Disintegrations per second to Kilobecquerel

Because dps is literally what the instrument measures — a detector counts individual nuclear decay events over time. Calling it "dps" keeps the language grounded in what physically happened. Calling it "Bq" applies an SI label to the same number. Old lab protocols, standard operating procedures written before 1975, and some US-centric equipment manuals still use dps because nobody rewrote the paperwork. Numerically, 1 dps = 1 Bq, so the conversion is trivially multiplying by one.

Counts per second (cps) is what the detector actually registers; disintegrations per second (dps) is how many decays actually occurred. No detector catches every decay — some radiation misses the detector, some is absorbed before reaching it, and some types of radiation are invisible to certain detectors. The ratio of cps to dps is the detection efficiency, which can range from under 1% (for low-energy beta emitters in a Geiger tube) to over 90% (for gamma emitters in a well counter). Getting from cps to dps requires careful calibration.

The sample is dissolved in a scintillation cocktail — a solvent containing fluorescent molecules. Each beta particle or electron excites the cocktail, producing a flash of light detected by photomultiplier tubes. But chemical impurities in the sample absorb some of that light (a phenomenon called quenching), so the counter sees fewer flashes than decays. The instrument runs an internal or external standard to measure the quench level, then applies a correction curve to convert raw cpm to true dpm, which you divide by 60 to get dps.

Not numerically — they are identical. But contextually, "dps" emphasizes the physical measurement process and appears in lab protocols where you are calculating detector efficiency: "the source emits 10,000 dps and the detector reads 3,200 cps, so efficiency is 32%." Writing that sentence with Bq would be technically correct but odd, like referring to your morning coffee temperature in kelvin. The unit name signals what kind of work you are doing.

Before the becquerel was adopted in 1975, there was no named SI unit for radioactivity — scientists just said "disintegrations per second" or used the curie. The CGPM gave the name "becquerel" to one disintegration per second to honor Henri Becquerel and to bring radioactivity into the SI naming system alongside the gray and sievert. The dps description never went away; it just lost its status as the primary label. Think of it like saying "cycles per second" instead of "hertz" — correct, but dated.

A standard ionisation smoke detector contains about 1 kBq (roughly 0.9 microcuries) of americium-241, an alpha emitter. That tiny speck of material ionizes air inside the detection chamber; when smoke particles disrupt the ion current, the alarm triggers. The alpha particles cannot penetrate the plastic casing, so the external dose is essentially zero. You would have to physically open the sealed source and inhale the material to face any health risk — which is why proper disposal matters but daily proximity does not.

German wild boar still exceed the 600 Bq/kg caesium limit 40 years after Chernobyl because of a phenomenon called the "wild boar paradox." The animals root in forest soil for deer truffles — underground fungi that concentrate Cs-137 from the soil far more efficiently than surface plants. Forest floors recycle caesium in a closed loop: leaves fall, decompose, fungi absorb the caesium, boar eat the fungi, boar excrete it back into the soil. Unlike farmland, which was plowed and diluted, forest ecosystems locked the caesium in a tight cycle. Hunters in Bavaria must still test every carcass before sale.

The US measures radon in picocuries per liter (pCi/L) because the curie was the dominant unit when the EPA set its action levels in the 1980s. Most of the rest of the world uses becquerels per cubic meter (Bq/m³) because they adopted SI units. The EPA action level of 4 pCi/L equals about 148 Bq/m³; the WHO recommends action above 100 Bq/m³. Same phenomenon, different yardsticks — and a perpetual source of confusion when reading international radon guidelines.

Consumer Geiger counters can detect gross contamination — the kind where food is obviously dangerous — but they cannot identify specific isotopes or give reliable Bq/kg readings. Proper food monitoring requires a gamma spectrometer with a shielded sodium iodide or high-purity germanium detector, plus a sample prepared to known geometry and mass. After Fukushima, Japan deployed thousands of these in public food monitoring stations where citizens could bring their own produce for free testing.

Brazil nuts hold the record among common foods, with activity levels of 40–260 Bq/kg from radium-226 and radium-228 that the trees concentrate from soil. Lima beans and bananas follow at 170 and 130 Bq/kg respectively, mainly from potassium-40. None of these pose a health concern — the amounts are tiny compared to regulatory limits, and K-40 is self-regulating in the body. You would need to eat several hundred kilograms of brazil nuts daily before the radium intake became medically interesting.