Picocurie to Gigabecquerel

The EPA chose 4 pCi/L in 1986 as a practical action level — not a safety threshold. At the time, mitigation technology could reliably reduce levels to below 4 pCi/L but not much further. The risk at 4 pCi/L is roughly equivalent to smoking half a pack of cigarettes per day or having 200 chest X-rays per year. The EPA actually recommends considering mitigation at 2 pCi/L, but the 4 pCi/L number stuck because it was achievable and measurable with 1980s-era charcoal canisters.

Radon-222 is a gas produced by the natural decay of uranium-238 in soil and rock. Being a noble gas, it does not bind to soil particles — it seeps upward through cracks, gaps around pipes, sump pits, and any opening where the house contacts the ground. Indoor air pressure is slightly lower than soil gas pressure (the "stack effect"), so the house literally sucks radon in. A well-sealed, energy-efficient home can actually trap more radon than a drafty old one because there is less ventilation to dilute it.

Short-answer: yes, DIY kits work fine for screening. Charcoal canister tests (2–7 days, about $15) and alpha-track detectors (90 days–1 year, about $25) are available at hardware stores and by mail. You place the device in the lowest liveable area with windows closed, mail it to a lab, and get results in pCi/L. For real estate transactions, most states require a certified professional using continuous radon monitors. If your DIY test reads above 4 pCi/L, a professional follow-up is wise before spending $800–2,500 on a mitigation system.

Picocuries sound small, but they add up over decades of continuous exposure. At 4 pCi/L, you inhale about 8 radon atoms per second with each breath, 24 hours a day, for years. It is not the radon itself that does the damage — radon decays into polonium-218 and polonium-214, which are solids that lodge in lung tissue and blast it with alpha particles at point-blank range. The EPA estimates radon causes about 21,000 lung cancer deaths per year in the US, mostly among smokers where radon and tobacco synergise.

Granite contains trace uranium and therefore produces radon, but measured emission rates from countertops are typically 0.01–0.1 pCi/L contribution to room air — 10 to 100 times below the EPA action level. You would need to seal yourself in a phone booth with a granite slab to approach concerning concentrations. The radon-from-countertops scare peaked around 2008 when a few outlier samples made news, but systematic studies by the EPA and multiple universities consistently found negligible risk. Your basement floor is a vastly larger radon source.

The patient swallows a capsule containing 1–7 GBq of I-131. The thyroid gland concentrates iodine from the bloodstream — it cannot tell radioactive iodine from stable iodine — so the isotope accumulates right where you want it. I-131 emits beta particles with a range of about 2 mm in tissue, which destroy thyroid cells from the inside while sparing nearby structures. The gamma rays it also emits are used for imaging to verify uptake. Within weeks the targeted tissue is dead, no scalpel required.

At 3–7 GBq, a freshly treated thyroid cancer patient is a walking radiation source. They emit gamma rays and excrete I-131 in sweat, saliva, and urine for days. Regulations typically require isolation until the retained activity drops below 1.1 GBq or the dose rate at 1 meter falls below 25 µSv/hr. That usually means 2–5 days of sleeping alone, using a dedicated bathroom, and avoiding prolonged close contact — especially with children and pregnant women, who are more radiation-sensitive.

Brachytherapy places a sealed radioactive source directly inside or next to a tumor — "brachy" is Greek for "short distance." High-dose-rate (HDR) sources of iridium-192 at 100–370 GBq deliver an intense, highly localized dose in minutes. The inverse-square law means tissue just centimeters away receives dramatically less radiation. This precision is why brachytherapy can treat cervical, prostate, and breast cancers with fewer side effects than external beam radiation alone.

Industrial radiography sources (1–20 GBq of Ir-192 or Se-75) live inside heavy shielded containers called "cameras" or "projectors" made of depleted uranium or tungsten. The source is only pushed out through a guide tube during an exposure, and the area is roped off with radiation monitors. Strict transport regulations, tamper-proof locks, and regular inventory audits apply. When sources decay below useful activity, they are returned to the manufacturer. The IAEA maintains a database of lost or orphaned sources — the ones that slip through the system occasionally cause severe accidents.

Diagnostic procedures use just enough activity to produce a readable image — typically 50–800 MBq (0.05–0.8 GBq). The goal is information, not tissue destruction. Therapeutic procedures aim to kill cells, so they use 10 to 100 times more: 1–7 GBq for thyroid ablation, 100–370 GBq for HDR brachytherapy sources. The line between them is roughly 1 GBq. Below that, you are taking a picture; above it, you are prescribing a lethal dose to a very specific target.