Rutherford to Millicurie

The rutherford was proposed in the 1940s when the curie was the only game in town and was inconveniently large for many lab measurements. At 10⁶ dps (1 MBq), the rutherford sat in a useful range. But the 1975 SI reform chose the becquerel (1 dps) as the base unit with standard SI prefixes — kBq, MBq, GBq — which covered every scale. Having both the rutherford and the megabecquerel for the same quantity was redundant. The scientific community picked one, and the rutherford quietly disappeared from everything except unit conversion tables and physics trivia.

Rutherford discovered the atomic nucleus by firing alpha particles at gold foil (1911), identified alpha and beta radiation as distinct particle types, and performed the first artificial nuclear transmutation — turning nitrogen into oxygen — in 1917. He won the Nobel Prize in Chemistry in 1908, which famously annoyed him because he considered himself a physicist. His students went on to split the atom (Cockcroft and Walton) and discover the neutron (Chadwick). Nearly every branch of nuclear science traces back to his Manchester and Cambridge laboratories.

Several. The stat (1 disintegration per second, identical to the becquerel but proposed earlier), the eman (used for radon concentration in water, equal to 10⁻¹⁰ Ci/L), and the mache unit (another radon measure used in Austrian and German spa water literature) are all effectively extinct. The curie itself is technically obsolete under SI but persists through sheer institutional momentum in the US. The pattern is typical of measurement science: every era invents its own units, and standardisation eventually consolidates them.

Unlikely in practice because the rutherford disappeared from active use by the 1970s, before the megabecquerel entered common parlance in the 1980s. You would only encounter the rutherford in papers from roughly 1946–1970, primarily in European nuclear physics journals. If you see "Rd" in a modern unit conversion tool, it is there for completeness and historical interest, not because anyone is publishing in rutherfords. The real risk of confusion in old literature is between the curie and the becquerel, where a missing prefix can mean a billionfold error.

The "sunshine unit" — officially the strontium unit — was coined by the US Atomic Energy Commission in the 1950s to describe strontium-90 concentration in bones and milk during nuclear weapons testing. One sunshine unit equalled 1 picocurie of Sr-90 per gram of calcium. The name was a deliberate PR choice to make fallout contamination sound cheerful and harmless. It backfired spectacularly when journalists mocked it as Orwellian doublespeak, and the term was quietly dropped in favor of pCi/g Ca. It remains a cautionary tale about naming units for political rather than scientific reasons.

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.