Flight-time equivalent dose

The flight-time equivalent dose concept is the creation of Ulf Stahmer, a Canadian professional engineer working in the field of radioactive materials transport. It was first presented in the poster sessionStahmer, U. 11 – 16 September 2016. [https://www.researchgate.net/publication/308628378_Flight-Time_Equivalent_Dose_-_A_Concept_to_Contextualize_Radiological_Dose Flight-Time Equivalent Dose - A Concept to Contextualize Radiological Dose]. 18th International Symposium of the Packaging and Transport of Radioactive Materials (PATRAM). Kobe, Hyogo, Japan. at the 18th International Symposium of the Packaging and Transport of Radioactive Materials (PATRAM) held in Kobe, Hyogo, Japan where the poster received an Aoki Award for distinguished poster presentation.Nuclear Waste Management Organization (2016). [https://www.nwmo.ca/en/More-information/News-and-Activities/2016/11/17/11/05/NWMO-Engineer-Wins-Award-for-Best-Poster Engineer Wins Award for Best Poster]. Retrieved 10 December 2021. In 2018, an article on FED{{cite journal |title=Using Flight-Time to Contextualize Radiological Dose |journal=The Physics Teacher |date=2018-10-24 |last=Stahmer |first=U. |volume=56 |issue=8 |pages=508–511 |doi=10.1119/1.5064556 |s2cid=125730267 |url=https://aapt.scitation.org/doi/abs/10.1119/1.5064556?journalCode=pte |accessdate=2022-04-28 |doi-access=free |url-access=subscription }} appeared in the peer-reviewed journal The Physics Teacher.

Flight-time equivalent dose is an informal measurement, so any equivalences are necessarily approximate. It has been found useful to provide context between radiological doses received from various every-day activities and medical procedures.

FED corresponds to the time spent in an airliner flying at altitude required to receive a corresponding radiological dose. FED is calculated by taking a known dose (typically in millisieverts) and dividing it by the average dose rate (typically in millisieverts per hour) at an altitude of 10,000 m, a typical cruising altitude for a commercial airliner.

:$FED=\; \backslash frac\{\{mSv\}\_\{dose\}\}\{\{0.004\; \backslash frac\{mSv\}\{h\}\}\_\{cruising\; altitude\}\}$

While radiological dose at cruising altitudes varies with latitude, for FED calculations, the radiological dose rate at an altitude of 10,000 m has been standardized to be 0.004 mSv/h,Friedberg, W; Copeland K (2011). [https://rosap.ntl.bts.gov/view/dot/20607 "Ionizing Radiation in Earth's Atmosphere and in Space Near Earth"] Civil Aerospace Medical Institute, Federal Aviation Administration, DOT/FAA/AM- 11/9. about 15 times greater than the average dose rate at the Earth's surface. Using this technique, the FED received from a 0.01 mSv panoramic dental x-ray is approximately equivalent to 2.5 flight-hours; the FED received from eating one banana is approximately equal to 1.5 flight-minutes; and the FED received each year from naturally occurring background radiation (2.4 mSv/year{{cite journal |title=The annual effective dose from natural sources of ionising radiation in Canada |journal=Radiation Protection Dosimetry |date=2004-02-01 |last1=Grasty |first1=R.L. |last2=LaMarre |first2=J.R. |volume=108 |issue=3 |pages=215–226 |doi=10.1093/rpd/nch022 |pmid=15031443 |url=https://academic.oup.com/rpd/article-abstract/108/3/215/1593937?redirectedFrom=fulltext |accessdate=2022-04-28 |url-access=subscription }}) is approximately equivalent to 600 flight-hours.

For comparison, a list of activities (including common medical procedures) and their estimated radiological exposures are tabulated below. Regulatory occupational dose limits for the public and radiation workers are also included. Items on this list are represented pictorially in the accompanying illustrations.

• Background radiation
• Background radiation equivalent time
• Banana equivalent dose
• List of unusual units of measurement

{{reflist}}

Category:Radioactivity quantities

Category:Background radiation

Category:Equivalent units