E+20 stF	0.778855
8.0000E+20 stF	0.89012
9.0000E+20 stF	1.00138
1.0000E+21 stF	1.11265
1.0000E+21 stF	1.11265
2.0000E+21 stF	2.2253
3.0000E+21 stF	3.33795
4.0000E+21 stF	4.4506
5.0000E+21 stF	5.56325
6.0000E+21 stF	6.6759
7.0000E+21 stF	7.78855
8.0000E+21 stF	8.9012
9.0000E+21 stF	10.0138
1.0000E+22 stF	11.1265
1.0000E+22 stF	11.1265
2.0000E+22 stF	22.253
3.0000E+22 stF	33.3795
4.0000E+22 stF	44.506
5.0000E+22 stF	55.6325
6.0000E+22 stF	66.759
7.0000E+22 stF	77.8855
8.0000E+22 stF	89.012
9.0000E+22 stF	100.138
1.0000E+23 stF	111.265