CGS e.m. unit to Franklin second
CGS EMU
Fr.s
Conversion History
| Conversion | Reuse | Delete |
|---|---|---|
1 CGS EMU (CGS e.m. unit) → 29979245368.43143491760654099167 Fr.s (Franklin second) Just now |
Quick Reference Table (CGS e.m. unit to Franklin second)
| CGS e.m. unit (CGS EMU) | Franklin second (Fr.s) |
|---|---|
| 0.1 | 2,997,924,536.84314349176065409917 |
| 0.5 | 14,989,622,684.21571745880327049584 |
| 1 | 29,979,245,368.43143491760654099167 |
| 5 | 149,896,226,842.15717458803270495836 |
| 10 | 299,792,453,684.31434917606540991671 |
| 30 | 899,377,361,052.94304752819622975014 |
| 100 | 2,997,924,536,843.14349176065409916715 |
About CGS e.m. unit (CGS EMU)
The CGS electromagnetic unit (CGS e.m. unit) of current equals exactly 10 amperes, numerically identical to the biot and the EMU of current — all three are names for the same quantity within the CGS-EMU system. The term "CGS e.m. unit" is used explicitly when distinguishing the electromagnetic subsystem from the electrostatic (ESU) or Gaussian subsystems within CGS. In the CGS-EMU framework, resistance, capacitance, and inductance take unfamiliar dimensions compared to SI; the system is now of historical and theoretical interest only. Modern engineering and science universally use SI.
1 CGS e.m. unit = 10 A. A 100 A industrial busbar carries 10 CGS e.m. units. The designation appears only in pre-1960 electrical engineering literature.
About Franklin second (Fr.s)
The franklin per second (Fr/s) equals approximately 3.335641×10⁻¹⁰ amperes. The franklin (Fr), also called the statcoulomb, is the CGS-ESU unit of electric charge; one franklin per second of charge flow constitutes one statampere of current. The conversion factor arises from c/10 in CGS (where c ≈ 3×10¹⁰ cm/s), linking the ESU and SI charge systems. The franklin itself honors Benjamin Franklin, whose experiments established the convention of positive and negative electric charge. The unit appears in older electrostatics and radiation dosimetry literature and is otherwise of historical interest only.
1 Fr/s ≈ 3.336×10⁻¹⁰ A. One ampere of current corresponds to approximately 3×10⁹ franklin per second.
CGS e.m. unit – Frequently Asked Questions
Why were "absolute" and "practical" electrical units different in the 19th century?
The CGS e.m. unit of current (10 A) was inconveniently large for everyday lab work, while the CGS e.m. unit of resistance (the abohm, 10⁻⁹ Ω) was absurdly small. Physicists created "practical" units — the ampere, volt, and ohm — as decimal multiples that gave human-scale numbers. The ampere was set at 0.1 abampere. These practical units eventually became SI, while the "absolute" CGS units became historical footnotes.
Why does the CGS system have three different subsystems for the same physics?
In the 19th century, electricity and magnetism were treated as partially separate phenomena, leading to separate "natural" unit choices. The EMU system normalized magnetic permeability to 1; the ESU system normalized electric permittivity to 1; the Gaussian system mixed both. Once Maxwell unified electromagnetism, this fragmentation became unnecessary — but the systems persisted in literature for a century.
How did physicists handle the factor-of-10 difference between CGS e.m. units and practical amperes?
They introduced "practical" units — the ampere, volt, and ohm — as decimal multiples of CGS-EMU quantities. The ampere was defined as 0.1 abampere (CGS e.m. unit). This practical system eventually became SI, while the "absolute" CGS units faded. The factor of 10 was chosen for human-scale convenience.
What other CGS electromagnetic units still show up in modern contexts?
The gauss (magnetic flux density, = 10⁻⁴ tesla) remains surprisingly common — refrigerator magnets are rated in gauss, and MRI field strengths are often quoted in both tesla and gauss. The oersted (magnetic field strength) appears in materials science. These CGS-EMU holdouts persist because their numerical values are more convenient for everyday magnets.
When did the transition from CGS to SI happen in practice?
The SI was officially adopted in 1960, but the transition took decades. Most physics journals required SI by the 1970s, though astrophysics and plasma physics held onto Gaussian CGS into the 2000s. Some subfields never fully switched — you can still find new papers using gauss and oersted alongside tesla and A/m.
Franklin second – Frequently Asked Questions
Who was Benjamin Franklin and why is a charge unit named after him?
Franklin (1706–1790) was the American polymath who proved lightning is electrical with his famous kite experiment in 1752. He introduced the convention of "positive" and "negative" charge that we still use today. He arbitrarily assigned positive to the charge on glass rubbed with silk — which turned out to be a deficit of electrons, giving us the unfortunate convention that current flows opposite to electron motion.
Why is the franklin still referenced in the definition of the roentgen radiation unit?
The roentgen (R) was defined in 1928 as the radiation exposure producing 1 ESU of charge (1 franklin ≈ 3.336 × 10⁻¹⁰ C) per cm³ of dry air at STP. This CGS-era definition stuck because radiation safety regulations were already built around it. Even though the SI gray replaced the roentgen for dosimetry, the roentgen — and its franklin-based definition — persists in US regulatory and medical imaging contexts.
Why does the franklin appear in radiation dosimetry?
The legacy unit of radiation exposure, the roentgen (R), is defined as the amount of X-ray or gamma radiation that produces 1 esu of charge (1 franklin) per cubic centimeter of dry air at STP. This definition dates from the 1920s when CGS-ESU was standard. Modern dosimetry uses grays and sieverts, but the roentgen and its franklin-based definition persist in some medical and regulatory contexts.
How does franklin per second compare to everyday currents?
One Fr/s is about 0.33 nanoamperes — less current than a sleeping microcontroller draws. To equal the 1 A flowing through a phone charger cable, you would need about 3 billion franklins per second. The unit is spectacularly impractical for anything beyond electrostatics calculations.
Did Benjamin Franklin actually get the sign of electric charge wrong?
Sort of. He labelled the charge on glass rubbed with silk as "positive," not knowing it was caused by removing electrons. When Thomson discovered the electron in 1897, it turned out electrons carry what Franklin called negative charge. So conventional current flows from + to −, opposite to actual electron flow. Engineers and physicists have lived with this "mistake" for over 250 years.