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We're working on a comprehensive educational guide for the Radioactivity Unit Converter in your language. The content below is shown in English.

What is Radioactivity Unit Converter?

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The Radioactivity Unit Converter translates between SI Becquerel (Bq, 1 disintegration per second — the modern standard), the older Curie (Ci, defined as the activity of 1 gram of radium-226 = 3.7 × 10¹⁰ Bq exactly), the obsolete Rutherford (Rd, 10⁶ Bq), and Gigabecquerel (GBq, 10⁹ Bq, commonly used in nuclear medicine). These are units of activity — the rate at which a radioactive sample decays — not dose (which uses Sievert/Sv) or absorbed energy (Gray/Gy). The Curie was the original radioactivity unit, established by Marie Curie and named in honor of her and Pierre. The value 3.7 × 10¹⁰ Bq was chosen because that's the activity of 1 gram of radium-226 — Marie Curie's signature element. The SI Becquerel (named after Henri Becquerel, discoverer of radioactivity) replaced the Curie as the official scientific unit in 1975 but Curie persists in medical and industrial use. 1 Ci = 37 GBq. Typical activity ranges: natural human body contains ~6,000 Bq from internal potassium-40 (about 10 disintegrations per second per gram of tissue from natural sources). Smoke detector americium-241 source: ~30,000 Bq. Medical iodine-131 thyroid treatment: ~5 GBq (5 × 10⁹ Bq). Cobalt-60 cancer therapy source: ~50 TBq (50 × 10¹² Bq). Chernobyl reactor at meltdown: ~10²⁰ Bq. The activity scale spans roughly 20 orders of magnitude — Becquerel works well for small biological samples while Curie/GBq are more practical for medical and industrial sources. What activity tells you: half-life × natural log of 2 × original sample atoms = total decay events that will eventually occur. Activity at any moment tells you the current decay rate. Short half-life isotopes (technetium-99m, used in medical imaging, 6 hour half-life) have very high activity briefly. Long half-life isotopes (uranium-238, 4.5 billion years) have very low activity per gram. Both can be hazardous — high-activity sources need careful shielding; long-half-life isotopes persist in environment for geological timescales.

Calkulon makes complex calculations simple — built for students and everyday problem-solvers.

Formula

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f(x)1 Ci = 3.7 × 10¹⁰ Bq; 1 Rd = 10⁶ Bq; 1 GBq = 10⁹ Bq

Variable Legend

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Symbol	Ime	Jedinica	Opis
A	Activity Amount	varies	Quantity in chosen source unit
Bq	Becquerel	Bq	1 disintegration per second (SI unit)
GBq	Gigabecquerel	GBq	10⁹ Bq — common in nuclear medicine
Ci	Curie	Ci	3.7 × 10¹⁰ Bq — legacy unit
Rd	Rutherford	Rd	10⁶ Bq — mostly obsolete

How to Radioactivity Unit Converter

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1Step 1 — Identify the activity in your source document (Becquerel SI, Curie legacy, GBq medical)
2Step 2 — Select source unit in the calculator
3Step 3 — Enter the numeric value
4Step 4 — Calculator converts to Becquerel base: 1 Ci = 3.7 × 10¹⁰ Bq, 1 GBq = 10⁹ Bq, 1 Rd = 10⁶ Bq
5Step 5 — Computes equivalents in all four units
6Step 6 — Outputs in scientific notation for very large or small values
7Step 7 — Verify against expected magnitudes (medical doses GBq, environmental TBq, natural Bq)

Worked Examples

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Example 1Standard Curie

Given:1 Ci

Rezultat:3.70 × 10¹⁰ Bq = 37 GBq = 37,000 Rd

The traditional reference unit. 1 gram of radium-226 has exactly this activity by definition.

Example 2Medical I-131 dose

Given:5 GBq

Rezultat:5 × 10⁹ Bq = 0.135 Ci = 5,000 Rd

Therapeutic iodine-131 dose for hyperthyroid treatment. Activity is high but isotope half-life is short (8 days) so radiation declines rapidly.

Example 3Background body activity

Given:5,000 Bq

Rezultat:1.35 × 10⁻⁷ Ci = 5 × 10⁻³ GBq = 5 × 10⁻³ Rd

Natural human body radioactivity from potassium-40, carbon-14, etc.

Our bodies are always slightly radioactive — natural isotopes in food and tissue. This is harmless background.

Example 4Smoke detector source

Given:30,000 Bq

Rezultat:8.11 × 10⁻⁷ Ci = 30 kBq

Americium-241 in smoke detector. Very small but enough to ionize air for detection. Safely sealed; broken detectors should be disposed properly.

Real-World Applications

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Chemistry / physics homework and lab work

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Nuclear medicine dose calculation

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Reading radioactive source labels

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Translating between SI and US units in radiology

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Environmental sampling (Bq/L drinking water, Bq/kg soil)

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Reading regulatory documents (FDA uses Ci; international uses Bq)

Frequently Asked Questions

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When is each unit used?

Becquerel (SI): scientific and regulatory standard. Most physics, biology, environmental science papers. Curie: legacy in medicine and US industrial. Many older textbooks, FDA documents. Gigabecquerel (GBq): nuclear medicine standard worldwide — easier to write '5 GBq' than '5 × 10⁹ Bq' or '0.135 Ci'. Rutherford (Rd): essentially obsolete; appears only in very old French/European literature.

Is high activity always dangerous?

Not necessarily — depends on isotope, half-life, exposure type, distance, and shielding. 5 GBq of technetium-99m (6-hour half-life, gamma emitter, used for imaging) decays harmlessly in days, mostly outside the body. 5 GBq of plutonium-239 (24,000 year half-life, alpha emitter, lung-damaging if inhaled) is dangerous for centuries. Activity is one factor; dose (Sievert) and exposure pathway determine actual biological hazard.

What does specific activity mean?

Activity per gram of isotope (Bq/g or Ci/g). Helps distinguish 'concentrated' vs 'dilute' radioactivity. Plutonium-239 specific activity: 2.3 GBq/g. Uranium-238: 12 kBq/g (much lower — long half-life). Same TOTAL activity in different specific activities means very different physical mass and handling concerns.

How is activity different from dose?

Activity (Bq, Ci) = decay rate of source. Dose (Sievert, mSv) = biological effect on tissue. Two related but different: same activity in alpha emitter vs gamma emitter produces vastly different doses (alpha is biologically more damaging per energy when ingested). For health/safety, dose matters most. Activity helps quantify source strength for shielding, transport, and disposal decisions.

Why is 1 Curie such an awkward number (3.7 × 10¹⁰)?

Historical accident. Marie Curie measured radium-226's activity per gram and assigned the unit name. The value 3.7 × 10¹⁰ disintegrations/second wasn't chosen for mathematical convenience — it's just the natural physical property of radium. SI committee chose round-number Becquerel (1 dps) when standardizing, but Curie was already entrenched. Both persist.

Common Mistakes to Avoid

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!Confusing activity (Bq, Ci) with dose (Sievert) — different quantities measuring different things
!Using Ci value where Bq expected — off by factor of 3.7 × 10¹⁰
!Not converting GBq vs Bq — easy 10⁹ error
!Treating Rutherford as current — obsolete since 1980s
!Comparing activities of different isotopes without considering half-life and emission type

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Pro Tip

When working with both activity and dose, keep units explicit at every step — confusion between Bq (decay rate) and Sv (biological effect) is the most common error in radiation work. Activity tells you 'how much source'; dose tells you 'how much biological harm.' They're related but not interchangeable.

Regional Guides

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Scientific / international▾

US medical / industrial▾

Nuclear medicine globally▾

Legacy literature▾

References

📖Difficulty:Intermediate

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Reviewed June 2026

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