Millicurie to Terabecquerel

Yes, and it creates real problems. If a patient who received therapeutic I-131 (30–200 mCi) dies within days, the body can trigger radiation alarms at funeral homes and crematoria. Cremation is the bigger concern — burning the body aerosolises the isotope, contaminating the crematorium and potentially exposing workers. Most radiation safety programs require a waiting period before cremation, or direct burial with notification to the funeral director. In 2019, an Arizona crematorium unknowingly cremated a patient with residual lutetium-177, contaminating the facility. Hospitals are supposed to flag these cases, but the system is imperfect.

The radiopharmacist draws the Tc-99m solution into a syringe, places it in a dose calibrator (a pressurized argon ionisation chamber), and reads the activity in mCi or MBq. Because the isotope is decaying constantly — Tc-99m loses half its activity every 6 hours — the calibrator reading must be decay-corrected to the planned injection time. If the scan is at 2pm and the dose is drawn at 10am, the pharmacist dispenses more than the prescribed 20 mCi, knowing it will decay to exactly 20 mCi by injection. Timing is everything.

The Tc-99m bone scan, with about 20–25 mCi (740–925 MBq) injected intravenously. Technetium-99m accumulates in areas of high bone turnover — fractures, infections, metastases — and emits 140 keV gamma rays that a gamma camera images. The scan itself takes 2–3 hours (allowing time for the tracer to distribute), and the patient's radioactivity drops to negligible levels within 24–48 hours. Over 30 million Tc-99m procedures are performed worldwide each year, making it by far the most-used medical radioisotope.

Technically yes, but radiation detectors at airports, borders, and government buildings may alarm for days after certain scans. A patient who received 10 mCi of I-131 can trigger a portal monitor for up to 3 months. Most nuclear medicine departments provide a wallet card explaining the procedure, isotope, and date — TSA and customs agents are trained to recognize these. The actual radiation risk to fellow passengers is negligible; the issue is entirely about security system sensitivity, not safety.

Hyperthyroidism treatment aims to kill just enough thyroid tissue to normalize hormone production — typically 5–15 mCi (185–555 MBq) of I-131. Thyroid cancer ablation aims to destroy every remaining thyroid cell after surgery and kill any metastases — that takes 30–200 mCi (1.1–7.4 GBq). The higher doses require inpatient isolation and more aggressive radiation safety precautions. Some oncologists are exploring whether lower ablation doses (30 mCi) work as well as high ones (100+ mCi) for low-risk cancers — the evidence is surprisingly close.

The total release from Chernobyl Unit 4 is estimated at 5,200 petabecquerels (5.2 × 10⁶ TBq), though figures vary by source and isotope accounting. Of that, about 1,760 TBq was iodine-131 and 85 TBq was caesium-137. For perspective, the entire global nuclear weapons testing era released roughly 2.6 × 10⁸ TBq — so Chernobyl was devastating but still a fraction of Cold War fallout. Fukushima released about 520 TBq of Cs-137, roughly one-sixth of Chernobyl.

To sterilise food, you need to deliver 1–10 kilograys of absorbed dose in minutes across conveyor belts of product. That requires an enormous photon flux, which only a multi-hundred-TBq cobalt-60 source can provide. A typical facility starts with 500–1,000 TBq and replenishes as the Co-60 decays (5.27-year half-life). The food never becomes radioactive — gamma photons do not induce radioactivity in stable atoms at these energies. Over 60 countries have approved food irradiation for spices, meat, and produce.

Nuclear medicine staff literally call it a "moly cow." A generator arrives with ~150 TBq of Mo-99 adsorbed onto an alumina column. Mo-99 decays (66-hour half-life) into Tc-99m, which is washed off the column with saline — "milking" the generator. Fresh Tc-99m accumulates between milkings, reaching peak yield about every 23 hours. A single generator supplies a hospital for about a week before the parent Mo-99 activity drops too low. It is one of the cleverest supply chains in medicine.

Fresh spent fuel is extraordinarily active — a single assembly registers in the petabecquerel range, dominated by short-lived fission products like I-131, Xe-133, and Ba-140. Within a year, activity drops by about 99% as these burn out. After 10 years it drops another 90%, leaving mainly Cs-137 and Sr-90 (both ~30-year half-lives). After 300 years those are gone too, and the remaining activity comes from transuranics like plutonium — far less active per gram but with half-lives of thousands to millions of years.

Permanently, no — radioactivity decays by definition. Practically, it depends on the isotopes deposited and the cleanup threshold. Chernobyl's exclusion zone still restricts habitation 40 years later because Cs-137 (30-year half-life) contaminated the soil at levels above 1,480 TBq/km² in the worst spots. Parts of Fukushima were decontaminated and reopened within years because the deposition was lower. The real question is not whether an area recovers, but whether society is willing to wait — or pay for aggressive decontamination.